|Publication number||USRE31183 E|
|Application number||US 06/318,103|
|Publication date||Mar 22, 1983|
|Filing date||Nov 4, 1981|
|Priority date||Nov 3, 1976|
|Publication number||06318103, 318103, US RE31183 E, US RE31183E, US-E-RE31183, USRE31183 E, USRE31183E|
|Inventors||Maurice H. Brown|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (9), Classifications (8), Legal Events (2)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This application is a continuation-in-part of my copending application Ser. No. 844,034 filed Oct. 20, 1977, now abandoned which is a division of my application Ser. No. 738,639, filed Nov. 3, 1976, now U.S. Pat. No. 4,068,367.
The electrical and electronic industries use millions of terminal parts each year. Terminal parts include coil forms, bobbins, terminal strips and like items. These items are usually molded of plastic which may be of either the thermoplastic or the thermosetting types. The terminal parts are manufactured in various sizes, some of which are relatively small. The terminals of the smaller terminal parts are commonly formed of short pieces of wire which may be of circular or noncircular cross sections. The small pieces of wire forming the terminals are usually cut from continuous lengths of wire handled in coils. It is quite often difficult to manually insert the small pieces of wire into the smaller terminal parts.
Many different types of machines have been proposed or constructed for the purpose of inserting wire terminals into the smaller plastic terminal parts. Generally, these machines have been specially built to manufacture a few sizes or types of terminal parts and most of these machines were not readily adjustable or adaptable to manufacture terminal parts of different sizes and shapes. Further, these machines have not been suitable for manufacturing terminal parts in which it was necessary to vary the arrangement or lengths of terminal wires. Since the industry uses a variety of terminal parts, it is advantageous to provide a wire terminal inserting machine that can easily be modified or adjusted to manufacture terminal parts of varying sizes and having varying terminal arrangements.
To meet this need, this invention is concerned with an apparatus for simultaneously forming a number of short pieces of wire or terminals from a number of elongated lengths of wire and inserting the terminals in preformed openings in pieces of plastic to make parts such as coil forms, bobbins, terminal strips, etc. The invention is particularly concerned with such an apparatus in which both the type and number of wire forming tools can easily be changed and in which the sequence of operation of the forming tools can also easily be varied.
An object of this invention is an apparatus of the type described which can easily be adjusted to make plastic terminal parts of different sizes, shapes and having different numbers and locations of terminals.
Another object is a wire forming and applicator apparatus in which the wire terminals can be shaped both before and after insertion in the plastic parts.
Another object is a wire forming and applicator apparatus which can be adjusted to form wire terminals of varying lengths.
Another object is an apparatus which simultaneously forms and inserts wire terminals into a plastic part with the terminals being arranged in more than one plane.
Another object of this invention is a wire moving mechanism which can move more than two wires to a shearing position in a single plane by the use of clamping plates.
Accordingly, another object of this invention is an apparatus for simultaneously forming a plurality of terminals from a plurality of lengths of wire and inserting the terminals simultaneously into openings preformed in plastic parts. The apparatus includes means for simultaneously moving a plurality of lengths of wire which are held in spaced relation to one another to a severing position. Means are provided for simultaneously severing end portions from said lengths of wire to form a plurality of wire terminals. Means are provided for supporting said terminals in spaced relation to one another. Means are provided for supporting a plastic part having openings formed therein for receiving the terminals. Means are provided for moving the plastic part and the terminals into engagement with one another to embed the terminals in the openings in the plastic part. Means are also provided for bending portions of the terminals after the terminals have been embedded in the plastic part.
Other objects may be found in the following specification, claims and drawings.
The invention is illustrated more or less diagrammatically in the following drawings wherein:
FIG. 1 is a perspective view of an apparatus embodying the novel aspects of this invention;
FIG. 2 is a partial top plan view of the apparatus of FIG. 1;
FIG. 3 is an enlarged view taken along line 3--3 of FIG. 2;
FIG. 4 is an enlarged view taken along line 4--4 of FIG. 2;
FIG. 5 is an enlarged view taken along line 5--5 of FIG. 2;
FIG. 6 is a partial enlarged view of the wire clamping and moving elements;
FIG. 7 is a partial front elevational view of a modified form of wire shears and anvil;
FIG. 8 is a cross-sectional view taken along line 8--8 of FIG. 7;
FIG. 9 is a partial enlarged view of modified wire clamping and moving elements;
FIG. 10 is an enlarged view taken along line 10--10 of FIG. 9;
FIG. 11 is an exploded side elevational view of a wire guide element of FIG. 9;
FIG. 12 is an end elevational view of one portion of the wire guide of FIG. 9; and
FIG. 13 is a top plan view of the wire guide portion of FIG. 12.
One form of apparatus made in accordance with the teachings of this invention is shown in perspective in FIG. 1 of the drawings. The apparatus includes a base 11 on which are mounted tools for forming and inserting wire terminals into openings preformed in plastic parts. A bank of solenoid controlled air valves 15 and a programmable sequence and timing signal generator 17 for controlling the operation of the solenoid controlled air valves which are mounted on the base.
The programmable sequence and timing signal generator 17 includes a signal generator which is controlled by a number of individually adjustable printed circuit type timing circuits. The starting and stopping signal of each individual timing circuit is adjusted by separate selector switches actuated by thumb wheels with each timing circuit connected to a solenoid controlled air valve 15. Each timing circuit can be adjusted to vary the starting and terminating times of its signal as a percentage of the total operating cycle of the apparatus. The duration of the cycle can be independently adjusted by a separate control means. A suitable control system was designed and built by Intercontinental Dynamics Corporation of Chicago, Ill. and designated as Model FG212. Another suitable control system is supplied by Electronic Counters and Controls, Inc. of Mundelein, Ill. and designated as Model CE1-12-4. However, it should be understood that these signal generating systems are merely the preferred embodiments and other suitable control mechanisms can be adapted to the apparatus of this invention without departing from the teachings thereof.
The solenoid controlled air valves 15 are preferably four-way, two-position air valves of the spool type but, of course, other types of air valves may be used. The present embodiment of the invention includes a bank of ten solenoid controlled air valves. In any particular application, not all of these air valves may be used. However, in some applications, one air valve 15 may be connected to more than one tool. It can readily be appreciated that the control components of this apparatus provide wide range of flexibility in regard to the number and arrangement of tools controlled by the apparatus.
The exact layout of the tools as well as their number and functions will vary in accordance with the terminal part to be manufactured. It is a feature of this invention that the layout, sequence of operation and type of tooling may easily be changed to produce different types of finished terminals, bobbins, etc. A number of tools are mounted on an elongated rectangular raised framework 21 which extends the length of the base 11. A wire support mechanism 23 is located at the left end of the framework as viewed in FIG. 1. It includes horizontally extending rollers 25 and vertically extending rollers 27. In this embodiment of the invention, both a pair of horizontal and a pair of vertical rollers are provided. However, the number of rollers may be varied in accordance with the number of horizontal and vertical rows of wire to be handled. In this embodiment of the invention, four wires W are arranged in two vertical and two horizontal rows. With other arrangements of wires, the number and arrangement of horizontal and vertical rollers may be varied. Both the horizontal and vertical rollers are mounted on a stand 29 which is attached to the framework 21 at the left hand end thereof. A wire guide 31 is mounted on the framework inwardly of the rollers. The wire guide is formed of a block of material such as plastic and has a plurality of wire receiving holes cut therethrough and forming a grid pattern. The wire receiving passages or holes are formed a predetermined distance apart so that the wires may be passed therethrough for different arrangements of wires in the finished part. The wires are fed to the rollers and wire guide either from spools or from bicycle tire rims, which are not shown.
The mechanism for moving the wires W includes a wire pulling or feeding device 33. This device, shown in detail in FIGS. 4 and 6, consists of a stack of thin, flat, rectangular plates 35 which fit over a pair of spaced upstanding rods 37 (FIG. 4) mounted on a base plate 39. Cap screws 40 threaded into the rods limit upward movement of the plates. The base plate rides on the framework 21 and is connected to the end of a piston rod 41 extending from an air cylinder 42 mounted beneath and supported on the framework 21. An angle 43 connects the base plate and the piston rod. A plate 45 is connected to the base plate 39. The length of the plate 45 may be varied in accordance with the length of terminal wires to be formed. The plate 45 engages a stop 47 on the return stroke of the air cylinder to limit movement of the wire pulling device 33 towards the air cylinder. The stop 47 is attached to the framework 21 by a cross plate 48 and extends through a slot 49 formed in the base plate 39.
An air cylinder 51 is mounted on the top plate 35 of the wire pulling device 33 and has a piston rod 53 which extends through the top plate and engages the upper surface of the plate 35 located below the top plate. When the plates are loosely mounted on the spaced rods 37, wires W can be inserted between the plates and the plates and wires can be moved freely relative to each other. When these plates are clamped together by actuation of the air cylinder 51 and its piston rod 53, the stack of plates 35 and the wires W will move together upon movement of either. Thus, when the stack of plates 35 is clamped together against the wires W and is moved by the action of the piston rod 41, it will pull the wires W to a shearing position, to be described later. Two levels or horizontal rows of wires W are shown extending between the plates 35. This is merely one possible arrangement of wires. For example, wires could be positioned between each set of plates, if desired. Further, the number of plates in the stack may be varied.
The wires W are advanced to the wire shearing mechanism 73 in the following manner:
Solenoid controlled air valve 15 is actuated by the sequence and timing signal generator 17 to energize air cylinder 51 and to de-energize air cylinder 68. When air cylinder 51 is energized, its piston rod 53 extends and pushes against plate 35 located below the fixed top plate of the stack of plates on which the air cylinder is mounted. The plates 35 are forced against one another or against wires W which extend between certain of the plates to thereby clamp the plates and the wires W for movement together. De-energization of air cylinder 68 returns the plates 65 of the wire holding mechanism 63 to their loosely stacked condition which permits the wires W, which extend between certain of the plates 65 to be moved between the plates and through the wire holding mechanism.
Actuation of the air cylinder 42 extends its piston rod 41 and moves the base plate 39 and the wire pulling device 33, which is mounted thereon, toward the wire shearing mechanism 73. Because of the clamping action of the air cylinder 51, the wires W move with the plates 35 of the wire pulling device 33 toward the wire shearing mechanism.
When the wires W are advanced into and through the wire passages 101 of the wire die 97, the piston rod 41 reaches the end of its extension out of the air cylinder 42. At this point, the air cylinder 51 is de-energized and the air cylinder 68 is energized. Energization of the air cylinder 68 clamps the plates 65 of the wire holding mechanism 63 against one another and against the wires W which extend between certain of the plates. The wires W are now held against movement. De-energization of the air cylinder 51 allows the plates 35 of the wire pulling mechanism 33 to return to their loosely stacked condition and permits the wire pulling mechanism 33 to be moved in reverse relative to the wires W which are held by the wire holding mechanism 63. Retraction of the piston rod 41 into its cylinder 42 will return the wire pulling mechanism 33 to its starting position while leaving the wires W extending through the wire passages 101 of the wire die 97. Return movement of the wire pulling mechanism 33 is limited by engagement of the stop member 45 on the base plate 39 with the stop 47. The wire pulling mechanism 33 is now at the end of its cycle.
A wire holding mechanism 63 similar in construction to the wire pulling mechanism 33 includes a stack of plates 65. The wire holding mechanism is mounted on a fixed support 64 positioned on the framework 21 between the wire guide 31 and the wire pulling mechanism 33. The plates are loosely stacked on spaced upstanding rods 66 with the top plate restrained against upward movement by cap screws 67 threaded into the rods 66. An air cylinder 68 is mounted on the top plate of this stack of plates and has a piston rod which engages the upper surface of the plate beneath the top plate to clamp the lower plates of the stack together.
A wire guide 69 is fastened to the base 70 of the wire holding mechanism 63. Two spaced vertical slots 71 (FIG. 2) are formed in the wire guide with the slots extending from the top of the guide and terminating short of the lower edge thereof. Although two slots are shown in this embodiment of the invention, it should be understood that the number of slots may be varied in accordance with the number of vertical rows of wires to be installed in the terminal part to be manufactured. The slots function to maintain vertical alignment of the wires as they move through the wire holding and wire pulling mechanisms.
The air cylinders 51 and 68 of the wire pulling and clamping mechanisms are connected to opposite outlets of an air valve 15 so that when one stack of plates is clamped, the other is unclamped. Thus, the wire holding mechanism 63 will be clamping the wires when the wire pulling mechanism 33 is moving relative to the wires on the return stroke of the piston rod 41. The length of the return stroke is controlled by the length the adjustable plate 45 with the return stroke determining the length of wire fed in each stroke by the wire feeding mechanism 23.
A wire shearing mechanism 73, shown in detail in FIGS. 3 and 4, is mounted on the framework 21 inwardly of the wire feeding mechanism 23. The wire shearing mechanism 73 includes a wire die holder 75 which is supported on and straddles the framework 21. The wire die holder 75 includes integral upstanding portions 77 located on opposite sides of the framework. The wire feeding mechanism 33 is received in a valley 78 located between said upstanding portions 77. Aligned horizontally extending channels 81 are formed in the upstanding portions 77 on the side of the wire die holder 75 opposite to that facing the wire feeding mechanism 23. These channels are of rectangular cross-section and each extends completely across its upstanding portion 77 of the wire die holder 75. An elongated slot 83 is formed in the base of each channel. A slide 85 biased outwardly by a spring 87 is positioned in each slot. The slide carries a circular socket 89. An elongated fixed socket 91 is formed at the inner end of each slot 83.
A wire die 97 seats in the channels 81 in the upstanding portions 77 of the wire die holder 75 and is fastened thereto by threaded fasteners. A horizontally extending channel 99 of rectangular cross-section is formed in the face of the wire die and opens in a direction away from the wire die holder. A suitable number of wire passages 101 are formed in the die and arranged in the same pattern as the wire receiving openings in the plastic part. The wire passages have tapered entrances on the wire feed side of the die. In this example of the invention, four wire passages of rectangular cross-section are arranged in a square pattern. The wire passages could be circular in cross-section and the layout pattern can be varied in accordance with the arrangement of wires in the terminal part.
An anvil 103 is fastened to the wire die and is positioned between the vertical rows of wire passages. A pair of opposite facing shears or blades 107 are slidably mounted in the channels 99 for movement towards and away from the anvil. Wire supporting notches 108 are formed in the blades and align with the wire passages 101. Sleeves 109 extend from the shears 107 through elongated slots 111 formed in the bases of the channels 99. Washers 113 located on the opposite side of the wire die from the shears span the elongated slots. Cap screws 115 threaded into the shears 109 engage the washers and fasten the shears to the wire die 97. The heads of the cap screws 115 are sized to seat in the slots 89 formed in the spring biased slides 85 located in the wire die holder. This arrangement provides a spring return for the shears. In both the cutting and return positions of the shears, the ends of the shears extend outwardly of the ends of the wire die 97. It should be noted that there is sufficient space between the wire passages 101 and the anvil 103 to permit the severed portions of the wires to be moved out of alignment with the wire passages, thus providing a backing surface for the severed pieces of wire or terminals to support the terminals firmly during insertion into the plastic part.
The shears 107 are moved through their cutting strokes into engagement with the anvil 103 upon actuation of a free floating air cylinder 125. The air cylinder has a bumper 127 connected to its piston rod 128 and a yoke 129 connected to the cylinder body. The bumper engages the outer end of one shear 107 while the yoke engages the outer end of the opposite shear 107. Upon actuation of the air cylinder, the shears are moved together in a squeezing action. A spring return (not shown) mounted on the air cylinder retracts the bumper and yoke. As previously mentioned, the shears 107 are retracted after their cutting strokes by action of the spring actuated slides 85 carried by the wire die holder 75. The yoke is mounted on the air cylinder 125 by a bolt and arcuate slot arrangement 131 to permit rotation of the yoke about a horizontal axis through an arc of approximately 60° to provide flexibility in engaging the yoke with the shears.
A part feeding tool 141 is slidably mounted on a base 143 for reciprocal movement towards and away from the wire die anvil 103 (FIGS. 1, 2 and 5). A mounting base 144 which carries base 143 is supported on the framework 21. The tool is reciprocated by means of a rod 145 extending from an air cylinder 147, also mounted on the base 144. The part, in this example, a plastic bobbin 149, is carried on an upwardly opening U-shaped support 151 mounted on the end of the tool 141 facing the wire die anvil 103. The U-shaped support is mounted for limited sliding movement towards and away from the wire die anvil and is biased by a spring (not shown) towards the anvil. The part feeding tool 141 is moved against the wire die holder 75 after the wire terminals have been sheared from the wires W. The wire terminals are held by the shears 107 against the anvil 103 in alignment with preformed openings in the plastic bobbin 149. As the part feeding tool and wire die holder come together, the U-shaped support 151 contacts the anvil 103 and is forced backwards against its spring bias and the wire terminals are forced into the openings in the plastic part. An air hose 153 is connected to an opening 155 in the base of the U-shaped support to permit the introduction of air under pressure to discharge the plastic bobbin from the U-shaped support after the terminal wires have been inserted in the plastic part.
A wire bending mechanism 161 (FIG. 5) is carried on the part feeding tool 141. The wire bending mechanism includes a pair of wire bending blades 163 each of which has a wire engaging hook-like portion 165 at the end thereof adjacent the U-shaped support 151. In this example, each blade includes a pair of projections 166 which fit in recesses in the part 149 to engage the terminals. A generally rectangular shaped opening 167 is formed in the outer end of each blade creating a cam follower surface. A circular cam 169 eccentrically mounted on the end of a shaft 171 is located in each rectangular opening and engages the cam follower surface. The blades are guided for reciprocating movement in a channel 173 formed in a cross piece 175 mounted on the part feeding tool 141. Loops 177 removably fastened to the cross piece 175 hold the wire bending blades in the channels.
The shafts 171 which carry the eccentrically mounted circular cams 169 extend parallel to each other along the sides of the part feeding tool 141. A sprocket gear 181 is mounted on each shaft 171 intermediate its ends with the gear on one shaft aligned with the gear on the other shaft. An air cylinder 183 is mounted on the tool 141 by means of a support member 185. The air cylinder has an elongated geared rack 187 extending at right angles to the shafts 171 with the teeth of the gear rack engaging the teeth of the sprocket gears 181 so that actuation of the air cylinder 183 causes rotation of the sprocket gears 181, rotation of the cams 169 and reciprocal action of the wire bending blades 163. Since the air cylinder 183 is mounted on the tool 141 it moves with the tool.
A modified embodiment of the wire die, anvil and shears is shown in FIGS. 7 and 8 of the drawings. These modified tools are used to form terminals which can be anchored in the openings of a plastic part. The terminals thus formed do not require bending after they have been inserted in the plastic part to firmly hold them in the part.
A modified wire die 191 having two rows of wire passages 193 with three wire passages in each row is shown. In this embodiment, the wire passages are circular in cross-section. The deforming of ends of the terminals permits the anchoring of terminals of circular cross-section in openings of circular cross-section and eliminates the need for wire of non-circular cross-section.
An anvil or terminal stop means 195 is formed integrally with the wire die on the face thereof. The anvil is located between the rows of wire passages 193. A laterally projecting offset or step 197 is formed on each side of the anvil facing a row of wire passages.
A pair of oppositely facing shears or blades 199 are slidably mounted in the channel 99 of the wire die for movement towards and away from the anvil. Wire supporting rectangular notches 201 are formed in the blades and are aligned with the wire passages. The blades are undercut at 203 adjacent the anvil to the depth of the notches and have a height sufficient to compliment the steps or offsets 197 formed on the anvil 195.
When the blades 199 are moved into engagement with the anvil 195, the wires W projecting out of the wire passages 193 are severed, thereby forming terminals which are carried in the notches 201 of the blades to the anvil. As the terminals are moved into contact with the anvil, the ends of the terminals adjacent the wire die 191 engage the steps 197 of the anvil and are deformed out of alignment with the remaining portions of the terminals. The distorted portions of the terminals form what can be called anchors which are firmly seated in openings in the plastic part which is moved into contact with the terminals by the part feeding tool 141.
As part feeding tool 141 and the wire die blades 199 which are supporting the terminals are moved together, the U-shaped support 151 contacts the anvil and is forced backwards against its spring bias. The undistorted portions of the wire terminals are moved into the openings in the plastic part thereby seating the terminals up to the depth of the distorted portions or anchors. The part feeding tool is retracted and then is again moved toward the wire die blades. A pusher plate, which is not shown, is positioned between the wire die blades and the U-shaped support 151. The pusher plate engages and forces the distorted portions of the terminals into the openings in the plastic part thereby anchoring the terminals to the plastic part.
The mechanism for moving the wires can also be modified. One such modification, which is intended to move more than two wires into position in a common plane for shearing and insertion as terminals, is shown in FIGS. 9 to 13 of the drawings. In this embodiment, the wires S are in the form of strips having rectangular cross-sections. It should be understood that the modified apparatus is also adaptable to handling wires of other cross-sections.
The mechanism for moving the wires S includes a wire holding mechanism 301. The wire holding mechanism 301 is mounted on a fixed support 303 positioned on legs 305 on the framework 21 between the wire guide (not shown) and the wire pulling mechanism 307. It includes a stack 308 of thin, flat rectangular plates 309 loosely stacked on a pair of spaced posts (not shown). A socketed top plate 311 rests on the tops of the posts and is held against movement by cap screws (not shown) threaded into the rods.
An air cylinder 313 is mounted on the top plate 311 and has a piston rod (not shown) which engages the upper surface of the plate 309 beneath the top plate to clamp the plates of the stack together. At least one plate 315 of the stack of plates is thinner than the remaining plates 309 so that pairs of wires S can be positioned in closely spaced planes. Shallow notches 317 are formed in one surface of each plate to horizontally align the wires S. The pair of notches 317 in the plate 315 are located between the notches 317 in the lower plate 309 as shown in FIG. 10.
The wire pulling or feeding mechanism 307 includes two side-by-side stacks 321 of thin, flat, rectangular plates 323. The plates of each stack 321 are loosely mounted on pairs of spaced rods (not shown) mounted on a support plate 325. A socketed top plate 327 rests on top of each pair of rods. Cap screws (not shown) are threaded into the tops of the rods to hold the socketed top plates against movement.
The support plate 325 is mounted on a base plate 329 which rides on the framework 21 and is connected to the end of a piston rod 41 extending from an air cylinder 42 mounted beneath and supported on the framework 21. An angle 43 connects the base plate and the piston rod. A stop plate 45 is attached to the base plate. The length of the stop plate 45 may be varied in accordance with the length of the terminal wires to be formed. The stop plate engages a stop 47 on the return stroke of the air cylinder to limit movement of the wire pulling device towards the air cylinder.
An air cylinder 331 is mounted on the top plate 327 of each stack 321 of plates of the wire pulling mechanism 307. Each air cylinder has a piston rod (not shown) which extends through the top plate of its stack and engages the upper surface of the plate 323 located below the top plate. At least one plate 333 of each stack of plates is thinner than the other plates of the stack for the reasons previously mentioned in connection with the description of the wire holding mechanism. Shallow notches (not shown) similar to the notches 317 of the wire holding mechanism 301 are also formed in the plates 323 and 333 in a similar pattern to that previously described.
The wire holding and pulling mechanism of this embodiment functions in the same manner as the corresponding mechanism of FIGS. 1 to 8 whose operation has been previously described. The wires S which are located in two closely spaced, parallel planes, separated by thin plates 315 and 333 of the wire holding and pulling mechanism, are brought together in a common plane at a wire shearing mechanism 335. The wires S are brought together in a common plane by a two piece converging member 337. The converging member shown in detail in FIGS. 11, 12 and 13 includes two grooved die members 339 and 341 mounted on spaced rods (not shown). Each die member includes four grooves 343 with each groove aligned with a groove in the other die member. The grooves are dimensioned so that a pair of aligned grooves in the opposed die members accommodate a wire S. Each pair of aligned grooves includes a horizontal groove and an inclined groove. In the upper die member 339, the inner two grooves are inclined downwardly from the side adjacent the wire moving mechanism 307 to the side adjacent the wire shearing mechanism 335 while the outer two grooves are horizontal having a depth equal to one-half the thickness of the wires S. In the lower die member 341, the outer two grooves are inclined upwardly from the wire moving mechanism to the wire shearing mechanism while the inner two grooves are horizontal having a depth equal to one-half the thickness of the wires S.
The wires S are clamped in pairs between the plates 309 and 315 and brought to planar alignment at the wire shearing mechanism because of the difficulty in clamping more than two wires between a single pair of plates. Irregularities in the thicknesses of the wires S will prevent proper gripping of more than two wires between any pair of flat plates. This problem is overcome by using thin gripping plates and positioning only a pair of wires between adjacent parallel plates with the two pairs of wires being brought to the same plane for shearing after leaving the wire moving mechanism 307.
One of the reasons that the apparatus of this invention can easily be modified to make plastic terminal parts of different sizes, shapes and having different quantities and locations of wire terminals is that the tools such as the wire dies 97 and 191, the anvils 103 and 195, the shears 107 and 199 and the part feed tool 141 are bolted to the apparatus and therefore can easily be changed. This is also the case with the wire bending mechanism 161. The wire bending blades 163 are easily replaceable. Also, the provision of the programmable sequence and timing signal generator 17 with its individually adjustable printed circuit type timing circuits each of which controls a solenoid controlled air valve 15 which can be connected to any tool gives almost unlimited flexibility to the apparatus.
The foregoing description is directed to the parts of the apparatus of this invention whose construction and operation require a detailed description in order that a person skilled in the art will be able to practice the invention. There are other parts shown in the drawings which have not been described, such as the operator's button controlled operating switch for each cycle, the electric control panel with its switches, lights and counters, the electric eye safety control mounted on the control panel, pressure gauges, filters and valves for the air supply and flexible tubing connecting the solenoid controlled air valves 15 with the various air cylinders. This does not mean that these parts are unimportant to this apparatus, but only that they are so well known to those skilled in the art that their construction and function can be understood merely from a showing in the drawings.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US2711818 *||Dec 9, 1953||Jun 28, 1955||Western Electric Co||Apparatus for feeding simultaneously a plurality of wires|
|US2840381 *||Jul 2, 1953||Jun 24, 1958||Ajax Mfg Co||Wire gripping mechanism|
|US3004565 *||Aug 7, 1958||Oct 17, 1961||Western Electric Co||Device for indexing, guiding and severing a plurality of wires|
|US3329327 *||Mar 25, 1966||Jul 4, 1967||Scribner Albert W||Stock advancing device for punch presses and the like|
|US3747186 *||Oct 12, 1971||Jul 24, 1973||Cerzel Tool & Eng Co||Machine for making wire terminals and applying same to a bobbin|
|US3771400 *||Apr 3, 1972||Nov 13, 1973||Schaefer O||Wire measuring and cutting apparatus|
|US4043017 *||Feb 11, 1976||Aug 23, 1977||Amp Incorporated||Apparatus for inserting wires into terminals and for manufacturing electrical harnesses|
|US4060890 *||Jan 4, 1977||Dec 6, 1977||Amp Incorporated||Method of manufacturing an electrical harness|
|US4068367 *||Nov 3, 1976||Jan 17, 1978||Brown Maurice H||Terminal forming and installing apparatus|
|U.S. Classification||226/134, 226/176|
|International Classification||H01F41/10, H01R43/20|
|Cooperative Classification||H01R43/20, H01F41/10|
|European Classification||H01F41/10, H01R43/20|
|Jul 29, 1987||AS||Assignment|
Owner name: BROWN, PETER H., 12209 S. 86TH AVENUE, PALOS PARK,
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:BROWN, MAURICE H.;REEL/FRAME:004766/0637
Effective date: 19870723
|Mar 27, 1989||AS||Assignment|
Owner name: AZONIC PRODUCTS, INC., 11700 SOUTH MAYFIELD, WORTH
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:BROWN, PETER H.;REEL/FRAME:005060/0846
Effective date: 19890307