Search Images Maps Play YouTube News Gmail Drive More »
Sign in
Screen reader users: click this link for accessible mode. Accessible mode has the same essential features but works better with your reader.


  1. Advanced Patent Search
Publication numberUS3017636 A
Publication typeGrant
Publication dateJan 23, 1962
Filing dateNov 4, 1957
Priority dateNov 3, 1956
Publication numberUS 3017636 A, US 3017636A, US-A-3017636, US3017636 A, US3017636A
InventorsWolfgang Koennecke
Original AssigneeElastic Ag Vormals M Vogel A G
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Stapling apparatus
US 3017636 A
Abstract  available in
Previous page
Next page
Claims  available in
Description  (OCR text may contain errors)

Jan. 23, 1962 w. KOENNECKE- STAPLING APPARATUS 2 Sheets-Sheet 1 Filed Nov. 4, 1957 Jan. 23., 1962 w. KOENNECKE STAPLING APPARATUS 2 Sheets-Sheet 2 Filed Nov. 4, 1957 United States Patent Orifice 3,017,636 Patented Jan. 23, 1962 This invention relates to stapling devices.

It is an object of the invention to provide an improved stapling device.

Another object of the invention is to provide a stapling device adapted for holding multiple staples and for driving these staples singly with a variable number of strokes.

Briefly, in accordance with the invention, there is provided an apparatus comprising a frame having means for accommodating one or more staples or fasteners and further having a fastener driving channel through which the fasteners can be expelled; Moreover, there is provided a driver attached to an anvil movably supported on the frame and within the fastener driving channel for purposes of ejecting fasteners out of said channel. The invention further contemplates the use of a hammer movable independently of the anvil for striking the latter in order to cause the driver to eject a fastener which is aligned with the driving channel. Furthermore, the invention employs electromagnetic principles for actuating the hammer in order to make the same forcibly contact the anvil, whereby the latter performs its function.

The above objects and features of the invention, as well as the advantages thereof, will be better understood from the following detailed description of the preferred embodiment of the invention, as illustrated in the accompanying drawing, in which:

FIG. 1 is a side view substantially in section of an e m'bodiment of the invention in connection with which a source of direct-current electrical power is employed;

FIG. 2 is a diagrammatic view illustrating the electrical circuits associated with the embodiment illustrated in FIG. 1; and

FIG. 3 diagrammatically illustrates an embodiment of the invention wherein there is provided a frame comprising pivotally connected sections and in association with which is employed a source of alternating-current electrical power; and

FIG. 4 is a sectional view taken on the line 44 of FIG. 1.

The stapling device illustrated in FIG. 1 comprises generally a frame F, in which is supported a hammer 1 shown in its normal position of rest and susceptible of being displaced vertically downwards under the influence of an electromagnetic coil 2, which is actuated as.will hereinafter be described. The apparatus further comprises an auxiliary electromagnetic relay 3 the purpose of which will become hereinafter apparent.

Also supported Within the frame F is an anvil 11, shown in the position it assumes at the beginning of a stapling operation, the anvil 11 being so positioned that it is struck by the hammer 1 for a vertical displacement in the downward direction.

Attention is directed to the fact that the frame includes elements 1a and 11a, which define mutually aligned channels wherein the hammer 1 and anvil 11 are accommodated in order that these members are capable of performing their respective functions;

Accommodated within a blind bore 1c centrally provided in the hammer 1 is a rodlb, which extends downwardly into the anvil 11 which slidably-and centrally accommodates this rod. Encompassing the rod 1b is a spring 12, which extends into bore 10 and bears on anvil 11. The function of the spring 12 is to urge the hammer 1 into its normal position of rest on completion of each driving operation.

At the top of the hammer 1 are arranged two contacts 4 and 4a, the latter of which is supported directly on the hammer 1 and moves therewith. Contact 4 is fixedly mounted on a cap 4b, which is of insulating material and which is fixedly supported relative to the frame.

The frame defines a chamber C, into which the hammer 1 descends in order to perform its function of striking the anvil 11. Chamber C at its lowermost extremity is delimited by plate element 42, which defines the lowermost position to which the hammer 1 can descend.

In the frame is provided a driving channel 26 which accommodates a dn'ver 26a afiixed to the anvil 11 and moving therewith to eject one of a series of staples S, which are fed towards channel 26 by means provided by any conventional magazine arrangement.

Mounted internally of the anvil 11, which has the general form of a cylinder, are sets of contacts 5a, 5b and 6a, 6b which are capable of assuming positions whereat they are either engaged or disengaged. Contacts 512 and- 6b are mounted on disc 27 which is movable relatively to anvil 11. The relative positions of contacts 5a, 5b and 6a, 6b are controlled through the intermediary of pins 25 and 25a, which are slidably accommodated in the top of the anvil 11 and in a support 15 and which have rigid connection with disc 27 as shown in FIG- URE 2 so that, upon being struck by the hammer 1, pins 25 and 25a cause disc 27 to be lowered, thereby causing spring 1t) to be compressed and the contacts 5b and 6b to be moved apart from contacts 5a and 6a.

. As will be hereinafter explained, it is the function of contacts 5a, 5b and 6a, 6b to couple the coil 2 to a source of electrical power and, inasmuch as the contacts 511 and 6b move with disc 27 and the anvil 11, they are provided respectively with electrical connections to brushes 16, 16a and 17, 17a movable with anvil 11 and which slidably and continuously engage bus bars 18, 18a and 19, 19a fixed to frame F, to which electrical connections can be fixedly made. Accordingly, despite the movement of the disc 27 and the anvil 11, provision is made for the feeding of electrical power to contacts 5b and 6b.

As has been indicated above, the hammer 1,is motivated by electromagnetic forces and, consequently, is of any mechanically strong ferrous material. To provide for a complete magnetic circuit, there is provided, supported on the frame F, a yoke 14 of ferrous material which, with the hammer 1, constitutes a substantially closed magnetic circuit.

in the chamber C, which is defined within the frame as noted above, is provided a piston 21 which is connected to and moves with the hammer 1, so that a movement of the latter causes an expulsion of air from the chamber C. Actually, the hammer 1 contacts the anvil 11 through the intermediary of piston 21, but this has no effect on the desired result, provided that the piston 21 is made of sufficiently rigid material. Chamber C is provided with an exhaust vent, generally indicated at E,'

the flow of air through exhaust vent E serving a purpose which will hereinafter be indicated. The anvil 11 is made of non-magnetizable material in order to prevent the premature ascent of this part.

Completing the structure of the anvil 11 is the internally accommodated spring 10 situated between the disc 27, to maintain contacts 5a, 5b and 6a, 6b normally in engagement, and the driver 26a. Adjacent the anvil 11 is a guide portion 20 of frame element 11a, which serves the purpose of guiding the driver 26a.

It will be moreover noted that the anvil is provided with a lower member 28 which may be made of rubber, capable of descending with the anvil 11 towards a base member 27a afiixed to the frame. Element 28 is, however, engageable by a leaf spring 13 (FIG. 3), the purpose of which is to raise the anvil 11 to its initial position for commencing a new stapling operation after a previous stapling operation has been completed. The spring 13 will raise the anvil only when the device is not against the work due to elements 22 and 24. Thus, spring 13 will not raise the anvil during a given driving operation. The strength of spring 13 exceeds that of the spring 12, so that normally spring 13 is effective to maintain the anvil 11 and driver 26a in a non-stapling position when no stapling operation is to be performed and the work is removed, thus permitting insertion of a new staple, and is effective to return anvil 11 to its upper position after the completion of a stapling operation and de-energization of coil 2 and is necessarily maintained ineffective to control the position of anvil 11 when a stapling operation is being performed. In order to control the position of anvil 11 in this manner, there is pivotally mounted on frame F a lever 24, which is responsive to the positioning of a vertically movable abutment 22 against the body to be stapled, for displacing spring 13 downwardly away from the anvil during a stapling operation. There is also provided on the frame F a second vertically movable abutment 23, which actuates an electrical switch, as will be hereinafter indicated in greater detail. It will be understood that both abutments 22 and 23 are moved into a position which is fiush with the end of the driving channel 26.

Referring again to the electromagnetic switch 3 which has been noted above, it is seen that this switch comprises an electromagnetic coil 3a and a movable armature 3b. In conventional manner, the application of electrical power to coil 3a causes a displacement of the armature 3b. Slidably accommodating the armature 3b to the left of coil 3 is a disc member 33, on which is circularly disposed contact 8. A further disc 30 is rotatably mounted on a shaft 30a, which is fixed in a blind bore provided centrally within armature 3b. Contact 8a is circularly disposed on disc 30 for engagement with contact 8 on disc 33. Disc 30 is positioned by vented spring 30b to ensure electrical connection of the contacts 8 and 8a. Disc 30 is connected to its hub by means of spokes 37a, which are inclined relative to shaft 30a for the purpose which will be explained hereinafter. All of these latter elements are accommodated within a cylindrical element 31 supported in the frame.

Armature 3b is urged normally to the left by a spring 43, which is effective to move disc 30 to the left and, consequently, disengage contact 8 from contact 8a. Spring 43 centrally accommodates a rod 43a, the purpose of which is to cause engagement and disengagement of contacts 7, 7a which are mounted in a space 34 conveniently provided so that the contacts 7, 7a may be closed in response to actuation of the coil 3a.

Coil 3a is accommodated within a magnetizable housing 32 supported in section 38 of frame F, section 38 defining the aforenoted space 34.

The real-most end of the frame F is provided with a perforated cap 36, chamber C discharging via exhaust E and various channels 38b included within the support section 38 into the space 34 and thence through a filter 35 and cap 36 to the ambient atmosphere.

It was previously noted in accordance with this embodiment of the invention that the use thereof is contemplated with a source of direct-current electrical power which may be introduced through electrical lead P into the apparatus by means of a conventional lead-in P1. It will be assumed, for the purpose of the discussion which follows hereinafter, that the electrically operated elements are connected between power source P2 and ground, with the frame F of the stapling device grounded to one terminal of the power source P in conventional manner, and that the magnitude of the potential supplied to power source P is suflicient to effect the functions which are hereinafter ascribed to the various elements.

It is to be noted that the functions which are to be performed are the following: Hammer 1 is to descend on anvil 11 and, having applied its force thereto, the hammer is to be returned to its normal position of rest by spring 12 upon de-energization of coil 2 as mentioned heretofore, wherefrom it again descends on the anvil 11 upon re-energization of coil 2, for the next driving stroke. It is necessary to note that a direct-current source of electrical power is being employed, so that provision need positively be made for enabling the hammer 1 to return to its initial position, and as mentioned heretofore, positive provision is made by means of spring 12.

Reference is next made to FIG. 2, in which the necessary electrical circuitry associated with FIG. 1 is diagrammatically indicated. As indicated in FIG. 2, yoke 14 is connected to the ground of frame F as at 14a. The electrical circuit continues from yoke 14 through element 1a to hammer 1, which makes a sliding electrical contact with element 1a, and through contacts 4 and 4a via line L1 to contact 61: mounted on anvil 11. Because spring 10 urges disc 27 upwardly, contacts 5a, 5b and 6a, 6b are closed. Line L1 is connected to line L2, which is in turn connected via branch line L3 to coil 3a, and thence via branch line L4 to contact 9 directly controllable by abutment 23 and connectable to source of direct-current power P. Abutment 23 engages contact 9 to cause contact 9 to be coupled to power source P for coupling lines L4 and L5 to power source P.

Consequently, if frame F is being urged against a body to be stapled, abutment 23 is moved upwardly into alignment with the base of the frame F having the opening 26 and connects contact 9 to source P, and coil 3a is actuated by means of the circuit described above. With coil 3a actuated, armature 3b is moved in such a manner as to cause contact 8 to bridge contacts 811. Similarly, contact 7 bridges contacts 7a. Electromagnetic relay 3, is therefore, fully actuated.

The bridging of contact 8a causes a continuous circuit to exist between power source P and ground, via contact 9, branch line L5, contacts 8 and 8a, line L6 and coil 2 to ground (undesignated, but shown near top of yoke 14).

Similarly, a circuit exists between source of power P and ground through the intermediary of coil 3a, branch line L3, branch line L7, contacts 7 and 7a, line L8, contacts 5a and 5b, and line L9.

As a result, coil 3a is self-actuating. Therefore, when hammer 1 moves downwardly against anvil 11 in response to the actuation of coil 2, the disengagement of contacts 4 and 4a is of no significance, since this does not interfere with or open the circuit associated with coil 3a, which retains contacts 8 and 8a in engagement and, therefore, retains the coil 2 in active condition. As a result, hammer 1 continues to be driven downwardly by coil 2, despite the disengagement of contacts 4 and 4:: whereby to open the circuit of line L1.

When hammer 1 strikes the anvil 11, it operates through pins 25 and 25a to open contacts 5a, 5b and 6a, 612. At this time, hammer 1 has delivered an impact force to anvil 11 and has effectively performed its function. The opening of contacts 5a and 5b interrupts the only remaining circuit for coil 3a, and electrical power thereto is cut off. As a result, armature 3b is displaced by spring 43, to open contacts 8 and 8a and deactivate coil 2. Hammer 1 is then urged by spring 12 upwardly away from the anvil 11, and contacts 4 and 4a are again engaged.

To permit a cylical operation for the same staple, when the hammer 1 achieves its uppermost position which is its normal position of rest, it re-engages contacts 4 and 4a, thereby again closing a circuit for coil 3:: through line L1 and the associated circuitry, whereupon the operation repeats itself and a periodic and continuous hammering of anvil 11 is provided until the staple is driven and the work removed. At this time the anvil 11 and driver 26a are raised sufiiciently by spring 13 to allow insertion of a new staple into the driving channel 26.

During the movement of hammer 1 towards anvil 11, air is forced from chamber C through exhaust E and against the inclined spokes 37 of disc 30. Spokes 37 are inclined in a well known manner so as to form a blading arrangement of the propeller type. As a result of the flow of air against the inclined spokes 37, disc 30 is slightly rotated, whereupon the relative positions of contacts 8 and 8a are modified. The effect of this provision is that subsequent engagements between these contacts cause wear in different positions, and the increased longevity of the device is therefore assured.

In summary, with respect to the first embodiment of the invention, there has been provided a stapling device in which a hammer is repeatedly applied to an anvil, for purposes of driving a given staple from the associated mechanism. A direct-current source of power is employed, and provision is made for returning the hammer to its initial position of operation, and repeated and cyclical operation of the hammer can be efiected until the staple is driven and the work removed.

A further embodiment of the invention is illustrated in FIG. 3, where corresponding parts are designated by the same reference numerals as in FIGS. 1 and 2 with the addition of a prime superscript, in connection with which is employed an alternating current course of electrical power.

Briefly, this embodiment of the device comprises a hammer 1', operated by an electromagnetic coil 2' housed in element 14', the hammer 1 operating on an anvil 11 which is maintained in operating poosition by a spring 13 controlled by a lever 24', as has been described above. Abutments 22' and 23' are provided for respectively controlling lever 24 and closing an electrical circuit in the same manner as has been previously described. Coil 2' is maintained in position by an armature plate 42'.

Since an alternating current source of power is being employed, the oscillating movement of hammer 1 is assured for both of its directions of movement. Its magnitude of movement is, however, fixed and since there are no switches employed in this embodiment of the invention to terminate the movement of hammer 1', provision is made by the invention for effecting a sequentially increasing displacement of armature 11', as next described. Frame F is provided in two sections 38 and 39'. These sections are pivotally connected by means of pivot 40. Section 38' defines a channel 38" by appropriately supporting coil 2'. Channel 38" guides the movement of hammer 1. On the other hand, section 39' defines a channel 39 which guides the movement of anvil 11'.

Sections 38' and 39 are urged apart by spring 41 appropriately engaged therewith. The moving part of these two sections is positively limited by means of a stop T. The operator of the device controls the relative positioning of sections 38' and 39' by opposing the force of spring 41'. Thus, the closer section 38' is moved towards section 39', the greater striking force with which hammer 1' strikes anvil 11'. This because, at the closest position, the relative magnetic poles of the hammer 1' and the anvil 11 are aligned at the time of driving and the striking force is greatest. Accordingly, provision has been made for successively driving anvil 11' against a staple to be ejected from the stapling device.

It will be generally noted from what has been stated above that the method of the invention consists of cyclically and continuously hammering an anvil and driver against a staple or like device, in such a manner as to drive the same in increments into the body which is to be stapled. This method can be effected by various devices involving the use of either alternating or direct-current sources of electrical power.

The various features and advantages of the invention will now be apparent from what has been stated above. There will now be obvious to those skilled in the art many modifications and variation of the structure set forth. These modifications and variations will not, however, depart from the scope of the invention, as defined in the following claims.

What is claimed is:

1. Apparatus for driving a fastener into a body by means of a pluralityof hammering strokes comprising a frame including means for accommodating the fastener and means for driving the fastener and having a fastener driving channel adjacent thereto for the ejecting of said fastener, an anvil movably supported on said frame adjacent said channel for ejecting the fastener out of said channel, a hammer movable independently of said anvil, and electromagnetic coil encompassing the hammer, said hammer being of ferrous material and being responsive to said coil for making forcible contact with the anvil for ejecting the fastener, a source of electrical power coupled to said coil for activating the same and a switch on the frame responsive to the pressure of the latter against said body for coupling the source to said coil, the hammer having a normal position of rest, and comprising contacts respectively positioned on the hammer and on the frame, said contacts being engaged with the hammer in its normal position, a further set of contacts on the anvil, an electromagnetic relay on the frame, said source being coupled via said relay to said further set and from the latter via the first said contacts to said hammer, the hammer being grounded to complete a first circuit, said coil being con nected to ground and connectible via said relay to said source, the engagement of the first said contacts actuating said relay to couple the coil to said source, the engagement of the hammer and anvil controlling said further set of contacts to disconnect the source and coil.

2. Apparatus for driving a fastener into a body by means of a plurality of hammering strokes comprising a frame including means for accommodating the fastener and means for driving the fastener and having a fastener driving channel adjacent thereto for the ejecting of said fastener, an anvil movably supported on said frame adjacent said channel for ejecting the fastener out of said channel, a hammer movable independently of said anvil, an electromagnetic coil encompassing the hammer, said hammer being of ferrous material and being responsive to said coil for making forcible contact with the anvil for ejecting the fastener, a source of electrical power coupled to said coil for activating the same and a switch on the frame responsive to the pressure of the latter against said body for coupling the source of said coil, said apparatus further comprising a spring intermediate the anvil and hammer for providing a normal spacing therebetween, a further spring engaging the anvil for urging the same away from the driving channel opening and toward the hammer, and means on the frame responsive to the engagement of the frame with said body to deactivate said further spring.

3. Apparatus for driving a fastener into a body by means of a plurality of hammering strokes, comprising a frame including means for accommodating the fastener and means for driving the fastener and having a fastener driving channel opening adjacent thereto for the ejecting of said fastener, an anvil movably supported on said frame adjacent to the fastener driving channel for ejecting the fastener out of said opening, a hammer movable independently of said anvil, an electromagnetic coil encompassing the hammer, said hammer being of ferrous material and being responsive to said coil for making forcible contact with the anvil for ejecting the fastener, a source of electrical power coupled to said coil for activating the same, and a relay having a contact provided in circuit with said electromagnetic coil for placement thereof in circuit with said power source, a return device'coupled to said contact within said anvil for returning said contact to a starting position at the end of a work stroke, means on said frame responsive to the pressure of the latter against said body for coupling said power source to said coil and means associated with said relay within said anvil for opening said relay at the end of said work stroke of said anvil to remove said coil from the circuit of said source deactivating the same to return said hammer to its starting position, said return device actuating said contact to couple said coil in circuit with said scource to reactivate said coil.

4. Apparatus as claimed in claim 3, wherein said return device includes a spring.

5. Apparatus as claimed in claim 3, wherein said relay includes a further electromagnetic coil and set of contacts coupled to said source.

References Cited in the file of this patent UNITED STATES PATENTS 1,604,220 Davis Oct. 26, 1926 1,694,284 Santa Ana Dec. 4, 1928 1,807,170 Peterson May 26, 1931 2,272,533 Svenson Feb. 10, 1942 2,403,947 Oussani July 16, 1946 2,572,012 Curtis Oct. 23, 1951 2,756,426 Campbell July 31, 1956

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US164220 *Jan 21, 1875Jun 8, 1875 Improvement in umbrella-handles
US1694284 *Dec 1, 1927Dec 4, 1928Santa Ana MaxElectric hammer
US1807170 *Oct 28, 1929May 26, 1931Hotchkiss Co E HStapling machine
US2272533 *Dec 17, 1938Feb 10, 1942Carl SvensonActuator
US2403947 *May 19, 1944Jul 16, 1946Oussani James JElectric fastener driving machine
US2572012 *Jan 26, 1949Oct 23, 1951David G RobanskeSemiautomatic electric nailer
US2756426 *Jan 13, 1954Jul 31, 1956Campbell Lee RValve tripping mechanism for air stapling gun
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3172121 *Apr 1, 1963Mar 9, 1965Fastener CorpElectrically operated fastener driving tool
US3394856 *Oct 21, 1965Jul 30, 1968Joseph L. MitchellTag gun and mounting device
US3506178 *Dec 14, 1967Apr 14, 1970Olin MathiesonSpring piston return
US4349143 *May 12, 1980Sep 14, 1982Parker Manufacturing Co.Electric stapler and driver assembly therefor
US4380312 *Jul 17, 1980Apr 19, 1983Minnesota Mining And Manufacturing CompanyStapling tool
EP0130784A2 *Jun 27, 1984Jan 9, 1985Minnesota Mining And Manufacturing CompanyBone stapler
U.S. Classification227/7, 227/134, 227/131
International ClassificationB25C1/00, B25C1/06
Cooperative ClassificationB25C1/06
European ClassificationB25C1/06