CA2126119A1 - Personal computer with configurational flexibility and service features - Google Patents

Personal computer with configurational flexibility and service features

Info

Publication number
CA2126119A1
CA2126119A1 CA 2126119 CA2126119A CA2126119A1 CA 2126119 A1 CA2126119 A1 CA 2126119A1 CA 2126119 CA2126119 CA 2126119 CA 2126119 A CA2126119 A CA 2126119A CA 2126119 A1 CA2126119 A1 CA 2126119A1
Authority
CA
Canada
Prior art keywords
cover
door
attachment
top cover
pivot
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Abandoned
Application number
CA 2126119
Other languages
French (fr)
Inventor
John Robinson Dewitt
Todd Arthur Mcclurg
Jay Henry Neer
Orlando Pimienta
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
International Business Machines Corp
Original Assignee
International Business Machines Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by International Business Machines Corp filed Critical International Business Machines Corp
Publication of CA2126119A1 publication Critical patent/CA2126119A1/en
Abandoned legal-status Critical Current

Links

Classifications

    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F1/00Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
    • G06F1/16Constructional details or arrangements
    • G06F1/18Packaging or power distribution
    • G06F1/183Internal mounting support structures, e.g. for printed circuit boards, internal connecting means
    • G06F1/185Mounting of expansion boards
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F1/00Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
    • G06F1/16Constructional details or arrangements
    • G06F1/18Packaging or power distribution
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F1/00Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
    • G06F1/16Constructional details or arrangements
    • G06F1/18Packaging or power distribution
    • G06F1/183Internal mounting support structures, e.g. for printed circuit boards, internal connecting means
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F1/00Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
    • G06F1/16Constructional details or arrangements
    • G06F1/18Packaging or power distribution
    • G06F1/183Internal mounting support structures, e.g. for printed circuit boards, internal connecting means
    • G06F1/184Mounting of motherboards
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F1/00Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
    • G06F1/16Constructional details or arrangements
    • G06F1/18Packaging or power distribution
    • G06F1/183Internal mounting support structures, e.g. for printed circuit boards, internal connecting means
    • G06F1/186Securing of expansion boards in correspondence to slots provided at the computer enclosure
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T70/00Locks
    • Y10T70/50Special application
    • Y10T70/5009For portable articles
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T70/00Locks
    • Y10T70/50Special application
    • Y10T70/5093For closures
    • Y10T70/554Cover, lid, cap, encasing shield
    • Y10T70/5544Pivoted

Abstract

ABSTRACT OF THE DISCLOSURE

A personal computer includes a frame unit and a top cover mounted to pivot on the frame unit. In one version of the computer, the top cover pivots upward and outward to the rear of the system as it is opened. In another version, the top cover pivots upward to the side. One or more DASD storage devices may be mounted to extend downward from the top cover.
A planar board is attached atop the lower side of the frame unit, where flexible mounting hardware allows the attachment of one of several types of planar boards. A central support structure includes a riser card plugged into a connector of the planar board, and a number of card connectors into which option cards can be plugged for electrical connection with the planar board. The central support structure also includes a bracket extending along the rear of the computer, having slots through which port connectors of the option cards can extend.
The central support structure is held in engagement with the connector of the planar board by the top cover when this cover is closed. When the top cover is open, the DASD storage devices may be easily replaced, the central support structure may be unplugged from the planar board, and the planar board can be easily replaced or serviced. A front surface of the computer includes a door, which is opened by rotation outward and downward, to be slid inward, providing access for the replacement of media in the storage devices. This door and the top cover are separately lockable using a multi-function lock.

Description

~ 2~2~119 PERSONAL COMPUTER WITH CONFIGURATIONAL FLEXIBILITY
AND SERVICE FEATURES

BACKGROUND OF T~E INVENTION

Field o the In~ention This invention relates to the mechanical structure of a personal computer, and more particularly, to providing several levels of access to media and components within a personal computer.

Background Information Personal computer systems typically include electronic circuits mounted on a planar board, with various other circuits mounted on option, or feature, cards plugged into the planar board by means of connectors. This method allows the variation of features of the computer system by varying the option cards installed within the system. In some personal computer systems, the processor chip is also mounted on a card plugged into the planar board. In a desk-top type of system, the planar board is fastened in place to the system frame near the bottom of the system. The option cards extend upward from the planar board, being plugged directly into the planar board, or being plugged into an upward-extending riser card that is in turn plugged into the planar board. Various electromechanical devices within the system, such as diskette drives and hardfiles are typically also installed above the planar board.

A typical personal computer syctem also includes a number o other subassemblies installed above the planar board. Such devic~s may include the direct access storage devices (DASD
devices) used to provide data and program storage in most personal computers. These devices lnclude both devices with removable media, called floppy drive~, and devices with fixed media, called hardfiles. A typical personal computer includes one or two such devices with removable media, each of which , 2~6119 has a slot to which access must be available for the removal and replacement of magnetic media.

As a result of such configurations, desk-top personal computer systems must be almost completely disassembled before the planar board can be removed and replaced. This requirement causes particular difficulties because the planar board typically has the highest failure rate among system compo-nents. Particular problems are associated with the removal of option cards connected to peripheral devices, since the cables to such devices must be disconnected before the cards can be removed. Thus, much time is wasted in disassembly and reassembly of components in the event of a planar problem, which may occur during the process of building and testing the computer in a factory, or during the subsequent operation of the computer in the user's office. ~urthermore, in the user's office the additional desk space, required for the placement of various components removed for access to the planar board, is often not available. What is needed is a means to provide for easy access to the planar board and to DASD components for service.

Personal computer systems are typically configured to accept a single type of planar board, with mounting holes in the planar board attached to a frame by means of screws, plastic snap fasteners, or a combination of scre~s and plastic snap fasteners. To reduce the emission of radio frequency interference by the system, the planar board is typically grounded through a number of paths. Conductive pads on the planar may be provided in annular spaces around mounting holes, being held against the frame by screws tightened through the holes. Conductive pads also may be provided in other locations, to be contacted by flexible spring members supported by the frame. Thus, the fixed locations of mounting features in the frame limit the system to accepting a single type of planar board. Since the characteristics of a computer system depend largely on the planar board, this limitation often means that a different frame is required for each different system.

21~6~ ~9 Another problem with fixed locations for mounting the planar board arises from relatively small variations in the locations of mounting holes in the planar board and in the location of mounting features used for its attachment to the frame. Such variations, which are to be expected wi-th any practical processes for manufacturing planar boards and system frames, sometimes make it difficult to install a planar board in a specific rame. Occasionally, such variations make it impossible to perform this installation, so that a planar board or a frame mus-t be scrapped in the manufacturing process.

Thus, what is needed is a configurationally flexible means for mounting the planar board, including means for moving attachment points into various configurations, so that different kinds of planar boards may be accommodated. It is also desirable that the means for mounting be movable through small distances to accommodate variations in locations of features mounting a single kind of planar board.

A number of personal compu-ters, such as the IBM~ Personal Computer, Model AT, are equipped with key-operated locks that can be locked to prevent the removal of the top cover, and therefore to prevent access to subassemblies within the computar system. Such locks may also function as electrical switches to prevent the unauthorized use of the computers.
However, such locks tend to leave the system in either a totally locked or totally unlocked condition. Eor example, there is no condition in which the compu-ter can be operated without hindrance while its internal subassemblies ar~
protected from theft. What is needed is a flexible locking system, offering several levels of security through the use of a single lock, which may be placed in any of several positions through the use of a single key.

SUMMARY OF THE INVENTI~N
In accordance with one aspect of the inven-tion, there is provided personal computer hardware including a frame section, a planar board assembly, a central support structure, a top L, . ., ,". ..

} 2~26119 B~9-93-029 4 cover, a direct access storage device, and a cover attachment mechanism. The frame sec-tion has a generally flat lower side, a front frame bezel, a rear frame openiny, and an open side opposite the lower side. The planar board assembly is fastened within the frame section, by a planar board attachment mechanism, to the lower side. The planar board assembly includes a riser connector pointing toward the open side. The central support structure, which is for electrically connecting option card assemblies with the planar board, includes a riser card engaging the riser connector, a number of card connectors on the riser card electrically connected through the riser card to the riser connector, and a rear attachment framework extending within the rear frame opening.
This rear attachment framework includes a number of rear slots ex-tending through the ~ramework, with provisions for attaching a number of card assemblies in alignment with the rear slots and in engagement with various of the card connectors. The top cover has a g~nerally flat upper side and an open side opposite the upper side. The direct access storage device is attached to the upper side, extending below the upper side, by a storage device attachment mechanism. The cover attachment mechanism attaches the top cover to the frame section along a cover attachment edge of the top cover and along a frame a-ttachment edge of the frame s~ction, permitting pivoting movement of the top cover between a closed cover position and an open cover posi-tion. With the cover in the closed cover position, the cen-tral support structure is held in engayement with the riser connector. Wi-th the cover in the open cover position, the central support structure can be disengaged from the riser connector.

In accordance with another aspect of the invention, hardware is provided for controlling physical access within a computer system. This hardware includes a cover assembly, a media access door, a lock, a first locking mechanism, a cover locking mechanism, and a media door locking mechanism. The cover assembly includes a frame and a top cover, which is movable between a closed cover posi-tion and an open cover position. The loc}c has a rotor that can be rotated among -` 212~1~9 first, second, and third lock positions, when a properly encoded key is inserted in a slot of the rotor. The lock rotor cannot be rotated between adjacent lock positions when the key is no-t inserted in the slot. The first locking mechanism is moved by rotation of the lock. The cover locking mechanism is moved by the first locking mechanism between a cover locking position, in which the cover is held in the closed cover position, and a cover releasing position, in which the cover is released from the closed cover position. The cover locking mechanism is in the cover locking position when the lock is in the first and second lock positions and in the cover releasing position when the lock is ln the third lock position. The media door locking mechanism is moved by the first locking mechanism between a media door locking position, in which the media access door is held in the closed media door position, and a media door releasing position, in which the media access door is released from the closed media door position. The media door locking mechanism is in the media door locking position when the lock is in the first lock position, and in the media door releasing position when the lock is in the second and third lock positions.

BRIEF DESCRIPTION OF THE D~WINGS
Preferred embodiments or versions of the subject invention are hereafter described with specific reference being made to the following Figures, in which:
Figure 1 is an isometric view of a personal computer built in accordance with this invention, in a closed operating position, as viewed from in front, above, and to the right;
Figure 2 is a rear elevational view of the computer of Figure l;
Figure 3 is an isome-tric view o.E the computer of Figure 1, in an open position for repair or modification, as viewed in Figure l;
Figure 4 is a cross-sectional elevation, taken as indicated by section lines IV-IV in Figure 3, showing a central support structure used in the attachment of circuit cards;
Figure 4a is an exploded isometric view of the attachment BC9 93-029 6 ::
of connectors to a riser carcl in the central support structure of Figure 4;
Figure 5 is an isometric view similar to Figure 3, showing an alternative configuration of internal components;
Figure 6 is an isometric view similar to Figure 3~
showing a second alternative configuration of internal compo-nents;
Figure 7 is a cross~sectional side elevation of a pivoting attachment mechanism of the computer of Figure 1, in a closed operating position, taken as indicated by section lines VII-~II in Figure 2;
Figure 8 is a cross-sectional side elevation similar to Figure 7, except that the computer is shown in an open position for repair or modification;
Figure 9 is a front elevational view of the top cover of t~e computer of Figure 6, shown wi-th a media access door open to reveal the mounting of DASD devices;
Figure 10 is a partial cross-sectional side elevation of the top cover of Figure 9, taken as indicated by section lines X-X in Figure 9;
~ igure 11 is a ragmentary plan view of an attachment mechanism mounting a planar board in the computer of Figure 1, including, in an exploded relationship, two different types of planar boards, either of which may be mounted within the computer;
Figure 12 is a cross-sectional elevation through the attachment mechanism of Figure 11, taken as indicated by section lines XII-XII in Figure 11;
Figure 13 is a fragmentary isometric view of the attachment mechanism o~ Figure 11 as viewed from above and in front of this mechanism;
Figure 14 is an underneath plan view of the computer o Figure 1, showing in particular means provided to facilitate mounting the computer in a vertical orientation on a wall;
Fi.gure 15 is an exploded isometric view of foot assembly attached to an underside of the frame of the computer of Figure 1;
Figure 16 is a fragmentary right cross-sectional elevation of a front portion of the computer of Figure 6, 2~L2611~

taken as indicated by section lines XVI-XVI in Figure 6, but with the computer in a closed, operational position;
Figure 17 is a fragmentary rear cross-sectional elevation of a front portion of the computer of Figure 6, showing access doors in front surfaces of the system and a locking mechanism, taken as indicated by section lines XVII-XVII in Figure 16;
Figure 18 is a fragmentary rear cross~sectional view of an intermediate portion of -the compu-ter of Figure 6, showing the engagement of conductive shields, taken as indicated by section lines XVIII-XVIII in Figure 16;
Figure 19 is a fragmentary plan view of a media access door of the computer of Figure 6, taken as indicated by section lines XIX-XIX in Fi.gure 17;
Figure 20 is a fragmentary right cross-sectional elevation of a door actuating mechanism of the computer of Figure 6, taken as indicated by section lines XX-XX in Figure 17;
Figure 21 is a fragmentary longitudinal cross-sectional elevation of a lock of the computer of Figure 6, taken as indicated by section lines XXI-XXI in Figure 9;
Figure ~2 is a fragmentary transverse cross-sectional elevation of the lock of Figure 21, taken as indicated by section lines XXII-XXII in Figure 21;
Figure 23 is a fragmentary right cross-sectional elevation of the locking mechanism of Figure 17, taken as indicated by section lines XXIII-XXIII in Figure 17;
Figure 24 is a fragmentary underneath plan view of a pivot bail engaging mechanism of the computer of Figure 1, taken as indicated by section lines XXIV-XXIV in Figure 7;
Figure 25 is a fragmentary right cross-sectional elevation of the pivot bail engaging mechanism of Figure 24, taken as indica-ted by section lines XXV-XXV in Figure 24;
Figure 26 is a fragmentary, par-tially exploded longiku-dinal cross-sectional elevation of a link engaging pin of Figure 7, taken as indicated by section lines XXVI-XXVI in Figure 7;
Figure 27 is a fragmentary right elevational view of the front right, lower corner portion of -the top cover of the computer of Figure 1, showing a portion of a cover grounding 21~61~ 9 ~

spring;
Figure 28 is a fragmentary front cross-sectional elevation of the grounding spring of Figure 27, taken as indicated by section lines XXVIII-XXVIII in Figure 27;
Figure 29 is a fragmen-tary isometric vi~w of a central portion of the computer of Figure 1, showing an optional PCMCIA-type card socket and a connector mounting bracket which may be installed in the slotted bracket at the rear of the computer;
Figure 30 is a fragmentary plan view of the front right portion of the computer of Figure 1, showing particularly the optional installation of a PCMCIA-type card socket;
Figure 31 is a cross~sectional side elevation taken as Figure 8, showing an alternative linkage for holding the computer of Figure l in an open position by means of friction and detent forces;
Figure 32 is an exploded isometric view of a friction and detent portion of the alternative linkage of Figure 31;
Figure 33 is a fragmentary, partially exploded isometric view of an alternative attachment mechanism for mounting a planar board in the computer of Fiyure l;
Figura 34 is a fragmentary view of a personal computer built in accordance with this invention to provide an alterna-tive bus interface, showing in an exploded relationship therewith, an option card assembly, and an optional PCMCIA-type card socket;
Figure 35 is an isometric view similar to Figure 3, showing a computer having an alternative top cover providing more space for additional capabilities;
Figure 36 is a fragmentary cross-sectional right side elevation of the computer of the computer of Fiyure 35, taken as indicated by section lines XXXVI-XXXVI in Figure 35, showing -the computer in a closed, operating position;
Figure 37 is a fragmentary cross-sectional right side elevation of the media access door locking mechanism of the computer of E'igure 35, taken as indicated by section lines XXXVI-XXXVI in Figure 35, also showing the computer in a closed, operating position;
Figure 38 is a front elevational view of an alternative ~1~6119 BC9~93-029 9 -version of a computer built in accordance with the present invention, having a top cover pivoted along a right edge of the frame section, showing the computer in an open position, as required for service and configurational chanyes; and Figure 39 is a fragmentary cross~sectional right side elevation of the computer of Figure 38, taken as indicated by section lines XXXIX-XXXIX in Figure 38, showing the computer in a closed, opera-ting posi-tion.

DET~ILED DESC:RIPTION
Figures 1 through 15 show various aspects of a personal computer built in accordance with the present inven-tion, with Figures 1 and 2 showing the computer in a closed position, as it is normally operated. Figures 3, 5, and 6 show different ways the computer may be configured, with the computer in an open position, in which it may be serviced or reconfigured.
Figure 4 and Figures 7 through 15 show various assemblies forming parts of the computer. Figures 29 and 30 show optional assemblies that may be added to the computer.

Alternative applications of the present invention are shown in Figures 31 through 35, with alternate methods for providing certain of the features of the compu-ter being shown in Figures 31 through 33. Figure 34 shows how an alternate computer may be built -to provide a di:Eferent system bus. Figures 35-37 show a larger computer built using the lower portion of the computer of Figures 1 through 13, together with a number of concepts of the present invention. Figures 38 and 39 show a personal computer built in accordance with the present invention to have a top cover which pivots open along a right side edge, instead of along a rear edge.

At various points in the specification and in -the appended claims, references are made to directions, such as "upward" or "rearward." These references, which are made to simplify discussion concerning the relative locations of certain features, assume that -the computer is sitting on a desk, with -the frame facing down, the top cover facing up, and operational controls facing forward. These references are not ~126119 intended to limit the scope of the present invention; a computer built in accordance with the present invention can be used in various orientations, as demonstrated particularly through the wall-mounting hardware described in reference to Figures 14 and 15.

Referring first to Figure 1, which is an isometric view of the computer as viewed from in front, above, and to the righ~, personal computer 10 includes a top cover 12 and a frame 14, which together generally enclose various internal electronic circuits. Top cover 12 includes an upper front bezel 16, while frame 14 includes a lower front bezel 18. A number of controls 24 are provided for various purposes, such as turning computer 10 on and off. Since the enclosure of computer 10 may surround storage devices with removable media, such as diskette drives, a pivotable media access door 26 is provided to allow access for the insertion and removal of such media.

Referring to Figures 2 and 3, at the rear of computer 10, a pivoting bail 27 is pivotally moun-ted to top cover 12 and to frame 14. This arrangement allows both upward and rearward pivotal separation of top cover 12 and frame 14, as top cover 12 is moved from the closed position of Figure 1 into the open position shown in Figure 3, for repair, adjustment, or reconfiguration of internal components. Before this cover opening motion can occur, top cover 12 is released from frame 14 by rotating a lock mechanism 28, moving a cover latch 29 out of engagement with a latching slot 30. In this way, top cover 1~ is released to rotate upward while remaining in connection with frame 14 by means of pivoting bail 27.

Along each side of the interface between top cover 12 and frame 14, electrical continuity is provided by means of a number of flexible contact spring segments 31, which provide multiple contact points spaced apart from one another through distances compatible with the reduction of the emission of electromagnetic energy from the computer 10. This type of contact between major shielding covers has been found to be particularly beneficial in reducin~ the emission of such ~26119 BC9-93-029 ll energy, which may otherwise interfere with the transmission of communlcation signals.

Personal computer 10 may be assembled into a large number of configurations. As shown in Figure 3, major components attached within frame 14 include, for example, a power supply 32, a cooling fan 34, and a planar board 36. A transverse duct 38 directs cooling air from outlet 40 of fan 3g -to a space above planar board 36. A baffle 42, extending above the left portion of planar board 36 directs air from transverse duct 38, above this portion of the planar board, to outle-t slots 44 in the left side of frame 14. When top cover 12 is closed, outar slots 46 are generally aligned with outlet slots 44, so that air can flow outward from the space below baffle 42.
Those circuit devices most requiring cooling air may be mounted on this side of planar board 36, extending upward into this airflow. Fan 34 is a centrifugal-flow device sucking air through an inlet hole pattern 48 in its top surface and through a similar hole pattern (not shown) in its lower surface. Fan 34 is mounted on a suppor-t bracke-t 50 above the adjacent surface 52 of frame 14, exposing the hole pattern of the lower surface. Air is drawn into fan 34 through power supply 32, which has a number of external holes 53 in its rear surface 54 (shown in Figure 2), allowing the inward flow of air from outside, and throuyh a number of holes 55 allowing the flow of air between power supply 32 and fan 34. An additional inlet hole pattern 56 is provided in top cover 12 to allow the flow of additional air from outside computer 10 into fan 34.

Planar board 36 inclu~es a number of generally necessary circuits, along with means for electrically connecting a number of optional circuits. SIMM moduies 58 (single in-line memory modules) may be plugged into appropria-te sockets (not shown) on planar board 36 to provide a random access memory function.

Referring to Figures 2 and 3, rear surface 54 of power supply 32 also includes an appliance coupler 57, into which a line cord may be plugged for connect.ion -to a standard alternating-current power source. Connectors 60 ex-tend along a rear edye of planar board 36, -through apertures in a planar shielding bracket 61, for connection to various external cables (not shown). Various of these connectors 60 are configured for connection to input devices, such as a keyboard (no-t shown) or mouse (not shown), while others of these connectors 60 may be configured for connection to peripheral devices (not shown), such as a display unit and a printer, or to communication cables (not shown).

Referring to the cross-sectional elevation of Figure 4, additional, optional circuits may be provided by means of option cards 62, which are plugged into connectors 63 of a riser card 64. Riser card 64 is in turn plugged into a connector 65 of planar board 36. Thus, electrical connections are made from planar board 36 through connectors 65 and 63, and through circuit traces on riser card 64, to option cards 62. The I/0 channel of the system, for example, may be connected to op-tion cards 62 in this way.

As shown in Figure 4a, the use of sur~ace mount technology, in which formed terminal elements 66 extending from connectors 63 are soldered to conductive pads 67 at the surface of riser card 64, allows the placement of connectors 63 at identical locations on each side of riser card 64. Terminal elements 66 are integral portions of spring -terminals 67a which extend within each connector 63 -to con-tact conductive pads on an inserted op-tion card 62 (shown in Figure 4). Conductive pads 67 are electrically connected to pads 67b on the surfaca of riser card 64, by means of conduc-tive traces 67c. When riser card 64 is inserted into connec-tor 65 of planar board 36 (shown in Figure 4), electrical connections within the connec-tor 65 connec-t pads 67b -to various circui-ts within -the planar board.

~eferring again to Figures 2 and 3, a slotted bracket 71 extends partially across the rear of computer 10, behind the region in which option cards 62 may be placed. Each option ~C9-93-029 13 card 62 is part of an assembly including a card bracket 72, which is attached to slotted bracket 71 by means of a screw 73, closing a slot 74 in bracket 71. Some option cards also include port connectors 76 (shown in Figure 2), which are directed outward through apertures i.n card brackets 72 and through slots 74, to be used for the attachment of cables to peripheral devices or for -the attachment of communication cables (not shown).

Referring to Figures 3 and 4, limited option cards 68, which are installed in the lowest connectors 66 on riser card 64, are not directed at a corresponding slot 74 in ~racket 71, and are not attachecl to a carcl bracket 72. Preferably, limited option cards 68 are used for functions, such as extended system memory, which do not require cable attachment to a peripheral device. Blank brackets 77, which are not attached to option cards 62, are used to fill those slots 74 in slotted bracket 71 which do not correspond to an installed option card 62. Like each card bracket 72, each blank bracket 77 is removably attached to slotted bracket 71 by means of a screw 73.

Referring to Figures 3 and 4, a "T"-shaped central support structure 79 includes slotted bracket 71 ancl an a riser support bracket 80, which e~-tends forward to divide the space above planar board 36, being attached to riser card 64 by means of screws 82. These brackets 71 and 80 are attached -to one another, for example, by welding. Slotted bracket 71 generally fills a gap in the rear of computer 10, between power supply 32 and the left side of the computer. With computer 10 in the open position o~ Figure 3, central support structure 79 may be installecl by simply pluyging riser card 64 into planar board connector 65. Similarly, structure 79 may be removed ~y simply unplugying riser card 64 from connector 65.
With computer 10 in the closed position of Figure 1, central support structure 79 is held i:n place, with riser card 64 plugged into connec-tor 65, by means of the proximi-ty bet~een top cover inner surface 84 and the top surfaces of brackets 71 and 80. The stability of central support structure 79 is 212~119 further enhanced by contact between a downward-extending front leg 83, formed as an inteyral portion of riser support bracket 80, and an adjacent inner surface (not shown) of frame 14.

Top cover 12 includes slotted channels 86, which may be used to mount a number of DASD devices 88 in such a way that these devices are moved upward and rearward, providiny access to option cards 62, to planar board 36, and to the devices 88 themselves by moving top cover 12 into the open position shown in Figure 3. The acronym "DASD, 17 for direct access storage device, is used to reflec-t the type of magnetic storage device used in most personal computers. A DASD device, such as a maynetic disk device (floppy or hardfile), provides direct access to data instead of requiriny that data be read from the beyinniny of a data record, such as data stored se~uentially on a maynetic tape. DASD devices 88 may be attached to circuits mounted to frame 14 by means of flexible cables, such as cable 90, which are plugged into connectors atop planar board 36. Certain DASD devices may alternately be connected to various circuit cards 62, by means of flexible cables 92. In either case, the cables are routed near the rear of computer 10, where pivoting motion occurs with pivot bail 27, so that the cables are unfolded as computer 10 is opened and refolded as computer 10 is closed.

The configuration shown in Figure 3 includes one DASD device 88, directly behind media access door 26, and another DASD
device 93 in a location away from door 26. Thus, DASD device 88 preferably uses removable media, such as diskettes, while DASD device 93 preferably includes fixed media, beiny, for example, a hardfile.

The spaces above planar board 36 may be used for option cards 62 extending from central support structure 79, and/or ~or D~SD devices 88 ex-tending downward from top cover 12. In the example of Figure 3, two full-length option cards 62 are be installed above-the right side of planar board 36. SIMM memory modules 58 and baffle 42 lie below D~SD devices 88 with top cover 12 closed, so these elements can be present even with -2~261~9 ::~

upwardly adjacent DASD ~evices 88. Thus, a flexible use of space within compu-ter 10 is provided by the means for attachment of DASD devlces 88 and option cards 62.

In order to service a personal computer, it is necessary to obtain access to various subassemblies for repair or replacement. This type of access is also necessary for making configurational changes, such as adding circuits to perform additional functions. Access to the internal hardware of personal compu-ter 10 is easily obtained by opening top cover 12 aft~r lock 28 is rotated to disengage latch 29 from slot 30. A central electronic assembly 93a, consisting of central support structure 73 and of option cards, such as cards 62, and other devices attached to this structure 73, is then removed by lifting straight upward, so that riser card 64 is unplugged from planar board connector 65. To provide access-to planar board 36, central electronic assembly 93a may then be hun~, by means of a hole 93b in riser support bracket 80, on a hook 93c provided in top cover 12 for this purpose. At this point, planar board 36, being completely exposed from above, can be easily removed for service or replacement.

As shown in Figure 2, many option cards 62 include sxternal connectors 76 extending outward throuyh slots 74 in slotted bracket 71. In accordance with the typical usage of a personal computer, these connectors 76 are variously connected by means of cables (not shown) to peripheral devices (also not shown).
Referring again to Figure 3, when central electronic assembly 93a is hung on hook 93c, the cables extending from external connec-tors 76 can extend throuyh the opening at the rear of computer 10 between cover 12 and frame 14. Thus, it is unnecessary to unplug the cables attached to external connectors 76 to obtain access to planar board 36 or to other internal components.

In this way, the application of the present invention offers a significant number of serviceabilit~ advantages compared to computers of the backgroun~ art. In a typical computer of the background art, various DASD devices fas-tened in place above 212~

the planar board must be removed before access to the planar board can be obtained. On the other hand, in personal computer 10, DASD devices 89 and 93 are moved out of the way as top cover 12 is opened. In a typical personal comp~lter of the background art, various option cards are individually attached within a framework, either to the planar board by means of a number of connectors on the planar board, or to a riser card in turn connected to the planar board. In either of these cases, any external cables to peripheral devices must be disconnected, and each option card must be disconnected, both from its electrical connection through a connector and from its mechanical connection with the framework, to be removed completely from the computer system, before access can be obtained to the planar board. On the o-ther hand, in personal computer 10, the option cards 62 form part of central electronic assembly 93a, which can be removed intact by disconnection from the single planar board connector 65 for access to the planar board. In personal computer 10, this operation does not rec~uire the disconnection of individual option cards 62, or the disconnection of cables to external peripheral devices. Ease of access to planar board 36 is particularly important, since the planar board of a personal computer is-typically the component having the hi~hest failure rate, ancl hence the most frequent need for service.

Many of these advantages of the present invention are also evident during the manufacturing process, where planar boards also tend to experience relatively high failure rates. During the manufacturing process, it is of-ten necessary to repair or replace a planar board to fix a problem found during system testing. The ease of access to the planar and to other internal components wi-th -the present invention provides substantial time and cost savings during the ~anufacturing process.

The configuration of central elec-tronic assembly 93a also affords significant advantages relative to minimizing the overall size of personal computer 10 and relative to the servicing and reconfiguration of option carcls 62. In computer 2 ~ 2 6 ~

BC9-93-029 ]7 systems of the background art, the Iramework for moun-ting individual option cards is provided by the framework of the computer system. Thus, in computer systems of the background art, physical access -to both mechanical and electrical attachments must be obtained with the card installed within the system. On the other hand, in personal computer 10, the framework for mounting individual option cards 62 is provided by central support structure 79, which is removed as a part of central electronics assembly 93a. Physical access to mechanical and electrical attachments is afforded with this assembly 93a removed from its connection with planar board 36.
In this example, mechanical connection is provided by fastening card bracke-t 72 to slotted bracket 71 with a screw 73. Thus, ~ince access to screw 73 with a screwdriver is provided with central electronics assembly 93a removed, it is not necessary to allow clearance for the operation of screwdriver on each side of slotted bracket 71. Specifically, screwclriver clearance space is not required between slotted bracket 71 and power supply 32. Furthermore, since individual option cards 62 are removed and installed with central electronics assembly 93a removed, it is never necessary to remove one option card 62 to achieve access to the space for another card 62.

Referring to Figure 5, an alternative allocation of space above planar board 36 is provided through the use of a short option card 9~L in an uppermost position provided by "T"-shaped central support structure 79, in place of a full-length option cards 62. When a short option card 94 is installed in this way, space is provided in front of the option card for the installation of a second DASD device 88 in a front space adjacent to media access door 26. In the closed position, the second DASD device 88 is brought into a space above the front right portion of planar board 36, in front of the short option cards 94. This configuration thus offers two DASD devices 88 directl~r behind media access door 26; each of -these devices 88 can employ removable media. A single DASD device g3, which may be, for example, a hard file, is located away from door 26.
The popular system configuration including a 3~2-inch diskette 212Bl~

drive, a ~-inch diskette drive, and a hardfile can be built in this way. Thus, the present inven-tion easily provides for the alternative use of the same space for option cards or for DASD devices.

Figure 5 also shows a bracket assembly 95 holding a speaker 95a and various switches and indicators 95b in locations adjacent to corresponding features of top cover 12 in its closed position. Thus, a pattern of holes 96 in top cover 12 is brought into place adjacent to speaker 95a, while push-buttons and apertures 96a are adjacent to switches and indicators 95b. This bracket assembly 95 is equally applicable to the configura-tion shown in Figure 3; it has been omitted from Figure 3 only -to reveal the features which would otherwise be hidden.

Referring to Figure 6, an "H"-shaped central support structure 97 may be used in place of the "T"-shaped central support structure 79 previously discussed in reference to Figures 3 and 4. Support structure 97 is particularly designed to take advantage of the space savings made available through the use of short option cards 94 (shown in Figure 5). Thus, support structure 97 includes five connectors 63 on each side, each of which is connected to the system bus through a riser card ~not shown). In Figure 6, these connectors 63 are individually indicated as connectors 63-1 through 63-5. Support structure 97 includes a front slotted bracke-t 98 having a slot 98a on each side, aligned with an adjacent connector 63-1 in such a way that the bracket of a short option card 9~ installed in this connector 63-1 extends across the corresponding slot 98a.
The configuration of front slotted bracket 98 corresponds to that of rear slotted bracket 71 in such a way that each card bracket 72 and each blank bracket 77 can be :Eastened to front slotted bracket 98 in the manner used for attachment to rear slotted bracket 71. Slotted bracket 98 extends atop transverse duct 38, being fastened, for example by welding, to a central support member 99 at a tab 99a. Thus, the concept of a central elec-tronics assembly is implemented either wi-th a central support structure 79 having a single end at which card 212~19 ~ ~

brackets 72 may be attached, or wi-th a central suppor-t structure 97 having two opposite ends at which card brackets 72 may be attached.
. .
In many applications, it is necessary to obtain access to slots 98a from outside system 10. For example, a short option card 94 (shown in Figure 5) may be connected to an external peripheral device by means of a cable from a connector extending through a card bracket 72 of the short option card 94. To obtain such access, an alternate lower bezel 100, which includes a pair of rotatable lower access doors lOOa and lOOb, is used in place of lower bezel 100.

Central support struc-ture 97 provides on each side a lower position in which a single long card without a bracket 72 may be placed in a connector 63-2, or in which two shor-t cards without brackets 72 may be placed, using connectors 63-2 and 63-3. In a central position, a single long card 62 with a bracket 72 may be placecd in a connector 63-4, or two short cards 94 with brackets 72 may be placed, using connectors 63-4 and 63-1. In an upper position, using connector 63-5, a single short card 94 with a bracket 72 may be placecl, or a single long card 62 with a bracket 72 may be placed. However, if a long card 62 is placed in the upper position, no DASD device may be placed above it. If a shork card 94 is placed in the upper posi.tion, a single DASD device 88 may be installed on the corresponding side toward the front (as shown in Figure As further shown in Figure 6, a total of four DASD devices---two DASD devices 88, which are located near door 26 for media access, and two DASD devices 93, which are preferably devices with fixed media---may be installed to extend ~ownward from top cover 12 if no option card 62 or 94 is installed in connector 63-1. A configuration of the general type shown in Figure 6 may be used as an expansion box to provide additional data storage capability to a personal computer system. In such an application, the expansion box functions as a peripheral unit attached to a base system. A planar boarcl having the 212611 ~

circuit functions typically associated with such an circuit board may no-t be required. A different sort of planar board, having various connectivity features with limited logical functions may be provided instead.

General con.figurational features of the present invention have been discussed above with reference to Figures 1 throuyh 6.
More specific hardware features, variously applied in the implementation of these yeneral features, will now be discussed with references being made to Fi~ures 7 through 28.
The pivoting arrangement joining top cover 12 with frame 14 will first be discussed in greater de-tail, with reference being made to Figures 2, 7 and 8. Figure 2 is a rear elevational view of computer 10. Figures 7 and 8 are cross-sectional elevational views taken as indicated by lines VII-VII in Eigure 2, with Figure 7 showing the computer in a closed position, while Figure 8 shows the computer in an open position.

Referring to Figure 2, pivot bail 27 is a formed and welded rod structure extending generally around an inner periphery formed by the rear edges of frame 14 and top cover 12. A lower rod portion of 101 of bail 27 is pivotally mounted to frame 14 by means of rolled hinge tabs 102 e~tending from frame 14. In turn, top cover 12 is pivotally mounted on an upper rod portion 103 of bail 27 by means of hinge couplings 104 e~tending from top cover 12.

As shown in Fi~ure 7, when personal computer 10 is in its closed position, upper rod portion 103 is held adjacent to rear surface 54 o power supply 32, by the engagement of cover latch 29 in slot 30 (shown in Figure 3), which prevents the rearward motion of top cover 12.

As shown in Figure 8, when persona] computer 10 is in its open position, upper rod portion 103 is pivoted to the rear, away ~rom power supply rear surface 54, with lower rod portion 101 turning in rolled hinge tabs 102. Bail 27 includes, at each end, a "U"-shaped inward-e~tending portion 105 adjacent to a 212~9 BC9-g3-029 21 bail support bracket 106 extending upward from frame 1~. Each bracket 106 includes a formed tenon 108 e~tending into the adjacent inward-extending portion 105. As bail 27 is pivoted rearward, a corner 107 of inward-extending portion 105 on each side engages tenon 108, spreading portion 105 slightly, so that bail 27 is held in its fully rearward position by frictional forces.

Top cover 12 is also rotated upward, with hinge couplings 104 turning on upper rod portion 103. On each side, a travel limiting linkage 110 is provided to control the angle through which top cover 12 is rotated and to hold cover 12 in its open position. This linkage 110 includes a lower link 112 pivotally mounted to frame lg by means of a pivot 113 attached to support bracket 106, and an upper link 114 pivotally mounted to top cover 12 by means of a pivot 115. Links 112 and 114 are also pivotally mounted to one another at a central pivot 116.
A tab 118 from lower link 112 restricts the motion of pivot 116 in the direction of arrow 120 after linkage 110 is fully opened, by closing against a stopping surface 121 of upper link 114, as shown in Figure 8. Links 112 and 114 are configured so that, when linkage 110 is fully opened, central pivot 116 is located in the direction of arrow 120 from a line between pivots 113 and 115. When top cover 12 is ~ully opened, linkage 110 is straightened as shown in Figure 8. With linkage 110 straightened in this way, a force tending -to close cover 12 results in-the generation of a torque tending to move pivot 116 in the direction of arrow 120. However, since such motion is impossible, the linkage serves to hold cover 12 fully open.
Thus, top cover 12 canno-t be closed until central pivots 116 on each side are manually moved the direction opposite arrow 120 to release the cover 12.

Reerring again to Figure 3, as top cover 12 is moved upward and to the rear, clearing the space above planar board 36, allowing central support structure 7g to be unplugged and removed or replaced, and allowing access to planar board mounting screws at any location within the boundaries of planar board 36.

2126~1~

BCg-93-029 22 The method for moun-ting DASD devices 88 within top cover 12 will now be discussed in yreater detail, with particular reference being made -to Figures 9 and 10. Figure 9 is a front view of personal computer 10, wi-th media access door 26 shown in a lowered ~open) position, stored under the front portion of DASD devices 88. Also, in Figure 9 a portion of cover 12 is cut away to reveal the mounting of devices 88. Figure 10 is a par-tial cross-sectional side view of top cover 12, taken in the direction indicated by section lines X-X in Figure 9.

Reerring to Figures 9 and 10, a device mounting bracket 124, including a number of slotted channels 86, is attached by welding inside top cover 12. Each DASD device 88 is attached to bracket 124 by means of a pair of sideplates 126 with tabs 128 extending upward into the slots 130 of channels 8~. These sideplates 126 are mounted to the DASD devices, for example, by means of screws 129. Two channels 86 form mounting surfaces above the leftmost position, in which a DASD device 88 is installed, while three channels 86 form mounting surfaces above the rightmost position, in which a wider DASD device 131 is installed. Thus, the leftmost position is configured for mounting 3~ inch DASD devices, while the rightmost position is configured for mounting either 3~-inch or 5~-inch DASD
devices.

Figure 9 also shows some of the spatial relationships among top cover 12, central support structure 79, and DASD devices 88. Central support structure 79, including the uppermost option card connectors 63-5, fits between installed DASD
devi.ces 88. This is why as many as four DA~D devices may be installed if no cards are installed in uppermost connectors 63~5, as in the configuration of Figure 6. However, if an option card is installed in one of the uppermost connectors 63-5, a DASD device cannot be installed in an adjacent position. Thus, the configuration of Figure 3 has a daughter card in uppermost connector on the right side of central support structure 79, but not on the lef-t side of this structure 79, with DASD devices 88 and 93 installed on the left side of this structure 79.

2126~

Central support structure 79 extends upward into close proximity with an adjacent underside of top cover 12. This proximity holds the riser card 64 of structure 79 in engagement with central connector 65 of the planar board 36 (shown in Figure 4), as long as top cover 12 remains in a closed position. When cover 12 is opened, central support structure 79 can be easily disengaged from central connector 65 for system servicing or for configurational changes.

As shown in Figure 10, each DASD device 88 or 93 is installed by moving the device upward and to the rear, in the direction of arrow 134. After installation, each tab 128 of sideplate 126 extends upward into a channel 86 through a slot 130. A
notch 132 of each tab 126 holds the associated DASD device 88 or 93 in place by engagemen-t with an adjacent end of a slot 130. A latching mechanism, including a flexible cantilever spring 136 welded inside channel 86 at an attachment region 138, is provided to retain device 88 or 93 by preventing forward motion after installation. Cantilever spring 136 includes a latching tip 140, which extends partially across an adjacent slot 130. As the corresponding tab 128 is inserted into this slot 130, the latching tip 140 is deflected upward.
As tab 128 is subsequently moved rearward in the direction of arrow 134, latching tip 140 is cleared to return downward, into its undeflected position, blocking subsequent forward motion in the direction opposite arrow 134. Cantilever spring 136 also includes a force-loading tip 142, which applies a downward force on an upstanding cam portion 144 of sideplate 126, which is thereby held downward, with the surfaces of notches 132 resting against -the internal sur~aces 146 of channels 86. In this way, clearance distances between adjacent surfaces are avoidecl. Such clearance distances could otherwise cause rattling and shock loads, which could damage DASD
devices, during the transport of computer 10.

Cantilever sprinq 136 also includes a tab 148 extencling outward through a slot 150 in channel 86. The DASD unit, such as DASD unit 88, attached to sideplate 148 may be removed as ta~ 148 is held upward, deflecting spring 136 until latching 2~2~tl9 BC9-93-029 24 .
tip 140 is deflected upward past the adjacent tab 128. The DASD unit may then moved forward, in the direction opposite arrow 134, and downward to be disengaged from channel 86.

Figures 11 through 13 show a method used to attach planar board 36 within frame 14, with Figure 11 providing a plan view -showing the use of the me-thod to attach either of two different types of planar boards, with Figure 12 providing cross-sectional elevation through the attachment mechanism used by this method, taken as indicated by saction lines XII-XII in Figure 11, and with Figure 13 providing an isometric view of this attachment mechanism. ~;

Re~erring first to Figure 11, a mounting plate 176 is attached inside frame 14, for example by welding at various tabs 178.
Mounting plate 176 provides a number of attachment holes 180, each of which defines a location at which planar board 36 may be fastened. In general, mounting plate 176 is configured to provide for the attachment of any one of a number of different planar boards, with th~ required attachment points for any one planar board being a subset of the total number of attachment holes 180. For example, mounting plate 176 may be configured for the attachment of either planar board 36, having a mounting hole 182, or of an alternate planar board 184, having a mounting hole 186 at a position not corresponding to that of mounting hole 182.

Referring also to Figure 12, -to allow the alternate attachment of planar boards 36 and 184, mounting plate 176 includes a hole 180 corresponding to the location of each mounting hole 182 and 186. The attachment of planar board 36 is accomplished by means of a screw 188 extending through mounting hole 182 to engage a threaded surface 190 of a formed nut 192. Planar board 36 is clamped in a spaced-apart relationship with mounting plate 176 through the use of a formed spacer 194. :

Referring also to Figure 13, hole 180 and formed nut 192 include particular provisions for allowing the installation of formed nut 192 and spacer 194 to mounting plate 176 after ~ 2~261 1~

BC9 9~-029 25 plate 176 is welded in place within frame 14. Nut 192 includes three angularly spaced flange segments 196, which fit through three outward-extending aperture segments 198 within each hole 180. Formed nut 192 and spacer 194 are assembled together with tapered upstanding portion 200 of formed nut 192 extending within central portion 202 of spacer 194. Upstanding portion 200 includes three outward-extending lanced tabs 204, which snap into three slots 205 within upstanding portion 206 of formed spacer 194 as spacer 194 is brought into engagement with nut 192. In the process of attaching a planar board, such as planer board 36 or alternate planar board 184, assemblies thus formed of nuts 192 and spacers 194 are inserted into holes 180 corresponding to the locations of mounting holes 182 in the planar board to be attached. This insertion is accomplished with flange segments 196 dropping throuyh aperture segments 198. Each of these assemblies is then rotated in a hole 180~ so that the inward extending tabs 208 of the hole 180 are clamped between flange segments 196 of formed nut 192 and flange 210 of spacer 194 when screw 188 is -tightened in the direction of arrow 210a in threaded surface 190 of nut 192. These tabs 208 extend inward be-tween adjacent aperture segments 198. To assure that this tightening process leaves flange segments 1~6 aligned to clamp the tabs 208, each tab 208 includes a downturned por-tion 211 restricting motion beyond an angle at which flange segmenks 196 are fully under the tabs 208.

Some or all of the areas around mounting holes, such as mounting holes 182 and 186, on a typical planar board are used to provide ele~trical grounding for various ground planes or other circuits within the board. Conductive pads around the mounting holes, one or both sides of the planar board, electrically connected to circuits needing -the grounding function, are provided for this purpose. For e~ample (as shown in Figure 11) a conduc-tive pad 1~7 may be provided around hole 182. Effective grounding of this kind is required to minimize the emission from the system of radio frequency interference (RFI). To be effective in this regard, the grounding means mu~t be apable of carrying radio frequency slgnals.

-" 2 1 ~ 9 In the structure described above, mounting plate 176 is used with spacer 194 and formed nut 196 to provide electrical grounding paths capable of carrying radio frequency electrical signals. These parts are preferably composed of metallic materials with surface coatings minimizing the formation of surface oxidation. Such materials and coatings are well known to those skilled in the art. This assembly is particularly effective in providing this kind of electrical grounding, because relatively large con-tact surface areas are available, and because relatively high contact forces can be derived from the thrust force provided by tigh-tening screw 188 in threaded surface 190. Thus, as screw 188 is tightened, the lower surface 211a of planar board 36 is clamped directly to the upper surface of spacer 194. If electrical grounding is to occur at this location, a conductive pad planar board 36 includes a conductive pad on its lower surface 211a around hole 184, so this clamping provides a suitable contact between this conductive pad and spacer 194. Furthermore, as screw 188 is tightened, tabs 208 are clamped tightly between flange segments 196 of nut 192 and flange 210 of spacer 194, providing suitable contact between spacer 194 and mounting ;plate 176. A secondary grounding path may also be provided through a pad 187 on the upper surface of planar board 36 to the underside of the head o~ screw 188, through the threaded portion of screw 188 to the threaded surface 190 of nut 192, and through flange segments 196 to tabs 208.
:
Referring to Figure 12, planar board 36 is generally of a modern type, having conductive traces an~ electronic components 214 on both sides. On each side of planar board 36, an annular space around each mounting hole 182 is reserved or mounting, and often for electrical grounding, purposes, being free from components and traces except for conductive grounding pads, such as pad 209 (shown in E'igure ll). However, locations corresponding to the places used for moun-ting other -types of planar boards cannot be expected to be free from components or circuit traces Therefore, the ability to move nut 192 and spacer 194 between the various holes 180 in mounting plate 176 is par-ticularly important; along with a ~12~119 ~-' ;~':' capability for providing mounting hardware where it is needed, this method provides a capability for removing mounting hardware from positions where it is not needed, and where it would otherwise interfere with mounting a planar board by contacting circuit traces and electronic components.

These capabilities provide an advantage in the manufacturing process, allowing a single frame 14 to be used with a number of different types of planar boards, such as planar boards 36 and 184, to build different system models. Eurthermore, these capabilities provide an advantage of allowing subsequent upgrading to a new type of planar having a different mounting configuration.

Referring to Figure 14, the underside 212 of frame unit 14 includes four foot structures 214, each of which provides an elastomeric pad 215, establishing an appropriate surface for contact with a furniture surface, such as a desk top, and a keyhole-shaped aperture 216 for accepting the head portion of a headed fastener, such as a screw of nail, which may be used to hang computer 10 on a wall surface. Preferably, when the computer 10 is hung from a wall surface, two of the foot structures 214 adjacent to a side surface 217 are used in this way, so that the system unit is hung with the upper bezel 16 facing toward either the right or left on the wall. When the computer 10 is hung in this way, the servicing or reconfiguration of components is easily accompIished by opening top cover 12 as previously described; there is no nqed to remove the computer 10 from its position on the wall for this purpose.
,~
- Reerring to Figure 15, each foot structure 214 includes a housing 218 fastened to the underside of frame 14 by means of four screws 219, each of which extends downward through a hole 220 provided in frame 14 to engage a hole 221 in housing 218.
Housing 218 is preferably composed of a thermoplastic resin material. An elastomeric pad 215 is adhesively attached to a lower surface 222 of housing 218. Keyhole-shaped apertures 223 and 224 are also provided in housing 218 and elastomeric pad 212~1~9 215, respectively. (Wall sections of housing 218 are partially cut away in Fiyure 15 to reveal lower sur~ace 22 and aperture 223.) Referring to Fiyures 14 and 15, computer 10 may be huny from the wall using two of these structures 21~ to engaye headed fasteners (not shown). The computer lO is first placed with the heads of the headed fasteners extendiny through the enlarged portions of keyhole-shaped apertures 223 and 224. The computer 10 is then allowed to slide downward, so that the head of each fastener is trapped between a pair of flanyes 225, extending to define the narrowed por-tion of aperture 223, and an adjacent surface of underside 212 of frame 14. Computer 10 may be subsequently removed from the wall by liftiny upward, so that the fastener heads are ayain aligned with the enlarged portions of keyhole-shaped apertures 223 and 22~, and by pulling outward from the wall.

The operation of media access door 26, which is opened to ~rovide access to DASD devices 88 for the removal and replacement of magnetic media, will now be discussed, with particular reference being made to Figures 16 through 19.
Figure 16 is a riyht cross-sectional elevation, taken as indicated by section lines XVI-XVI in Fiyure 9. Figure 17 is a partial rear cross-sectional elevation, taken as indicated by section lines XVII-XVII in Eigure 16, showiny part:icularly the internal features o~ door 26. Figure 18 is another partial rear cross-sectional elevation, taken as indicated by sections lines XVIII-XVIII in Figure 16, showiny particularly metallic structures used or electro~nagnetic shielding. Figure 19 is a partial cross-sectional plan view, taken as indicated by section lines XIX-XIX in Figure 17, showing the engagement between -the ends of door 26 and the openiny for this door within upper bezel 16. As shown in Figure 16, a provision is made for allowing media access door 26, in upper bezel 16, to be pivoted downward manually and to be pushed into a pocket 228 in an open horizontal orientation indicated by dashed lines at 230.

~C9-93-029 29 Referring to Figures 16 and Figure 17, each end of door 26 is held in a closed position, at i-ts top edge by means of a slotted tab 232, near each (righ-t and left) end of the door 26, engaging a downward-extending tab 234, and at its lower edge by means of a cylindrical tab 236 engaging a downward extending portion of a slot 238. Cylindrical tab 236 extends at each end of the door from the lower end of a descending support structure 240. A housing 242 of upper bezel 16 includes, outwardly adjacent to each end of door 26, a sidewall portion 244 extending into system 10. Each sidewall portion 244 includes, directed toward the adjacent door 26, the door guiding slot 238. Door 26 and housing 242 are preferably composed of suitable plastic resin materials, allowing the fabrication of slotted tabs 232, support structures 240, and cylindr.ical tabs 236 as integral portions of door 26, and further allowing the fabrication of downward-extending tabs 234 and sidewall portions 244 with slots 238 as integral portions of housing 242.

Referring to Figures 16 and 18, the metal enclosure 246 of top cover 12 includes a downward-extending front portion 248 with a slot 250 through which DASD devices 88 may extend. A "U"-shaped flexible shield 252 extends below a lower edge section 254 of ~ront portion 248, providing an elec-tromagnetic sh~ield around pocket 228. Front edges of shield 252 are divided into lip porticns 256 and in-tervening tab portions 258, which provide electrical contact with enclosure 246 by cl.amping lower edge section 254. Shield 252 extends into slots 260, to be held in place at each end within a sidewall portion 244.
Shield 248 also i.ncludes, adjacent to each end, a spring tab 262, which extends orward to push upward on a cylindrical tab 236 of door 26, holding door 12 closed by maintaining engagement between slotted tabs 232 and downward-extendiny tabs 234.

Door 26 is opened by pushing downward at a ridged gripping surface 263 to release slotted tabs 232 from engagement with downward-extending tabs 234, and by subsequently rotating the door downward in the direction of arrow 264. As the door is 212~

rotated downward, spring tabs 262 continue to push upward on cylindrical tabs 236, aiding in the aliynment of these tabs with the rearward-extending, horizontal portion of slot 238.
Door 26 may then be pushed to the rear, into pocket 228, to the position indicated by dashed lines 230. The rearward motion of door 26 is limited by a pair of s-top tabs 266 extending within shi01d 248 to contact cylindrical tabs 236 as door 12 is moved fully rearward. ~s shown in Figure 19, the edges 268 at the right and left ends of door 26 are preferably shaped to prevent inward movement of the door unless the door is rotated ~ownward, to be pushed straight inward.

Door 26 is subsequently closed by pulling forward, with cylindrical tabs 236 being pulled in slots 238. Door 26 is then rotated upward, opposite the direction of arrow 264, to be snapped into engagement with tabs 234 extending downward from housing 242.

E'igures 16 through 18 also show the alternate lower bezel 100, including a pair of lower doors lOOa and lOOb. Referring first to Figure 16, as previously discussed in reference to Figure 6, each door lOOa or lOOb is used to obtain access to a slot 98a in a bracket 98, which is a part of an alternate central support structure 97. The metallic enclosure 265 of frame 14 includes an upward-extending portion 266, which has an access slot 267 adjacent to each slo-t 98a. An upper edge portion 268 of upward-extending portion 266 is clamped between lip portions 256 and intervenlng tab por-tions 258 of shield 252, ther0by assuring elec-trical contlnui-ty between shield 252 and frame enclosure 265.

Referring to E'igure 17, lower door lOOa includes a central pivot shaf-t 269, extending toward the centre of computer 10, and an outer pivot shaft 770, extending away from the centre o computer 10. Lower door lOOb includes an elongated central pivot sha~t 270a and an outer pivot shaft (not shown). Lower door lOOa is pivotally mounted in lower bezel 100, with outer pivot shaft 270 being snapped into place to pivot between a pair of flexible bearing tabs 271, with central pivot shaft 2~2~

269 being snapped into place to pivot between a flexible bearing tab 272 and a central bearing tab 274. I,ower door lOOb is pivotally mounted in lower bezel 100, with elongated central pivot shaft 270a being snapped in-to place to pivot between a fle~ible bearing tab 272 and a central bearing tab 274, and also between another pair of flexible bearing tabs 271. The outer end of door lOOb is pivotally moun-ted in a manner similar to -the outer end of door lOOa. Pivot shafts 269, 270, and 270a extend frorn tabs 278, which in turn extend into computer 10 as a part of doors lOOa and lOOb. This mounting provides for the rotation of each door lOOa or lOOb between a vertical position and a horizontal position, as indicated by dashed lines a-t position 280 in Figure 16.

Figure 20 is a partial right cross-sectional elevation, taken as indicated by section lines XX-XX in Figure 17, to show the method provided to facilitate the manual opening and closing o~ doors lOOa and lOOb. A sector gear 282 is formed at an end of each central pivot shaft 269 and 270a. Both of these sector gears 282 engage internal tee-th 283 of a lever actuator 284, which is pivotally mounted between the two doors lOOa and lOOb by means of an integral pivot shaft 286 extending from each side of actuator 284 to be snapped between a central bearing tab 274 and a flexible bearing tab 288. Central pivot shafts 269 and 270a are arranged in a coa~ial alignment, and -the two sector gears 282 are rotationally aligned to engage the same internal teeth 283. A lever tab 290 of lever actuator 284 extends through a slot 2g2 in -the front housing wall 293 of lower bezel 100, providing the appearance and manual operating characteristics generally associata~ with an electrical switch.

Thus, when lever tab 290 is pushed downward to rotate lever actuator 284 in the direction of arrow 294, shafts 269 and 270 turn to rotate lower doors lOOa and lOOb into the horizontal orien-tation shown by dashed lines a-t posi-tion 280. Similarly, the subse~uent rotation of lever actuator 284 opposite to the direction of arrow 294 rotates doors lOOa and lOOb into the closed position. However, this motion can be prevented by the movement of a locking bar 296 into a position stopping the passage of tab 298 of actuator 284.

A multi-functional locking mechanism 299 for moviny locking bar 296 to lock lower doors lOOa and lOOb closed, for locking media access door 26 closed, and also for locking top cover 12 closed will now be discussed, with particular reference being made to Figure 17 and to Figures 21 through 23. Figures 21 and 22 show the lock 28, with Figure 21 being a longitudinal cross-sectional elevation of the lock, while Fiyure 22 is a transverse cross-sectional elevation taken as indicated by section li.nes XXII-X~II in Figure 21. Figure 23 is a right side cross-sectional elevation, taken as indicated by section lines XXIII-XXIII in Figure 17 to show the multi-functional locking mechanism 29q located near the centre of frame unit 14.

Referring first to Figures 21 and 22, lock assembly 28 is operated by inserting a key 300 into a slot 302 within a lock rotor 304, and by rotating the rotor 304 within a stator 306, by means of the key, among four rotary positions. As key 300 is inserted, i.ts encoded edge 308 engages a number of tumblers 310, each of which is held against the edge 308 by means of a compression spring 312. Each tumbler 310 is thus moved outward through a distance corresponding to the location of the part o~ encoded edge 308 contacted by the tumbler 310. Each tumbler 310 includes a slot 314, with variations in the distance between this slot 314 and -the points at which the tumblers contact the encoded edge providing the means for encoding the lock 28. Thus, if a properly encoded key 300 is fully inserted, all of the slots 314 are aligned to al].ow rotation past a barrier 316 extending inward as a part of stator 306.
~s shown in Figure 22, barrier 316 is divided into three segments, each of which extends inward be-tween-two of the four slots 318. When the tumblers 310 are aligned with one o these slots 318, the key 300 may be inserted and withdrawn.
Rotor 304 can be rotated to bring tumblers 310 out of alignment with a slot 318 only if a properly encoded key is fully inserted in slot 302. The lock assembly 28 is preferably 212~ ~9 configured so -that a key 300 cannot be removed from slot 302 unless tumblers 310 are aligned with one of the slots 318.
This is achieved by assuring that a-t least one of the tumblers 310 must be moved outward during the process of removing key 300.

In Figure 17 and in each Figure 20 through 23, the locking mechanism is shown in the first position, in which top cover 12 and all doors 26, lOOa, and lOOb are locked. From this position, lock rotor 304 can be rotated in the direction of arrow 320 in Figure 22, and of arrow 322 in Figure 17, into second through fourth positions. In the second of these positions, top cover 12 and doors lOOa and lOOb xemain locked, while media access door 26 is released. In the third of these positions, all doors 26, lOOa, and lOOb are released, while top cover 12 remains locked. In the fourth of these positions, top cover 12 and all doors 26, lOOa, and lOOb are released to be opened.

The lock stator 306 is attached to front housing wall 293, being clamped in place, for example, using a collar 324. A
flat or keyslot arrangement (not shown) is preferably also used to assure the correc-t orientation of stator 306 within housing wall 293. A shaft 326 extends rearward in-to computer 10 as a part of lock rotor 304. The various locking functions are performed by means of a cam 328 rigidly attached to shaft 326.

Referring to Figures 17 and 23, the rear surface of cam 328 includes a spiral groove 330. Locking bar 296, which is slidably mounted in a pair of slotted tabs 332 extending into system 10 from front housing wall 293, includes a tab 334 e~ctending downward and into groove 330. When the locking mechanism is in its first and second positions, tab 334 is in a portion of groove 330 at its outermost radial location, holding locking bar 296 interposed above tab 298 to prevent the rotation of actuator 284 in the direction of arrow 294 (as shown in Figure 20). ~s the locking mechanism is rotated between its second and third positions, rotating cam 328 in ---" 21261~9 the direction of arrow 322, the inward spiral shape of groove 330 causes-the movement of lockiny bar 296 in the direction of arrow 336, releasiny tab 298, so that actuator 284 can be moved in the direc-tion of arrow 294 to open doors lOOa and lOOb. As the locking mechanism is further rotated between the third and fourth positions, tab 298 remains in a portion of groove 330 at its innermost radial location, so locking bar 296 is held away ~rom tab 298. Thus, doors lOOa and lOOb are unlocked when the locking mechanism is in its third and fourth positions.

Referring -to Figure 23, cam 328 also includes a peripheral groove 338 extending around a port.ion of its cylindrical outer surface. A latching bracket 340 includes a tab 342 descending into this groove 338 and a tab 344 ascending toward media access door 28. Latching bracket 340 is mounted to slide in a track 346 within bezel 100, in the rearward direction indicated by arrow 34~ from the forward position in which it is shown. In this forward position, tab 344 blocks the downward motion of media access door 26 required -to disengage slotted tabs 232 from downward-extending tabs 234 ~shown in Figure 16). In this way, medla access door 26 is lockad in a closed position. As the locking mechanism is rotated from its first position to its second position, the slope of groove 338 moves locking bracket 340 -to the rear, so tha-t tab 344 clears door 26, allowing the downward motion required to begin the process of opening the door. As the locking mechanism is rotated into its third and fourth positions, locking bracket 340 remains in i-ts rearward position, with door 26 unlocked.

Referring to Figure 17, cam 328 also includes a peripheral cam surface 350. ~over latch 29, which is pivotally mountecl in lower bezel 100 by means of a pin 354, is held against this cam surface by an extension spriny 356. The tip of latch 29 includes a notch 358, whlch engages a slot 30 (shown in Figure 3~ to hold top cover 12 in a closecl position. This slot 30 may ~e, for example, formeclin a tab 359 extending from shield 252 (as shown in Figure 23). The top cover is thus locked shut when the lock mechanism is in its first through third -- 2~2~

positions. However, as the lock mechanism is rotated between the third and fourth positions, in the direction of arrow 356, the outward ramped portion 360 of peripheral cam surface 350 moves notch 358 in the direction of arrow 336, releasiny the engagement of this notch 358 with slot 30. In this way, the top cover is locked closed when the lock mechanism is in its first to third positions, to be released as the locked mechanism is rotated into its fourth posi-tion. If top cover 12 is closed while the lock mechanism is in i-ts fourth position, it remains shut but unlocked. If top cover 12 is closed while the lock mechanism is in another position, the angle of tip surface 3~2 moves latch 29 in the direc-tion of arrow 336, to be returned subsequently by means of spriny 356, so that the cover 12 is loc~ed down as it is closed.

Thus, multi-function locking mechanism 299 provides several levels of security without requiring several different keys or different locking mechanisms. The first level of security prevents both unauthorized use of the DASD devices and access to all subassemblies within computer 10. The second level of security allows access to the removable media of DASD devices, while preventing access to subassemblies within the computer.
The computer can be fully functional at this level; it can be used for all normal functions, even when it is necessary to change the media in DASD devices having removable media.
~owever, since access to subassemblies is prevented, theft is expected to be reduced. Theft of sensitive data can also be protected by software means, such as encryption and the re~uirement for a password to operate some or all system functions. The third level of security also permits access to the slots 98a of central support structure 97, while continuiny to prevent access to subassemblies within -th~
computer. The significance o~ this level of security is dependent on the devices moun-ted in these slots 98a. The fourth level of security also permits access to all subassemblies within the computer. This level must be accessed for repair and reconfiguration of the hardware.
While the use of a properly encoded key 300 is required to move locking mechanism 299 among these various levels of ~261~ 9 security, the key 300 may be removed -to leave the mechanism 299 at any such level of security.

While the door operation and locking aspects of the present invention has been shown and discussed in a version of a system including a lower bezel 100 having lower doors lOOa and lOOb, it is understood that various aspects of this invention can readily be applied to a version of the system having lower bezel 14 (shown in Figure 3) without lower doors. Various mechanisms associated with the lower doors, such as lever actuator 284 (shown in Figure 20) and locking bar 296 (shown in Figure lld), would not be included in such a version. While the third position of the locking mechanism, for releasing the doors lOOa and lOOb could be omitted, reducing the number of slots 318 in stator 306 (shown in Figure 22), this difference from the version described above is not required. Similarly, it is possible but not necessary to modify the configuration of cam 32~ by eliminating groove 330 (shown in Figure 17). It is a matter of manufacturing convenience whether such differences are implemented in two different versions of a computer system.

Significant advantages of the present inven-tion, when compared -to the background art, arise from the fact that a level of security may be selected with the key, which is -then removed, causing the system to remain at that level of secur:i-ty. For example, the system may be left in a fully operational state, providing media access for the DASD devices, without exposing the internal subassemblies. The key can be with~rawn and taken away at this or any other level of security. This feature contrasts with locking mechanisms which leave computers of the background art in either a totally locked or a totally unlocked condition.

Provisions for disengaging the top cover 12 from the frame 14 will now be discussed in reference to Figures 24 through 26.
Figure 24 is a fragmentary underneath cross-sectional plan view, taken as indicated by section lines XXIV-XXIV in Figure 7 to show a hinge coupling 104 used for releasably engaging -2l2~

pivot bail 27 with top cover 12. Figure 25 is a fragmentary right side cross-sectional elevation, taken as indica-ted by section lines XXV-~XV in Fiyure 24. This mechanism may be used, for example, in changing the top cover to a different type, providing even greater configurational flexibility. The method chosen for allowing this disengagement requires that the sys-tem must be unlocked to open top cover 12 before the process of disengagemen~ is begun. Thus, the protection afforded by -the multi-functional lockiny mechanism 299 is not compromised by -the provision made for disengaging cover 12 from frame 14.

Referring to Figures 24 and 25, each hinge coupling 104 includes a coupling bracket 370 and a coupling spr:ing 372.
Coupling bracket 370 is welded to metal enclosure 245 of top cover 12 with coupling spring 372 mounted to slide between a crossmember 374 formed as a part of coupling bracket 370 and an adjacent surface of enclosure 246. In this way, coupling spring 372 is assembled during the welding process as a captive part, which can be moved back and forth, but which cannot be removed. Pivot bail 27 is pivotally mounted between a downward curved bracke-t portion 376 of coupling bracket 370 and a downward curved spring portion 378 of coupling spring 372. Frictional engagement between the coupling spring 372 and the surfaces on which it slides ls ensured by curving a central portion of the coupling spring as generally indicated by dashed line 380 before the welding process. Thus, frictional engagement prevents the mo-tion of coupling spring 372 in the absence of externally applied forces.

Pivot bail 27 is disengaged from the hinge coupling 104 by applying pressure -to spring tab 382 in the direction of arrow 384, causing the deflection of spring-tab 382 in the direction of arrow 386, along with the slidiny of coupling spring 372 in the direction of arrow 388. In this way, coupling spring 372 is moved into the position indicated by dashed lines at position 390, opening the space between downward curved spring portion 378 and downward curved bracket portion 376 to release bail 27 as indicated by dashed lines at position 392.

2~2~

Coupling bracket 370 includes a tab 394 extending toward an opening 396 of an adjacent pocke-t 398 formed in coupling spring 372. If an attempt is made to move the spring 372 in the direction of arrow 388 without exerting a downward force on tab 382, pocket 398 is moved over tab 394, so -that this motion in the direction of arrow 388 is limited to a travel distance insufficient to release pivot bail 27. Thus, pulling the outward extending portion 400 of coupling spring 372 does not result in releasing bail 27 from the coupling 104. To release the bail 27, i-t is therefor necessary to open top cover 12, having released latch 29 by means of lock 2~3 (shown in Figure 23), so that a downward force may be applied to deflect spriny tab 382 in the direction of arrow 386. In this way, the ability of the lock mechanism to prevent access to various subassemblies within system unit 10 is maintained.

Hinge coupling 104 may be engaged with pivot bail 27 essentially by reversing the procedure described above. With coupling spring 372 in the open position indicated at dashed lines 390, pivot bail 27 is introduced into the opening provided between downward curving spring portion 378 and downward curving bracke-t portion 376. Coupling spring 372 is then slid in the dlrec-tion opposite arrow 388, as spring tab 382 is pulled downward to cause deflection in the direction of arrow 386.

In order to disengage the top cover 12 from frame unit 14, travel limiting linkage llO, which has been described in reference to ~igures 7 and 8, is disengaged from top cover 12.
Figure 26 shows a pin 115 configured to provide for this disengagement. This pin 115 includes a solid portion 406 extending throuyh a hole in metal enclosure 246 of top coVer 12 to a rivet head 408. Pin ]15 also includes a hollow portion 410 extending inward to engage a pivot hole 412 in upper link 114. Mutually perpendicular slots 413 extend along the length of hollow portion 140, providing flexibility by dividing this portion 114 into four sections. Pin 114 is fas-tened to metal enclosure 246 by ~orming a shoulder portion 414 a-t an end of hollow portion 410. An enlarged portion 416 is also formed a-t 2~ 2 ~

a tip of hollow portion 410, providing a surface over which upper link 114 is snapped to be engaged with, or reLeased from, pin 115. Thus, the top cover 12 must be opened, having been unlocked, for -the removal of link 114 from pin 115, by sliding the link inward on the pin.

While the preceding discussion has been related to the releasable engagement of pivot bail 27, it is understood that hinge coupling 104 could be used with equal effectiveness to establish the releasable engagement of another type of pivot pin structure, such an a hinge pin fastened directly to a frame for pivotally mounting a cover.

Referring again to Figure 3, a long gap, or seam is presented around the interface between top cover 12 and frame 14. Since both metal enclosure 29:6 of top cover 12 and metal enclosure 265 of frame 14 are used to provide shielding for minimizing the emission of electromagnetic energy at radio frequencies, which could otherwise interfere with communication signals, i~
is necessary to provide a number of electrical contact points spaced along this gap. Naturally, this shielding is effective only when the top cover 12 is closed (as shown in Figure 1), but the top cover should be closed for system operation. Some of these contact points are formed at the interface between shield 252 and frame metal enclosure 265, as described above in reference to Figure 16. Others of these contact points are formed through the use of flexible contac-t segments 31, which extend along a downward-extending skirt por-tion 420 at each side of cover metal enclosure 246. ~t each side, the skirt portion 420 fits inside an adjacent side portion 424 of frame enclosure 265, with electrical contact being effect0d between the convex-curved portion of each contact segment 31 and an adjacen.t inner surface of side portion 42~. While the distance required between adjacent contact points depends in part on a number of operating parameters, such as the clock frequencies of computer 10, this method of forming flexible contact segments 31 can readily be used to produce contact spacings of 0.75 to 1.5 inch as typica]ly ref~uired. Similarly the spring tabs 258 (shown in Figures 16 and 18), which ex-tend as ~126119 portions of shield 252 -to contact frame metal enclosure 265, may be placed as close together as necessary for effective shielding. ;

The method used to provide these flexible spring segments 31 will now be explained with reference bei.ng made to Figures 27 and 28. Figure 27 is a fragmentary right side elevational view, showiny the lower front corner portion of top cover 12.
Figure 28 is a fragmentary front elevational view, taken through the centre of a contact seyment 31, as indicated by section lines XXVIII-XXVIII in Figure 27. Referring first to Figure 27, the individual contact segments 31 are formed as "T"-shaped portions of a spring strip 422 extendiny along each skirt portion 420. In the assembly process, spring strip 422 is first fit into a number of essentially triangular apertures 424 in skirt portion 420, with the widened end 426 of each contact segment 31 fitting through an aperture 424. Referring to Figure 28, the "U"-shaped lower portion 428 of spring strip 422 is then welded along the lower edge of skirt portion 420.
The engagement of each widened portion 426 within an aperture ~-424 serves to maintain the convex shape of each contact segment 31. -As shown in Figure 29, specializ.ed mounting bracket configurations may alternately be attached to slot-ted bracket 71, in place of blank brackets 77, to provide additional types of I/0 ~orts or solid-state removable media. For example, a feed-through mounting bracket 450 includes a pair of connectors 452, which are electrically connected by wires 454 and a cormector 456 to a circuit card 458. Connectors 452 carry electrical signals into or out of computer 10 through a slot 74 in bracket 71. A bracket 450 of this kind may be used, for example, to connect audio signals with circuits in computer 10.

A socket 460, built in accordance with -the standards of the Personal Computer Memory Card Industry Association (PCMCIA) is similarly mounted to slotted bracket 71, by means of a socket mounting bracket 462. In accordance with well known standards, 2~2gl~9 socke-t 460 removably accepts a palr of circuit cards, which may be manually inserted into upper and lower slots in the direction of arrow 466. Socket 460 includes a number of terminal pins (not shown), which extend into sockets in an end of card, making electrical contact with terminal springs (not shown) within card 464. Additional mechanisms (not shown3, associated with socke-t 460, are further configured in accordance with well known standards to provide additional features. As a card 464 is inserted, an ejection mechanism (not shown) is conditioned to facilitate the subsequent removal of the card 464. When a pushbutton 468 is depressed, in the direction of arrow 466, an adjacent card 464, the ejection mechanism is released to push an adjacent card 464 partially outward, in the direction opposite arrow 466, thereby facili-tating manual removal of -the card. The terminal pins within socket 460 are electrically connected-to a circuit card 458 by means of a flexible circuit cable 470 and connector 472. Circuit card 458 may be, for example, the system planar board 36 or an option card 62 (shown in Figure 3).

Cards configured to fit into a PCMCIA-type socket 460 are generally available, containing random-access memory, read-only memory wi~h a stored program, or I/0 adapter logic. Cards having random-access memory can be used to expancl system memory, while carcls having read-only memory can be used as a source of external programs, in place of diskettes. Cards with I/0 adapter logic may have cables to p~ripheral devices extending from or otherwise connected to their outward extending edges 476.

Reerring to Figure 30, alternate or additional means for mounting a PCMCIA-type socket 460 to removably accept cards 464 may be provided by attaching a socket frame 478 within the right front corner of frame 14 An access door 480 is provided in lower front bezel to permit access to removable cards 464 and to card ejection pushbuttons 468. This access occurs under an overextending bracket assembly 95 holding speaker 96 and switches and indicators 97. A flexible cable 484 extends under 2 1 ~

B~9-93-029 42 coolin~ fan 34 for connection to planar board 36 by means of a connector 36. As described above in reference to Figure 3, cooling fan 34 is mounted in a position spaced above an adjacent inner surface 52 of frame 14, providing a space suitable for cable routing.

An alternative linkage 490 for suppor-t:iny top cover 12 in a raised position will now be discussed, with particular reference being made to Figures 31 and 32. This linkage 490 is an alternative to the l.inkage 110 previously discussed in reference to Figures 7 and 8 Figure 31 is a partial elevational view showing-the alternative linkaye 490 extending between frame 14 and top cover 12, with top cover 12 in an open position for servicing or reconfiguring s~stem lO. Figure 32 is an exploded isometric view of a friction brake and detent mechanism 492 used to stabilize the linkage 110 with top cover 12 in its open position.

Referring to Figure 31, an alternative linkage 490, fastened at each side between frame 14 and top cover 12 includes a lower link 494 and an upper link 496, pivotally joined through a friction brake and detent mechanism 492. A lower tab 498 of lower link 494 is displaced outward for pivotal attachment to a pin 499 extending inward from a sidewall 500 of frame 14.
Upper link 496 is pivotally attached to upper cover 12 by a hollow pin 115, which has been discussed in reference to Figure 26. Pivoting bail 27 is pivo-tally attached to frame 14 and to top cover 12, being used as previously described with reference to Figurés 2, 7, and 8.

As top cover 12 is pivoted downward, the pivotal connection at friction brake 492 is moved in the direction of arrow 120. In this way, linkage 490 is folded forward to allow the free flow of cooling air through slots 46 in upper cover 12. A notch 508 in upper cover 12 allows this cover 12 to be pivoted downward over the outward spaced tab portion 498 of lower link g94 at each side of frame 14. This notch 508 does not extend upward into the portion of top cover 12 which is externally visible when top cover 12 is closed.

2~2~119 Referring to Figure 32, ].ower link 494 and upper link 496 are pivotally a-ttached by means of a pivot screw 510, which includes a hexagonal shoulder 51Z, a round shoulder 514, and a threaded portion 516. When these items are assembled, hexagonal shoulder 512 engages upper link 496 by means of a hexagonal aperture 518, while also enyaging a bellville spring washer 520 and a detent plate 522 by extending through central hexagonal apertures 524 and 526, respec-tively. Round shoulder 514 of pivot screw 510 extends through hole 528 in thrust plate 530, through hole 532 in lower arm 494, and through hole 534 in thrust washer 536. Threaded portion 516 o~ pivot screw 510 engages a nut 538.

Thus, the opening or closing of top cover 12 (shown in Figure 31) resul-ts in the rotational mo-tion of upper link 496 relative to lower link 494. Bellville spring washer 520 and detent plate 520 are constrained by hexagonal shoulder 512 to turn with upper link 496. Thrus-t plate 530 is held against a thrust surface 540 of lower link 494, being constrained from rotation by a pair of tabs 542 held in slots 544 extending outward from thrust surface 540. As nut 538 is fastened onto threaded portion 516 of pivot pin 510, -the compression of bellville spring washer 520 holds thrust~plate 522 against thrust washer 530, with contact being made particularly between a pair of dimples 546 in detent pla-te 522, directed toward thrust plate 530. When -top cover 12 ~shown in Figure 31) is in its fully open position, each dimple 546 extends into a corresponding deten-t hole 548 in thrust washer 530, providing a tendency to hold top cover 12 fully open.

As top cover 12 is opened or closed, relative rotation occurs at a first interface between detent plate 522 and thrust plate 530 and at a second interface between nut 538 and lower link 494. Detent plate 522 and thrus-t plate 530 are preferably composed of hardened steel, while thrus-t washer 536 is preferably composed of a plastic resin having lubricity, such as an ace-tal ma-terial. A number of widely known techniques for locking nut 538 in place on threaded portion 516 may be employed to prevent the loosening of nut 538 with the opening 2~2~119 BC9-93~029 ~4 -and closing of linkage 490. Such techniques include the -~
adhesive fastening of nut 538 to threaded portion 514 and the provision of an elastomeric insert within the threads of nut 538 or within threaded portion 516.

A motion limiting surface 550 of lower link 494 and a similar motion limiting surface 552 of upper link 496 are offset to contact one another when top cover 12 is fully opened, preven-ting further relative rotation of links 494 and 496.
This position is held by means of the detent function provided by dimples 546 extending into adjacent holes 548. Various parameters, such as the force provided by -the compression of bellville spring washer 520, the shape of dimples 546, and the angle to which links 49~ and 496 are allowed to open before contact occurs between motion limiting surfaces 550 and 552, may be adjusted to provide either a mechanism allowing the closure of top cover 12 applying pressure to top cover 12, or alternately a mechanism preventing the closing of top cover 12 until a force is applied to linkage 492 in the direction of arrow 120.

Figure 33 is a fragmentary isometric view of an alternative mechanism for attaching planar board 36 to frame 14, thereby providing an al-terna-tive to the mechanism previously described in relation to Figures 11 through 13. Thus, alterna-te means for engaging a mounting screw 188, used in the attachment of a planar board 36 to frame 14, include a formed nut 560, a formed spacer 562, and an attachment plate 564. Spacer 562 includes a flange 566 and a tapered hexagonal upstanding portion 568. Similarly, nut 560 includes a flange 570 and a tapered hexagonal upstanding portion 572, which fits inside upstanding portion 568 of spacer 562 to provide a threaded surface 573 for engaging screw 1~8. At-tachment plate 564 includes a hexagonal aperture 574 at each location ~here nut 560 may be placed for fastening a planar board in place.
Hexagonal aperture 574 is used both for locating nut 560 and for preventing its rotation when screw 188 is subsequently tightened to fasten planar board 36 in place. Spacer 562 also includes a number of lanced tabs 578, which snap into ~C9-93-029 45 corresponding slo-ts 580 o~ nut 460 to hold these parts together when they are assembled at a location defined by an aperture 574.

The process of attaching planar board 36 to frame 14 begins with -the assembly of a number of spacers 562 to nuts 560 extending through hexagonal apertures 574 in positions corresponding to locations of mounting holes in planar board 36. In the manner previously described in reference to Figure 11, attachment plate 564 may include several pa-tterns of apertures 574 for a-ttaching several different planar boards.
The assembly thus formed ls attached to frame 14 by means of a number of screws 582 engaging standoffs 584 extending upward from frame 14. Planar board 36 is then installed, with various screws 188 engaging various nuts 560. The configuration of nuts 560 and spacers 562 may subsequently be changed, if necessary, by removing plate 564 from frame 14, and by moving the nuts and spacers around as required. This method may be used, for example, to facilitate upgrading computer 10 by installing another kind of planar board.

The preceding discusslon has been directed to particular examples of the present invention using the ISA bus as an interface to cards, such as option cards 62 (shown in Figure 3) or short option cards 94 (shown in Figure 5). Thus, the connectors 63 on riser card 64 (shown in Figure 4) are of a type compatible with cards configured according to standards for the ISA bus interface. Similarly, slotted bracket 71 provides a mechanical interface compatible with the attachment of the cards configured according to s-tandards associated with the use of the I~A bus. In turn brackets 72 (shown in Figure 3), and the specialized brackets 450 and 462 (both shown in Figure 29) provide a mechanical interface compatible with bracket 72, and also with mounting means provided in various other systems usinq the ISA bus.

As shown in Figure 34, concepts of the present invention can be applied with equal facility, for example, to a system configured to use the IBM "MicroChannel" bus. In this -- 21~6119 example, a riser card 594 includes a number of connectors 596 configured for the a-ttachment of standard option cards 598 using the MicroChannel bus. These connectors 596 are different from the previously described connectors 63 in a number of ways, including the use of a 0.050-inch contact spacing in place of the O.100-inch contact spacing of connectors 63. A
different planar board 600, providing signals for the MicroChannel bus at an interface connector 602, into which riser card 494 is plugged, is also used in this example.

Option card 598 includes provisions for elec-trical grounding which are typically used in systems with the MicroChannel bus.
A slotted mounting structure 604 is provided at the back of the computer system, with features for providing a grounding and mounting interface for standard cards, such as option card 598. This mounting struc-ture 604 is preferably a die cast metallic structure, which may be mounted in the computer in place of slotted bracket 71, having similar means for attachment within the framework of the computer. Since mounting s-tructure 604 is used to provide electrical grounding for option cards 598, suitably grounding is preferably provided for structure 604 through the framework of the computer, or through additional grounding means.

A flexible yrounding bracket 606 is attached as a part of the assembly of card 598 using rivets 608. Card assembly 598 is installed by sliding in the direction of arrow 610, with grounding bracket 606 sliding into an elongated slot 612 of mounting structure 604. As this occurs, a pair of-tabs 614 of grounding bracket 606 slide into slots 615 of mounting structure 604, and with a number of cantilever spring portions 616 of flexible grounding bracket 606 effecting electrical grounding b~ contacting mating surfaces 618 extending along each side of elongated slot 612. Slotted end 620 of grounding bracl~et 614 slides along an outer surface (not shown, but opposite inner surface 621) of mounting structure 604, with slot 622 passing over a threaded stud 624, extending outward in the direction of arrow 626. ~dditional electrical grounding i.s provided by contact between :Elexible tab 628 of grounding 2126~19 ~C9-93-029 47 bracket 606 and an adjacent inner surface 630 of mounting structure 604. Contact -tab 632 of card 598 is simultaneously inserted into the slots 634 of a ccnnector 596, with conductive pacls (not shown) on contact tab 632 making electrical contact with spring contacts (not shown) within connector 596. Card assembly 598 is subse~uently held in place by tiyh-tening a nut 636 on the stud 624, clamping slo-tted end 620 of grounding bracket 606 in place. Nut 636 is preferably of a captive type, which canno-t be removed from stud 624, and which, having a knurled surface, can be tightened by hand. -As also shown in Figure 34, a socket 460, built in accordance wi-th PCMCIA standards as previously discussed in reference to Figure 29, is provided with alternate means for attachment in a structure, such as mounting structure 604, conigured to accept option cards for attachment to the MicroChannel bus.
Thus, socket mounting bracket 638 is formed to include a slotted tab portion 640 and a pair of mounting tabs 642. A
flexible grounding bracket 644, attached -to soc~et mounting bracket 638 by means of rivets 646, includes features of grounding bracket 606, such as can-tilever spring portions 616 ~-and a flexible tab 628.
:: :.
When the socket assembly thus formed is installed in a slot 612 by slidiny in the direction of arrow 610, electrical grounding is effected as described above, through contact between cantilever spring portions 616 and flexible tab 62 of grounding bracket 644. Socket assembly 630 is subsequen-tly held in place, and a ground connection capable of carrying high currents is established with slotted tab portion 640, by tightening a nu-t 636 on a threadecl stud 624.
As further shown in Figure 34, riser car~ 394 includes an electrical interface for a PCMCIA-type socket a-t a connector 650, to which socket 460 is attached by means of a mating connector 652 and a flexible cable 654.

The application of various aspects of-the present invention to a personal computer having additional capahilities achieved through the use of an enlarged top cover will now be discussed ~2~

BC9~93-029 48 in reference to Figures 35 through 37. Figure 35 is an isometric view of this expanded personal computer 660 with the enlarged top cover 662 in an open position. Figure 36 is a partial right cross-sectional elevation of computer 660, with top cover 662 in a closed position, taken along section lines XXXYI-XXXVI in Figure 35, in the manner of previously-discussed Figure 16, showing particularly the arrangement of access doors and of the space ad~acent to these doors. Figure 37 is a partial cross-sectional elevation showing a sliding link 663 used in locking media access door 26, taken along section lines XXVII-XXVII in Figure 35.

Referring first to Figure 35, an enlarged top cover 662 may be installed in place of top cover 12 (shown, for example, in Figure 6). Specifically, the sides 664 of the top cover enclosure 665 and the upper bezel 668 of top cover 662 are e~tended downward to provide space under DASD devices 88 and 93, which are attached to the top cover 662 by means previously ~escribed in reference to Figures 9 and 10. The : media access door 26 of previous configurations fits into an ope~ing in the upper portion of front bezel 668, and two intermediate access doors 670 are pivotally mounted in openings below door 26. This enlarged cover 662 is mounted to the frame unit 14 of previously discussed versions of the computer. Frame 14 includes a front bezel 100 having a pair of pivotable doors lOOa and lOOb. The same means for pivotable attachment, consisting of travel limiting linkages 110 and of pivoting bail 27, which have been described in reference to Figures 7 and 8, are used. Since -the attachment positions of pivoting bail 27 remain in the location previously described for computer 10, despite the larger top cover 662, a rear panel 672 is added to the metal enclosure 665 of top cover 662. Previ.ously described means for the releasable attachment of linkages 110 and of pivoting bail 27. A pair of hinge couplings 104, which are described above in reference to Figures 24 and 25, are attached to rear panel 672. Linkages 110 are attached to enlarged top cover 662 by means of snap~
flt couplings 115 as previously described in reference to Figure 26.

2~2~

The b0nefits of this approach are best seen by comparing :~
Figures 16 and 36, which are, respectively, right side cross-sectional elevations of computer 10, with the conventional top cover 12, and of computer 660, with an enlarged top cover 662.
In computer 660, additional space is provided below shield 674, which is similar to shield 252, except for a downward-extending portion 676, which engages the upper edge portion 268 of metal enclosure 265 of frame lg. Thus, shield 674 provides a place for storing media access door 26 in an open, horizontal position, as indicated at dashed lines 230, and as previously described in reference to Figure 16. In computer 10, the space between transverse duct 38 and shield 252 is limited so that "H"-shaped central support structure 97 has ~8 room for only a single slot 98a on each side of central support member 99 ~also shown in Figure 6). On the other hand, in computer 660, there is enough dis-tance between transverse duct 38 and shield 674 -to allow space for both an upper slot 678 and a lower slot 680 on each side of central support member 682 of enlarged "H"-shaped central support structure 684. Downward-extending portion 676 includes a slot 685 to provide access to each upper slot 678.

Referring again to Figure 35, these slots 678 and 680 in front slotted bracket 682 of central support s-tructure 684 may be used for mounting the card bracket 72 of a short option card 94 or for mounting the a specialized mounting bracket configuration, such as one of the confiyurations discussed above in reference to Figure 29. For example, socket mounting bracket 462 can be used to mount a PCMCIA-type socket 460, with a cable 470 extending to a be connected to a riser card (not shown) within central support structure 684.

In both the enlarged version of Figure 35 and the smaller version of Fiyure 6, this type of mounting for socket 460 is feasible and particularly desirable, since the cards 464 inserted into the socket 460 and the associated card ejection buttons 468 are accessible from the front of the computer with the appropriate doors open. Thus, these advantages are achieved either by attaching socket mounting bracket 462 to 212~

front slotted bracket 682 of computer 660 or to front slotted bracket 98a of computer 10 (shown in Figure 6).

Referring again to Figure 36, lower slots 680 are accessed through lower doors lOOa and lOOb, while upper slots 678 are accessed through intermediate doors 670. These doors 670 are mounted to rotate between a closed (vertical) position and an open (horizontal) position, as indicated at position 686 by dashed lines, in the manner of lower doors lOOa and lOOb, as previously described in reference to Figures 16, 17, and 20.
A second lever actuator 284 (shown in Figure 35), between these doors 670 in top cover 662 is added -to provide means for manually opening and closing doors 670.

A separate locking mechanism is not needed for intermediate doors 670. As these doors are pivoted open, their lower edges traverse a curved path 6~8 as indicated by a dashed line, contacting the upper edges of doors lOOa and lOOb if these doors lOOa and lOOb are closed. Thus, doors lOOa and lOOb must be opened before doors 670 can be opened. In this way, the use of lock 28 to determine whether doors lOOa and lOOb can be opened is extended to provide a similar determination relati~e to doors 670.

The use of a cam 328 rotated by a lock 28 to move a locking bracket 340 has been discussed in reference to Figure 23.
Since the same frame unit 14 is used in computer 660, the multi-function locking mechanism 299 is also available in computer 660. In computer 10, when locking bracket 344 is moved in the direction of arrow 348, access door 26 can be moved downward for opening. When locking bracket 344 is returned in the direction opposite arrow 348, the downward motion required to begin the process of opening the door is blocked. Referring to Figure 37, in computer 12 a sliding link 690 is added to prevent downward motion of door 26 from its position in cover bezel 668. This link 690, which is arranged to slide vertically in a track 692, includes a -tab 694 extending under door 26 to block downward motion of the door and an inclined surface 696 engaging locking bracket 344. When 2~2~

locking bracke-t 344 is held in the direction opposite arrow 348, the downward motion of sliding link 690, resulting from an attempt to open door 26, is prevented by contact between inclined surface 696 and locking bracket 344. When locking bracket 344 is moved in the direction of arrow 348 this motion is allowed to occur. When locking bracket 348 is returned in the direction of arrow 348, the angle of inclined surface 696 returns sliding bracket 694 upward.

The preceding discussion has described a number of versions of -the present invention having means for pivo-tally mounting a top cover along rear edges of the top cover and of -the frame unit. ~owever, as shown ln Figures 38 and 39, the present invention may alternately be applied to a personal computer 700 in which a top cover 702 is pivotally mounted along an attachment side 704, extending from front to rear of a frame unit 706. Eigure 38 is a front elevational view of the computer 700 with its top cover 702 rotated upward into the position re~uired for service and reconfiguration. Figure 39 is a partial cross-sectional right side elevational view taken as indicated by section lines XXXIX-XXXIX in Figure 38. In the example of F.igure 38, the right side of computer 700 is used as the attachment side 704. The following discussion describes the example of computer 700, with items having similar functions and charac-teristics as those previously described being accorded like reference numerals.

Referring first to Figure 38, a top cover 702 is pivotally attached along an upper edge of attachment side 704 by means of a pair of l~U"-shaped formed hinge rods 707 fastened to the side 70~, for e~ample, by welding. Top cover 702 is preferably mounted to pivot on hinge rods 707 by means of a pair of releasable hinge couplings 104, which have been described in detail referring to Fiyures 24 and 25. In this way, top cover 702 can be easily removed af-ter it is opened. A -travel-limiting linkage 110, which has been described in detail referring to Figures 7 and 8, is also used to stop the opening rotation of top cover 702. This linkage 110 of compu-ter 700 is in an inverted relationship with the linkage 110 of computer ~12~119 10, so that contact between tab 118 and stopping surface 121 prevents motion in the direction of arrow 708, away from the pivot axis determined by hinge rods 707, instead of in the direction of arrow 120 (as shown in Figure 8) toward the pivot axis determined by upper rod portion 27 of pivot bail 27 in computer 10. Thus, as upper cover 702 is closed, linkage 110 folds toward the pivot corner, in the direction opposite arrow 708, instead of away from the pivot corner, in the direction opposite arrow 120 (as shown in Figure 8). In this way, an adjacent area 710, in which a DASD unit may be placed in engagement with a channel 86 of top cover 102, is not compromised by a need to accept the folding of linkage llO as top cover 102 is closed. The o~fset of central pivot 116 from a line between upper pivot 115 and lower pivot 113 (shown in Figure 8) is retained to provide a means for holding the top cover open (as described in reference to Fi~ures 7 and 8).
After top cover 702 is fully open, it is necessary to push the central portion o~ linkage 110 in the direction opposite arrow 708 to begin the process of closing top cover 702.

Continuing to refer to Figure 38, various ~eatures of computer 10 are retained in computer 700. For example, a central support structure 79 includes a riser card 64, which is plugged into a planar board 36 at a planar board connector 65 (as shown in Figure 4). Riser card 64 includes a number of attached connectors 63 in-to which option card assemblies 62 may be plugged. Cen-tral support structure 79 includes a slotted bracket 71, to which brackets 72 of card assemblies 62 are attached by means of screws 73. Top cover 702 includes a bracket 124, with slotted channels 86, internally attached by welding, to which DASD storage devices 88 and 93 may be in turn attached in the manner previously discussed in re~erence to Figures 9 and lO.

Re~erring to Figure 39, like computer lO, computer 700 includes a media access door 26 which is manually movable between a vertical closed position and a horizonal open position indicated by dashed lines at position 230. However, in computer 700, the shield 712 forming a pocket for door 26 2 ~

BC9-93~029 53 in its open position does not move upward with top cover 702 as this cover is opened. Metal enclosure 714 of frame unit 706 includes an upstanding portion 716 to which shield 712 is attached. Metal enclosure 718 of top cover 702 includes a downward extending portion 720, which engages a front lip 722 and a number of spring tab portions 724 of shield 712. Slotted tab`s 232 of door 26 engage a downward formed lip portion 726 of cover enclosure 718 to hold door 26 in a closed position.

Referring to Figures 38 and 39, a rotary lock 28 with an attached cam 728 is used to provide the functions of locking top cover 702 and media access door 26 in closed positions. In the general manner previously discussed in reference to Figure 23, as lock 28 is rota-ted with an inserted encoded key, a sliding bracket 730 is moved by a groove 732 between a forward position in which downward motion of door 26 is permitted to a rearward position in which such motion is permitted. Since shield 712 remains in place as -top cover 702 is opened, a connecting link 734 is used to transmit the motion provided by a peripheral surface 736 of cam 728 between a cam follower 738 pivoted at a pin 740 and a cover latch 742 pivoted at a pin 744. Top cover 702 includes a latching bracket 748, which engages latching surface 750 of cover latch 7~2 when lock 28 is rotated -to allow the motion of this latch 742 in the direc-tion of arrow 752. Cam follower 738 is held against peripheral cam surface 736 by means of an extension spring 754.

An advantage of relative simplicity is achieved by employing the methods shown in Figures 38 and 39, in that a simple pivot along -the upper edge of frame attachmen-t sida 704 is used in -the attachment of top cover 702. That is, a bail pivotally mountecl to both the frame and cover, as described in reference to Figures 2, 7, and 8, is no-t re~uired. This simplicity is not simply due to pivoting the cover on the side instead of in the back; it is due to the fact that, in the computer of Figures 38 and 39, the central attachment structure 79 can be removed without moving the top cover with attached DASD
devices away from the frame 706. Howev~r, even in this 212~119 configuration, a pivotable bail of the type shown in Figures 2, 7, and 8 would possess some benefits in facilitating the removal of the power supply (not shown, but placed in the location of power supply 32 of Figure 3). Also, it is understood that a rearrangemen~ of internal components could result in a configuration haviny a top cover pivoted along the rear without a requirement for-the cover to be moved away from the frame as i-t is opened.

While the invention has been described in its preferred forms or embodimen-ts with some degree of particularity, it is understood that this description has been given only by way of e~ample and that numerous changes in the details of construction, fabrication and use, including the combination and arrangement of parts, may be made without departing from the spirit and scope of -the invention.

Claims (40)

1. Personal computer apparatus comprising:
a frame section with a generally flat lower side, a front frame bezel, a rear frame opening, and an open side opposite said lower side;
a planar board assembly fastened within said frame section, by planar board attachment means, to said lower side, said planar board assembly including a riser connector directed toward said open side;
a central support structure for electrically connecting option card assemblies with said planar board, said central support structure including a riser card engaging said riser connector, a plurality of card connectors on said riser card electrically connected through said riser card to said riser connector, and a rear attachment framework extending within said rear frame opening, wherein said rear attachment framework includes a plurality of rear slots extending therethrough and means for attaching a plurality of card assemblies of a first type in alignment with said rear slots and in engagement with various of said card connectors;
a top cover with an upper side and an open side opposite said upper side;
a storage device attached to said upper side, extending below said upper side, by storage device attachment means; and cover attachment means attaching said top cover to said frame section along a cover attachment edge of said top cover and along a frame attachment edge of said frame section, permitting pivotal movement of said top cover between a closed cover position, in which said central support structure is held in engagement with said riser connector, and an open cover position in which said central support structure can be disengaged from said riser connector.
2. Apparatus as recited in Claim 1, wherein said cover attachment means includes:
a pivotable bail with an upper bail portion on which said cover attachment edge is pivotally mounted, and a lower bail portion pivotally mounted along said frame attachment edge for pivotal movement between an inward position, in which said top cover is in said closed cover position, and an outward position, in which said top cover is in said open cover position;
first holding means for holding said top cover in said open cover position; and second holding means for holding said pivotable bail in said outward position.
3. Apparatus as recited in Claim 2, wherein:
said pivotable bail includes an end portion extending between said upper portion and said lower portion at each end, each said end portion including an inward extending portion;
and said second holding means includes stopping surface contacted by each said inward extending portion, wherein the deflection of said inward extending portion in contact with said stopping surface results in the development of a frictional force holding said pivotable bail in said rearward position.
4. Apparatus as recited in Claim 2, wherein:
said cover attachment edge extends along a rear edge of said top cover; and said top cover includes a front cover bezel extending above said frame bezel with said top cover in said cover closed position.
5. Apparatus as recited in Claim 1, wherein:
said cover attachment edge extends along an upper side of said cover; and said frame attachment edge extends along an upper side of said frame, adjacent to said cover attachment edge.
6. Apparatus as recited in Claim 5, wherein:
said frame attachment edge extends rearward from said front bezel, along a side cover of said frame; and said front frame bezel extends between said lower side of said frame and said upper side of said top cover.
7. Apparatus as recited in Claim 1, comprising in addition:
a media access opening adjacent to said storage unit:
a media access door with an upward extending door latching slot and an outward extending pivot pin portion at each end;
a downward extending door latching surface extending into said upward extending door latching slot when said media access door is in a closed door position filling said media access opening;
a pocket for storing said media access door in a door open position, essentially perpendicular to said closed door position, below said storage device;
a door track at each end of said media access door, wherein said pivot pin portions extend into upper front corner portions of said door tracks when said media access door is in said closed door position, with a first portion of each said door track extending to permit downward motion of said pivot pin from said upper front corner portion, with a second portion of each said door track extending to permit rearward motion of said pivot point from said upper front corner portion as said media access door is moved into said door open position; and spring means for holding said media access door upward in said closed door position.
8. Apparatus as recited in Claim 7, wherein:
said frame section and said top cover together form an outer conductive structure enclosing electronic apparatus; and said pocket is formed by a "U"-shaped shield with an opening for receiving said media access door, said shield being in contact with portions of said outer conductive structure when said top cover is in said cover closed position.
9. Apparatus as recited in Claim 7, comprising in addition a locking mechanism operable by an encoded key and movable between a first position, blocking downward motion of said media access door from said closed door position, and a second position, allowing downward motion of said media access door from said closed door position.
10. Apparatus as recited in Claim 9, wherein:
said top cover additionally includes a cover latch engaging surface;
said frame section additionally includes a cover latch movable between a cover latched position, in which said top cover is held in said closed cover position by engagement of said cover latch engaging surface with a notch in said cover latch, and a cover unlatched position, in which said cover latch engaging surface is released from said notch, thereby releasing said top cover to pivot into said open cover position; and said locking mechanism is additionally movable into a third position in which said cover latch is moved from said cover latched position into said cover unlatched position.
11. Apparatus as recited in Claim 10, wherein said locking mechanism includes:
a lock with a lock rotor rotatable among first, second, and third angular positions when said encoded key is inserted therein;
a door locking bracket movable between a first bracket position, in which an end of said door locking bracket prevents downward motion of said media access door and a second position in which downward motion of said media access door is permitted; and a cam attached to said lock rotor, said cam including a first cam surface moving said door locking bracket between said first and second bracket positions, said cam additionally including and a second cam surface moving said cover latch between said cover latched position and said cover unlatched position.
12. Apparatus as recited in Claim 10, wherein:
said apparatus additionally includes an intermediate access opening and an intermediate access door mounted to moved between an intermediate open position and an intermediate closed position, filling said intermediate access opening; and said locking mechanism is additionally movable between a position in which said intermediate door cannot be moved from said intermediate closed position, and a position in which said intermediate door can be moved from said intermediate closed position.
13. Apparatus as recited in Claim 12, wherein said locking mechanism includes:
a lock with a lock rotor rotatable among first, second, third and fourth angular positions when said encoded key is inserted therein;
a media door locking bracket movable between a first bracket position, in which an end of said door locking bracket prevents downward motion of said media access door and a second position in which downward motion of said media access door is permitted;
an intermediate door locking member movable between an intermediate locking position blocking motion of said intermediate door between said intermediate closed position and said intermediate open position and an intermediate releasing position allowing movement between said intermediate closed position and said intermediate open position; and a cam attached to said lock rotor, said cam including a first cam surface moving said door locking bracket between said first and second bracket positions, a second cam surface moving said cover latch between said cover latched position and said cover unlatched position, and a third cam surface moving said intermediate door locking member between said intermediate locking position and said intermediate releasing position.
14. Apparatus as recited in Claim 12, wherein:
said intermediate access door is mounted to pivot with a door shaft having a sector gear;
said frame structure additionally includes a movably mounted actuator with a lever extending outward through an aperture in said frame structure, said actuator having gear teeth engaging said sector gear.
15. Apparatus as recited in Claim 1, comprising in addition:
a lower link pivotally mounted at a lower pivot on said frame section;
an upper link pivotally mounted at an upper pivot on said top cover, said upper and lower links being pivotally attached at a central pivot; said central pivot moving in a linkage opening direction between first and second positions as said top cover is moved between said closed and open positions, said second position being offset in said linkage opening direction from a line through said lower and upper pivots when said cover is in said cover open position; and
16. Apparatus as recited in Claim 1, comprising in addition:
a lower link pivotally mounted at a lower pivot on said frame section;
an upper link pivotally mounted at an upper pivot on said top cover, said upper and lower links being pivotally attached at a central pivot; and detent means at said central pivot, resisting relative movement of said lower and upper links as said cover is moved from said open cover position toward said closed cover position.
17. Apparatus as recited in Claim 16, wherein said detent means includes:
a detent surface of said upper link, disposed adjacent to said central pivot, said detent surface including a detent notch;
a detent plate mounted to slide along said central pivot and to pivot with said lower link, said detent plate including a curved surface extending into said detent notch when said top cover is in said open cover position; and a detent spring holding said detent plate in contact with said detent surface.
18. Apparatus as recited in Claim 1, wherein said central support structure additionally includes a front attachment framework having a plurality of front slots extending there-through and means for attaching a plurality of card assemblies of a first type in alignment with said front slots and in engagement with various of said card connectors.
19. Apparatus as recited in Claim 18, comprising in addition an intermediate door in alignment with one of said front slots, movable between an intermediate door closed position and an intermediate door open position.
20. Apparatus as recited in Claim 18, comprising in addition:
a socket assembly for removably receiving a circuit card of a second type, said socket assembly including a plurality of socket contacts for establishing electrical contact with a plurality of mating contacts along an end of said second type of circuit card inserted therein;
an ejection mechanism for facilitating removal of said second type of circuit card; and a bracket attaching said socket assembly and said ejection mechanism to said front attachment framework in alignment with one of said front slots for inserting and ejecting said circuit card of a second type therethrough.
21. Apparatus as recited in Claim 20, including in addition:
processor means;
a system bus extending from said planar board through said riser connector and through traces in said riser card to said card connectors; and a second bus interface extending from said planar board through said riser card for direction connection to a said socket assembly.
22. Apparatus as recited in Claim 1, comprising in addition:
a socket assembly for removably receiving a circuit card of a second type, said socket assembly including a plurality of socket contacts for establishing electrical contact with a plurality of mating contacts along an end of said second type of circuit card inserted therein;

an ejection mechanism for facilitating removal of said second type of circuit card; and a bracket attaching said socket assembly and said ejection mechanism to said front attachment framework in alignment with one of said rear slots for inserting and ejecting said circuit card of a second type therethrough.
23. Apparatus as recited in Claim 1, wherein said cover attachment edge is pivotally mounted on a pivot rod by releasable means comprising:
a bracket attached to said top cover, with a pivot engaging tip extending partly around said pivot rod; and a pivot holding member with a pivot holding tip extending partly around said pivot rod, said pivot holding member being movable between a pivot holding position in which said pivot rod is pivotally held between said pivot engaging tip and said pivot holding tip, and a pivot releasing position in which said pivot rod is released for movement away from said releasable means.
24. Apparatus as recited in Claim 23, wherein:
said bracket includes a release stopping tab engaging a stop surface of said pivot holding member, to prevent motion of said pivot holding member from said pivot holding position into said pivot releasing position; and said pivot holding member includes a deflectable tip enclosed by said top cover when said cover is in said cover closed position, said tip being deflectable to move said stop surface past said release stopping tab.
25. Apparatus as recited in Claim 23, wherein said releasable means can engage any one of a plurality of different top covers.
26. Apparatus as recited in Claim 1, including in addition:
processor means; and a system bus extending from said planar board through said riser connector and through traces in said riser card to said card connectors.
27. Personal computer apparatus as recited in Claim 1, wherein said planar board attachment means includes:
a planar board mounting plate extending above said generally flat lower side of said frame section, said mounting plate including an attachment aperture;
a nut having a raised central nut portion extending upward through said attachment aperture, with an internally threaded hole in said central nut portion, and with a nut flange extending outward from an outer edge of said central nut portion under a portion of said mounting plate around said aperture;
a spacer having a raised central spacer portion extending over and around said central nut portion and a spacer flange extending outward from an outer edge of said central spacer portion over a portion of said mounting plate around said attachment aperture;
means for locking said nut in engagement with said spacer as said central spacer portion is pressed downward over said central nut portion;
an attachment screw having a head above said planar board and an externally threaded portion extending downward through a hole in said planar board and through said clearance hole in said spacer to engage said internally threaded hole in said nut, whereby tightening said screw clamps said planar board between said head and said spacer while also clamping said mounting plate between said spacer flange and said nut flange.
28. Apparatus as recited in Claim 27, wherein:
said nut flange is divided into a number of flange segments extending radially outward; and said mounting plate includes a number of plate segments extending radially inward, providing a shape thereamong through which said nut flange can pass, and said mounting plate additionally includes a means for preventing rotation of said nut flange beyond a point at which said flange segments extend adjacent to said plate segments.
29. Apparatus as recited in Claim 27, wherein:
said attachment aperture is non-circular; and said central nut portion includes non-circular sides extending through said attachment aperture, preventing rotation of said nut within said attachment aperture.
30. Apparatus as recited in Claim 27, wherein:
said mounting plate includes a first plurality of attachment apertures, said attachment apertures being at locations corresponding to attachment holes of various planar boards; and said apparatus includes a second plurality of said nuts, said spacers, and said attachment screws, assembled within a subset of said attachment apertures.
31. Apparatus as recited in Claim 1, wherein:
said top cover includes a plurality of slotted channels extending downward from said upper side for the attachment of storage devices, each said channel including a plurality of device attachment slots and a latching spring for holding one of said storage devices in attachment with an adjacent said slot; and said storage device attachment means includes an attachment hook extending into one of said device attachment slots, held therein by said latching spring.
32. Apparatus as recited in Claim 1, wherein said top cover includes in addition a hook for attachment of said central support structure when said top cover is in said open cover position and when said central support structure is disengaged from said riser connector.
33. Electronic apparatus comprising:
a frame unit with a generally flat lower side, an open upper side, and a bracket aperture in a first side;
a cover unit with an upper side an open lower side, attached to said frame unit to move between a cover closed position, in which internal apparatus is enclosed by said cover unit together with said frame unit, and a cover open position, in which said internal apparatus is outwardly exposed;

a central support assembly including a central support structure with a first slotted bracket extending within said bracket aperture, said first slotted bracket including a plurality of card assembly attachment slots extending therethrough, said first slotted bracket additionally including card attachment means in alignment with said card attachment slots, said central support structure additionally including a riser card with a plurality of circuit card connectors electrically connected with said central attachment connector, various of said circuit card connectors being individually aligned with various of said card assembly attachment slots, said central support assembly additionally including a first type of circuit card assembly plugged into one of said circuit card connectors, said circuit card assembly including a port connector extending outward through one of said card attachment slots, wherein said central support assembly can be disconnected from said central attachment connector and removed therefrom with said cover unit in said open cover position, and wherein said central support structure is held in connection with said central attachment connector by proximity of said cover unit to said central support structure when said cover unit in said closed cover position.
34. Electronic apparatus as recited in Claim 33, wherein:
said central support assembly additionally includes a second slotted bracket, extending at an end of said central support assembly opposite said first slotted bracket, and a socket assembly for removably receiving a second type of circuit card through a slot in said second slotted bracket, together with an ejection mechanism for facilitating removal of said second type of circuit card from said socket, said socket assembly including a plurality of socket contacts for establishing electrical contact with a plurality of mating contacts along an end of said second type of circuit card inserted therein, and said apparatus additionally includes a lockable access door covering said slot in said second slotted bracket.
35. Apparatus for interchangeably mounting either a first type of circuit card assembly, having a card attachment bracket and an edge tab configured for insertion into a card edge connector, or a socket assembly for removably receiving a second type of circuit card, together with an ejection mechanism for facilitating removal of said second type of circuit card, said socket assembly including a plurality of socket contacts for establishing electrical contact with a plurality of mating contacts along an end of said second type of circuit card inserted therein, said apparatus comprising:
a central electronic structure including a card receiving connector for removably receiving said edge tab, a slotted attachment structure including a structure slot through which a terminal connector of said first type of card assembly may extend, and structure attachment means for attaching said card attachment bracket with said edge tab engaging said card edge connector;
a socket attachment bracket attached to said socket assembly, said socket attachment bracket having bracket attachment means connectable with said structure attachment means with said socket assembly aligned to accept said second type of circuit card inserted through said structure slot.
36. Apparatus as recited in Claim 35, wherein:
said apparatus comprises in addition a housing with a movable cover and a planar board with an interconnection connector; and said central electronic structure comprises in addition an interconnection card held in connection with said interconnection connector by said cover in a closed position thereof and released from such connection as said cover is opened.
37. Apparatus for providing controlled physical access within a computer system, said apparatus comprising:
a cover assembly including a frame and a top cover movable between a closed cover position and an open cover position;
a media access door movable between a closed media door position and an open media door position, in which media may be replaced in a storage device;
a lock having a rotor rotatable among first, second, and third lock positions when a properly encoded key is inserted in a slot thereof, said second lock position being disposed between said first and third positions, said lock rotor not being rotatable between adjacent said lock positions when said key is not inserted in said slot;
first locking means moved by rotation of said lock;
cover locking means moved by said first locking means between a cover locking position, in which said cover is held in said closed cover position, and a cover releasing position, in which said cover is released from said closed cover position, wherein said cover locking means is in said cover locking position when said lock is in said first and second lock positions, wherein said cover locking means is in said cover releasing position when said lock is in said third lock position;
media door locking means moved by said first locking means between a media door locking position, in which said media access door is held in said closed media door position, and a media door releasing position, in which said media access door is released from said closed media door position, wherein said media door locking means is in said media door locking position when said lock is in said first lock position and in said media door releasing position when said lock is in said second and third lock positions.
38. Apparatus as recited in Claim 37, wherein:
said apparatus comprises additionally track means for allowing the downward depression of said media access door, the outer rotation of an upper surface of said media access door, and the inward sliding of said media access door into a door receiving pocket, said outer rotation being prevented without said downward depression by engagement of said media access door with a latching portion of said cover assembly, said first locking means includes a cam attached to said lock rotor, having a first cam surface moving said cover locking means and a second cam surface moving said media door locking means;
said cover locking means includes a latch movably mounted in said frame and a latching surface attached to said top cover, said latch being moved between a cover locking position, engaging said latching surface, and a cover releasing position, releasing said latching surface;
said media door locking means includes a bracket mounted to move between a media door locking position, in which said downward motion of said media access door is blocked by an end of said bracket, and a media door releasing position, in which said media access door is allowed to move downward past said end of said bracket.
39. Apparatus as recited in Claim 38, wherein:
said apparatus additionally comprises an intermediate access door, rotatable with a pivot shaft between a closed intermediate door position and an open intermediate door position, in which access can be obtained to an intermediate area within said computer system, with said apparatus additionally comprising a door actuator with a gear segment meshing with a pivot gear on said pivot shaft, said apparatus additionally comprising intermediate door locking means, moved by said first locking means between an intermediate door locking position, in which said door actuator is held with said intermediate door in said closed position, and an intermediate door releasing position, in which said door actuator is released to move said intermediate door from said closed intermediate door position into said open intermediate door position;
said lock rotor is additionally rotatable to a fourth lock position between said second and third lock positions, said cam additionally includes a third cam surface moving said intermediate door locking means; and said intermediate locking means is in said intermediate door locking position with said lock rotor in said first and second lock positions and in said intermediate door unlocking position with said lock in said third and fourth lock positions, wherein said cover locking means is in said cover locking position with said lock rotor in said fourth lock position, and wherein said media door locking means is in said media door releasing position with said lock rotor in said fourth lock position.
40. Apparatus as recited in Claim 37, wherein:
said apparatus additionally comprises an intermediate access door movable between a closed intermediate door position and an open intermediate door position, in which access can be obtained to an intermediate area within said computer system, with said apparatus additionally comprising intermediate door locking means moved by said first locking means between an intermediate door locking position, in which said intermediate door is held in said closed position, and an intermediate door releasing position, in which said intermediate door may be moved from said closed intermediate door position into said open intermediate door position;
said lock rotor is additionally rotatable to a fourth lock position between said second and third lock positions, wherein said intermediate locking means is in said intermediate door locking position with said lock rotor in said first and second lock positions and in said intermediate door unlocking position with said lock in said third and fourth lock positions, wherein said cover locking means is in said cover locking position with said lock rotor in said fourth lock position, and wherein said media door locking means is in said media door releasing position with said lock rotor in said fourth lock position.
CA 2126119 1993-10-08 1994-06-17 Personal computer with configurational flexibility and service features Abandoned CA2126119A1 (en)

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US134,199 1993-10-08
US08/134,199 US5495389A (en) 1993-10-08 1993-10-08 Personal computer with configurational flexibility and service features

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EP (1) EP0647897B1 (en)
JP (1) JP2561808B2 (en)
KR (1) KR0129939B1 (en)
CN (1) CN1091894C (en)
AT (1) ATE182994T1 (en)
BR (1) BR9403997A (en)
CA (1) CA2126119A1 (en)
DE (1) DE69419862T2 (en)
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EP0647897A3 (en) 1995-10-25
CN1104347A (en) 1995-06-28
US5495389A (en) 1996-02-27
KR0129939B1 (en) 1998-04-15
TW286377B (en) 1996-09-21
EP0647897A2 (en) 1995-04-12
JPH07152457A (en) 1995-06-16
CN1091894C (en) 2002-10-02
US5598318A (en) 1997-01-28
BR9403997A (en) 1995-06-20
JP2561808B2 (en) 1996-12-11
DE69419862T2 (en) 2000-02-24
EP0647897B1 (en) 1999-08-04
KR950012187A (en) 1995-05-16
ATE182994T1 (en) 1999-08-15
DE69419862D1 (en) 1999-09-09

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