US3438405A

US3438405A - Wire stringing machine

Info

Publication number: US3438405A
Authority: US
Inventors: Harvey D Gibson Scheffer
Original assignee: RCA Corp
Current assignee: RCA Corp
Priority date: 1967-06-22
Filing date: 1967-06-22
Publication date: 1969-04-15
Anticipated expiration: 1986-04-15
Also published as: FR1569400A; DE1774456A1; DE1774456C3; NL6808771A; GB1180309A; DE1774456B2; US3438403A; US3448777A

Description

April 15,1969 H. D. G. SCHEFFER WIRE STRINGING MACHINE Sheet of 5 Filed June 22, 1967 INVENTOR Ha 6/550 Jaw-F5? 9% M AYMIIEY Sheet Filed June 22, 1967 INVEUTOR QM, a

H 0. 675:0 50/5014 8) g If If! a a. F 7%4 w f \M N m lfiw QN w v. 1

.4 w ullww April ,1969 H. D. G. SCHEFFER 3,438,405

WIRE STRINGING MACHINE Filed June 22, 1967 Sheet 3 of 5 INVEIITOR hf 0. 673:0 JZWiF/ER April ,1969 H. D. G. SCHEFFER 3,438,405

WIRE STRINGING MACHINE Filed June 22, 1967 Sheet 4 of 5 4 mvnvro fi .0. 6/550 JcWH-T BY W623 April 1969 H. D. G. SCHEFFER 3,438,405

WIRE STRINGING MACHINE Filed June 22, 1967 Sheet 5 of 5 INYENTOR By gbmfi v United States Patent Office 3,438,405 Patented Apr. 15, 1969 3,438,405 WIRE STRINGING MACHINE Harvey D. Gibson Schelfer, Westfield, N.J., assignor to Radio Corporation of America, a corporation of Delaware Filed June 22, 1967, Ser. No. 648,020 Int. Cl. 1321f 45/00 US. Cl. 14093 6 Claims ABSTRACT OF THE DISCLOSURE An apparatus for handling a plurality of flexible wires with a concurrent formation of integral leaders in each of the wires. The apparatus is particularly adapted for the simultaneous manipulation of a large number of fine flexible Wires for stringing a magnetic core memory matrix.

Background of the invention The conventional prior art stringing of magnetic core matrices has been largely a manual operation wherein the insulated wires are individually fed through the cores using needles which, for example, are butt Welded to the wire end to function as wire leaders. Further, in order to produce a core winding threading all the cores by this prior art technique, an insulated wire several feet in length is strung through the cores. Such prior art core stringing techniques are slow, tedious and, of primary importance, subject to errors, e.g., core damage, wire insulation damage and wire insertion mistakes. In practice, the correction of these errors may consume approximately three times as much time as the actual core stringing. Moreover, hand stringing, particularly with fine wires results in varying spacing from wire to wire along a row orcolumn of a matrix. This varying spacing, among other things, results in undesirable operational characteristics of the matrix. In core matrices strung by the present invention, however, the length and spacing of the wires is fixed within close tolerances which results in highly uniform electrical characteristics of the resulting matrix. For example, the inductance of the matrix is uniform as a result of uniform wire spacing, while the core matrix capacitance is reduced to the minimum possible as a result of maximizing the wire spacing. In general, the parameters from plane to plane will be nearly identical and will be effective to enhance the speed capabilities of core memory systems.

Brief summary of the invention The present invention relates to a wire stringing machine. More specifically, the present invention is directed to a wire stringing machine for concurrently handling a plurality of fine wires in a succession of wire stringing levels.

According to the present invention, a wire stringing machine is arranged to individually and concurrently drive a plurality of insulated wires along predetermined respective paths. The wires are withdrawn from individual wire supplies and are directed to wire receiving channels in a core support enclosure having individually supported cores arranged in alignment with these channels. An integral leader forming apparatus is located Within the stringing machine to form integral leaders in the wires before the core stringing operation. After the wires are threaded through the cores and emerge from the enclosure, they are locked in an accurate spatial relationship to provide a means for simultaneously handling groups of the wires. The stringing machine is provided with a turntable for supporting the core enclosure to allow selective access to various sides of the enclosure and cam mechanism for positioning the wires in successive layers through the cores.

Brief description of the drawing A better understanding of the present invention may be had when the following detailed description is read in connection with the accompanying drawings, in which:

FIGURE 1 is a pictorial view of a typical core and the signal wires passing therethrough as found in a prior art core plane;

FIGURE 2 is an enlarged cross-section of a corner of a support plate for supporting cores in the Wire stringing machine of the present invention;

FIGURE 3 is a pictorial side view of a wire stringing machine embodying the present invention;

FIGURE 4 is a view of an enlarged cross-section of a portion of the machine shown in FIGURE 3;

FIGURE 5 is a top view of the apparatus shown in FIGURE 4;

FIGURE 6 is an elongated cross-section of a portion of the apparatus shown in FIGURE 4;

FIGURE 7 is a pictorial illustration of atransfer tray used during the stringing of multiple sets of wires and for handling the completed core plane; and

FIGURE 8 is a pictorial illustration of a jig used to connect the core plane to a printed circuit board.

Detailed description of the invention Referring to FIGURE 1 there is shown a pictorial illustration of a typical prior art core 1 with the signal wires threading the core as found in a core plane having an X wire, a Y Wire, an INHIBIT wire and a SENSE wire. Each core in the plane has all of these wires passing through its center opening. A small core commonly used in current core matrices would have an approximate outer diameter of .030 and an inner diameter of .018. Such a core could be referred to as a 30/18 core. The wires used to string such a core could be a so-called No. 42 wire having a nominal outside diameter of .0030 inch including the insulating layer on the wire. In a core plane having 64 cores on each side, there would be 4096 cores, each with the aforesaid four wires passing therethrough It is to be noted that the method and apparatus of the present invention is suitable for use with smaller cores and thinner Wires without departing from the teachings of the present invention.

FIGURE 2 is an enlarged pictorial illustration of a corner portion of a core support plate 2. The plate 2 is provided with a plurality of recesses 3 which are arranged to hold half of a ferrite core. A typical core 4 is shown in one of the recesses 3. The recesses 3 are arranged to hold the cores 4 in a suitable predetermined configuration, which is well-known in the prior art, to enable the aforesaid wires to be passed through the cores 4 in a straight line from one side of the core matrix to the other. A hole 5 may be provided in the bottom of each recess 3 in order to enable a vacuum loading technique to be used to fill the recesses 3 with the cores 4. Such loading techniques are well-known in the prior art and comprise a means for applying vacuum to the underside of the plate 2 while the cores 4 are brushed or vibrated into the recesses 3. The vacuum which is communicated into each of the recesses 3 by the holes 5 is effective to induce a core 4 to enter the recess 3 and to retain the core 4 while the other cores are being positioned in the other ones of the recesses 3.

A plurality of row wire guide grooves 6 are provided in the surface of the plate 2 with the grooves 6 'being coaxially aligned with the center opening of the cores 4 across the plate 2. Similarly, a plurality of column wire guide grooves 7 are provided in the face of the plate 2. The column grooves 7 are also axially aligned with the cores 4 and are arranged to intersect the row grooves 6 at the center of the recesses 3 to provide separate levels for the wires threading the cores. The width of the row and column grooves 6, 7 is arranged to accommodate respective wires which are to be guided through the cores 4. A cover plate 2a shown in dotted outline, having an internal configuration similar to the support plate 2 is positioned on top of the plate 2 after the plate 2 is filled with the cores 4. The recesses in the cover 2a and the support plate 2 are arranged to mate to form closed boxes holding the cores 4 therein. Also, the row and column grooves in the cover plate are longitudinally aligned with the grooves 6, 7 in the support plate 2. The total height of the mated grooves is arranged to accommodate the number of layers of wires which are to be positioned in each row and column. For example, each of the row grooves 6 would be arranged to hold two layers of wires which would be the Y and INHIBIT wires shown in FIGURE 1. The grooves 6 and 7 may, also, be outwardly tapered at their ends at the outside faces of the plate 2 to facilitate the guiding of a wire into one of the grooves 6, 7.

The complete core assembly comprising the support plate 2, the cover 2a and the cores 4 positioned in their individual recesses are placed in a precisely predetermined position on a wire stringing apparatus shown generally in FIGURE 3 and in more detail in enlarged crosssection in FIGURES 4, and 6.

Referring to FIGURE 3 in more detail, there is shown a pictorial representation of wire stringing apparatus embodying the present invention. A wire storage box 11 is arranged to store a plurality of individual containers of insulated wire 12, e.g., 64, which wires are used in the stringing of a core matrix. The insulated wires 13 are brought out of the box 11 through individual ports 14 which may be fitted with smooth guide bushings 15 to prevent damage to the insulating coating on the wires 13. The wires 13 are, next, directed to a wire stringing apparatus starting with a support plate 16 having guide holes therein corresponding in number to the number of the wires 13. After emerging from the guide plate 16, the wires 13 are arranged in individual grooves in a curved transition plate 17 whereby their individual location is precisely determined. From the curved transition plate 17, the wires 13 enter a wire handling apparatus 18, described fully hereinafter, having individual wire grooves .for supporting the wires 13, drive means operative to move the wires .13 out of the storage box 11, and means for forming integral leaders in each of the wires 13.

A support structure 19, also described hereinafter, is provided at the exit side of the apparatus 18 to support a core matrix support plate 2 having the cores 4 to be strung individually positioned therein to receive the insulated wires 13 as previously discussed. Thus, the wires 13 are extracted from their individual containers 12 within the storage box 11 by the wire drive means within the apparatus 18 and are introduced into the core support assembly supported by the turntable 19. A bench 20 with a shelf 21 is provided to support the wire storage box 11, and the wire guiding assembly in an operative relationship as shown in exemplary form in FIGURE 3. A support arm 22 is attached to the base of the apparatus 18 to rigidly support the guide plate 16.

Referring now to FIGURES 4 and 5, there are shown detailed pictorial representations of the wire handling portion of the present invention. A turntable 30 is provided with a jig surface 31 for precisely locating the core assembly. The turntable 30 is rotatably mounted by means of a center support spindle 32 having a bearing 33 mounted thereon. The bearing means 33 is arranged to space the turntable 30 from a spindle sleeve 34 attached to the base 20. The jig surface 31 is arranged to hold the plate 2 with the cores 4 and the top cover 2a in a predetermined location in the center of the turntable 30. A clamp mechanism may be provided to further retain the plate 2 and cover 2a. In FIGURE 5, there is shown a partial cross-sectional top view of the apparatus shown in FIGURE 4. The jig turntable 30 and jig surface 31 are shaped to form a cross with equal length arms having depressed center areas to form a pair of similar intersecting channels. The intersection of these channels is arranged to hold the plate 2, core 4 and cover 2a in a precise location with respect to the edges of the aforesaid channels.

Adjacent to the jig surface 31 and the turntable 30 is a wire feeding mechanism including a support bracket 35 mounted on the base 20 and a guide channel member 36 mounted on the bracket 35. A wire driving apparatus 37 is positioned in the channel of the guide member 36. This channel is arranged to be the same size as the channels in the jig surface 31 to enable the drive apparatus 37 to slide from the guide membre 36 to the jig surface 31. The alignment of the channels in the jig surface 31 with the channel in the guide member 36 is effected by a springloaded indexing pin 40 which is arranged to cooperate with recesses 41 in the ends of the arms of the turntable 30. The drive apparatus 37 is arranged to have a sliding fit in the aforesaid channel to enable it to be moved from the guide member 36 to a precise location next to the facing side of the

core plates

2, 2a wherein the wires 13 are aligned with the grooves 6, 7. In the latter position, the wires 13 are driven by the drive apparatus 37 through the cores 4 in a manner hereinafter described.

A J-shaped wire locking comb 45 is positioned in the channel of the jig surface 31 adjacent to the side of the

plates

2, 2a opposite to that facing the drive apparatus 37. The spaces between the teeth of comb 45 on the long leg of the I are arranged to form a continuous wire channel with the respective wire slots in the

plaets

2, 2a. Thus, a wire driven by the drive apparatus 37 is ultimately positioned in the teeth of the comb 45 and sufiicient wire is fed to straddle the gap across the J. A wire locking member 45a in the form of a bar fitting between the legs of the comb 45 is inserted into this gap to lock the wires in the comb and to equalize the tension in the individual wires. The comb 45 may be temporarily retained against the

plates

2, 2a by any suitable means which allows free movement of the wires through the comb 45 during the stringing operation.

Referring now to FIGURE 6, an enlarged view of the drive apparatus 37 is shown with a bottom wire guide plate having longitudinal grooves 51 of approximately square cross-section therein to accommodate individual ones of the wires 13. The depth of these grooves 51 is arranged to accommodate the diameter of the wires 13 with cross-cut slots of predetermined locations to allow the drive mechanism of the apparatus 37 to exert a driving force thereon and for other reasons explained full-y hereinafter. The wire drive means is a spring-loaded transverse resilient roller 53 positioned in contact with the wires 13 near the entrance end of the plate 50. The roller 53 is provided with a pair of drive knobs 54 attached to respective ends of an axle 55 supporting the roller 53. The axle 55 is journaled in a cover housing 56 forming an upward extension of the guide plate 50. A cross-cut arcuate slot 57 is provided across the grooves 51 under the roller 53 to expose the wires 13 to the roller 53 with a small portion of the grooves 51 being retained to guide the wires 13.

A transverse clamp block 60 is centrally located in the cover block 56 and spaced from the roller 53. A screw 61 is attached to the top of the block 60 and is threaded into the housing 56. The other end of the screw 61 is attached to a knob 62 positioned above the housing 56. The block 60 has a fiat bottom surface and substantially the same width as the roller 53 to enable all of the wires 13 to be clamped upon the plate 50 by a rotation of the clamp knob 62. A second cross-cut slot 63 is provided under the block 60 to expose the wires 13 to the bottom surface of the block 60. The slot 63 is arranged to expose approximately percent of the diameter of the wires 13 to the block 60.

A transverse knife edge 65 is positioned in a slot 66 in the housing 56 adjacent to the exit side of the guide plate 50 and spaced from the clamp block 60. The knife edge 65 is connected to a spring-biased actuating lever 67 positioned above the housing 56. The slot 66 is continued to the bottom of the grooves 51 to prevent damage to the knife-edge 65. The depth of the cut is controlled by a stop 68 shown in FIGURE 4. The knife edge 65 is arranged to be normally out of contact with the wires !13. A matching cover 69 is provided on the transition guide plate 17 to restrain the wires 13 in the grooves of the plate 7.

Since, as previously discussed, the wires entering a side of the

core plates

2, 2a are on two levels, the bottom surface of the jig surface channels 31 must have a depth which will place the exit side of the wire grooves in the wire drive apparatus 37 in alignment with the spatial position of the desired wire location in the core assembly. In other words, the vertical location of the wires 13 exiting from the drive apparatus 37 with respect to the bottom of the guide plate 50 is fixed by this mechanical dimension. Additionally, the position of the

core plates

2, 2a is fixed on the jig surface 31. Accordingly, the depths of the various channels in the jig surface 31 are effective to vertically locate the wires 13 in the various Wire layers in the slots of the

plates

2, 2a. However, it is desirable to have the bottom face of the operative channel in the jig surface 31 and the guide channel in the support 36 in alignment to facilitate movement of the drive apparatus 37. Thus, for a deeper channel in the jig surface 31, the jig surface 31 must be raised slightly to align the aforesaid channel bottoms. This vertical motion is accommodated in the movement of the shaft 32 in the cylindrical housing 34. The extent of the vertical movement is determined by a camming action between the bottom of the turntable 30 and a fixed cam plate 70 attached to the support 35 under the index pin 40. The cam plate 70 is arranged to contact a bottom edge 71 of the outer periphery of the turntable 30. The thickness of the turntable 30 at this point for each of the four jig guide channels is arranged to provide the necessary positioning action of the jig surface 31.

In operation, the present invention is initially used to prepare the ends of the wires 13 to allow leaderless stringing of the wires through the cores 4. In this operation, the knife edge 65 is used to produce a notch 72 in each of the wires 13 with the stop 68 serving to limit the depth of the notch 72. The clamp block 60, on the other hand, is positioned by the knob 62 on the wires 13 in the cross-cut slot 63 behind the notch produced by the knife edge 65. The block 60 is forced down on the wire 13 until it reaches the top of the slot 63. This squeezing, or flattening of the top and bottom, of the wires 13 is effective to work-harden a substantial length of each insulated wire behind its respective notch.

An exemplary sequence of operations to produce leaderless wires ready for core stringing is now described for an initial state without a preceding core stringing operation. A locking comb similar to comb 45 is positioned and clamped by any suitable means in front of the drive apparatus 37 which would be positioned on the guide support 36. The feed roller 53 is operated to drive the wires 13 into the comb 45. The locking bar 45a is inserted in the comb 45 to lock the wires 13 in place. The wire 13 is then placed in a taut condition by reverse rotation of the feed roller 53. The clamp block 60 is lowered on the wires 13 and is effective to work-harden the wires 13 by a controlled deformation wherein they are taken past their yield point in the taut condition. The knife edge 65 is then used to produce the notches 72 in each of the wires. The drive apparatus 37 is then moved slightly backwards away from the locking comb 45 and the wires 13 are broken at the notches 72. This wire breaking step is effec P tive to form a cone-shaped end on each of the wires since they neck down at the notches 72 just before the actual break takes place. The clamp 60 is released, and the Wires 13 and the points may then be fed back under the clamp block 60 to work-harden the point by repeating the clamping and unclamping operations. The comb 45 and the locking bar 45a are removed and the short pieces of Wire therein are discarded.

The wire feeding apparatus 37 is now slid along the support channel 36 and into the waiting arm of the jig surface 31 until the exit end of the guide plate 50 is adjacent to the pre-positioned face of the

core plates

2, 2a. As previously discussed, the edges of the jig surface 31 are effective to transversely align the wire grooves 51 with the slots in the

core plates

2, 2a, while the cam plate positions the grooves 51 at the proper height. The feed roller 53 is then operated to propel the wires 13' along the grooves 51, through the cores 4 and through the comb 45. A locking bar is inserted in the comb 45 to lock the wires 13. The comb 45 is then repositioned and clamped at the end of its channel in the jig surface 31. The feed apparatus 37 is restored to its original position on the support channel 36 by a reverse rotation of the feed roller 53. A second comb is inserted beneath the wires 13 which are in a taut condition as a result of the reverse movement of the roller 53 while the ends are locked by the comb 45. The second comb is positioned and clamped adjacent to the exit face of the guide '50 with the wires 13 passing through wire slots in the comb. A locking bar is inserted in this comb to lock the wires 13, and the point forming operation described above is repeated.

After the new point is formed, the turntable 30 is rotated to position a second arm of the jig surface 31 in alignment with the guide channel 36. This movement is effective to remove the ends of the wires 13 strung through the cores 4- from the grooves 51. The above-described op eration is now repeated to insert a second set of wires 13 in the cores 4 perpendicular to the first set of wires. These two sets of wires may be designated as the X and Y wires shown in FIGURE 1.The point forming operation is repeated and the turntable 30 is again rotated to position a third arm of the jig 31 facing the wire drive apparatus 37. Since this arm and its counterpart on the other side of jig surface 31 have a set of wires and locking combs from the first threading operation, these parts must be displaced from their present locations on both sides of the jig surface 31 before a second set of wires and locking combs can be introduced on these arms of the jig surface 31.

In FIGURE 7 there is a transfer jig which is used to hold the locking combs and wires of a preceding wire layer in a non-interfering position during multiple wire threading on a single axis and to transfer the wired core matrix to other locations for subsequent operations. In order to position this jig 80 on the jig surface 31, the jig 80 may be provided with two L-shaped clips 81 which are arranged to fit on support pads 82, shown in FIGURE 5, located at the inside corners of the jig surface 31. The jig 80 is arranged as a U-shaped member 83 having a suitable opening to clear the core assembly and to allow the wire feed mechanism 37 to approach the

core plates

2, 2a during the threading of the aforesaid third set of wires. A plurality of comb-carrying arms 84 are mounted on swivel pins on the top of the member 83. Additional comb-holding arms or similar devices may be provided in the arms of the U-shaped member 83 to enable additional locking combs to be carried. A handle 86 is supplied at the closed end of the member 83- to transport the jig 80.

The further stringing of wires in the core 4, thus, is facilitated by the transfer jig 80 which is effective to provide a support for the locking combs and the attached wires of a prior threading operation. The third set of wires can, accordingly, be threaded through the cores 4 after the combs and wires of the first threading operation are supported on the transfer jig 80. Additional sets of wires may be threaded through the cores 4 up to their inner diameter capacity by rotating the turntable 30 and repeating the aforesaid operations while the layers of wires in the cores 4 are positioned in separate layers While the wires in a preceding layer are held in an appropriate position by the jig 80.

After all of the sets of wires have been threaded, the cover 2a is removed from the cores 4. The locking combs are all positioned on the transfer jig '80, and the cores and wires are lifted out of the support plate 2 by the lifting of the transfer jig 80 with the locking combs 45. The wired core plane is now ready to be connected to a printed circuit board or some means for providing terminals for the ends of the wires threading the cores 4. In FIGURE 8, there is shown a jig 90 arranged to hold a printed circuit board 91 in a predetermined precise alignment with respect to a plurality of comb-holding slots 92 and comb clamps 93. The spacing of the clamped combs from the center of the jig 90 is arranged to coincide with the clamped position of the combs 45 on the core threading jig 31. Accordingly, when the combs 45 are clamped in the jig 90 the wires 13 threading the cores 4 are restored to the taut condition of the core threading operation from the slack state imposed during the transfer operation on the transfer jig 80.

The printed circuit board is provided with two sets of wire attaching points on each edge of an inner opening 95 arranged to accommodate the wired core plane. A first set of attaching points comprises four groups of printed rectangular pads 96 adjacent to each edge of the opening 95. The pads 96 are each arranged to underlie the spatial position of two Wires coming from two adjoining columns in the core plane. Further, the pads on opposite sides of the opening 95 are staggered as a group with respect to each other so that the wires connected to a pad on one side of the opening 95 will be positioned for connection to two pads on the other side. Thus, the pads connect the wires in an appropriate layer into a continuous winding as may be required for the sense and inhibit wires. The ends of this winding, i.e., the first and last wires may be connected to individual pads and printed wiring on the board 91, shown in dotted form as printed segments 97, 98.

A second set of attaching points on the board 91 may be four groups of printed wires 99 with each extending from a point behind a respective one of the pads 96 to a spaced location on the adjacent edge of the board 91. The number of printed wires in each of the four groups is equal to the number of wires coming from a corresponding side of the core matrix. The wires to be connected to the pads 96 are first positioned by inserting their combs into the slots 92. In this position of the combs, the wires atached thereto are accurately positioned over the pads 96. These wires are then soldered and the excess wire removed. The respective combs are removed from the slots 92, and the combs for the wires to be connected to the printed wires 99 are inserted therein. These insulated wires pass over the previously soldered pads 96 and are also accurately positioned for soldering to the printed wires 99. If desired, these Wires may be anchored to the board 91 by an adhesive and a dip-soldering process may be used after the excess wires and combs are removed. The core matrix and the board 91 may, subsequently, be attached to individual input connectors or wired into a mass core memory having a plurality of similar core planes interconnected in a stack by any suitable prior art means.

What is claimed is:

1. A wire stringing machine comprising a wire supply means operative to store a quantity of a wire, wire handling means, wire guide means arranged to guide said wire from said supply means to said wire handling means, said handling means including drive means operative to propel said wire along a predetermined path and a leader forming means operative to form an integral leader end 8 in said wire, while said wire is in said handling means, said leader forming means includes a clamp means arranged to work-harden a section of said wire and a knife-edge means arranged to produce a notch in said wire adjacent to said section whereby said wire may be broken by said handling means at said notch.

2. A wire stringing machine for concurrently stringing a plurality of fine wires through respective rows of aligned perforated articles comprising a wire supply means operative to store individual quantities of said fine wires, wire handling means, first Wire guide means arranged to guide each of said Wires in mutually spaced apart paths from said supply means to said Wire handling means, said handling means including a drive means operative to concurrently propel said fine wires, 21 second wire guide means for guiding said wires along said rows of articles between said articles and a leader forming means operative to simultaneously form an individual leader end in each of said wires While said wires are in said handling means, said forming means including a clamp means arranged to concurrently work-harden a section of each of said wires and a knife-edge means arranged to produce a notch in each of said Wires adjacent to said section whereby said wires may be broken at said notch by said handling means.

3. A wire stringing machine as set forth in claim 2, and including a turntable for mounting said rows of articles to allow passage by said wires through said articles from successive sides of said articles, wire locking means arranged to lock said wires after each passage through said articles in a predetermined mutually spaced apart relationship and a turntable elevating means operative to position said turntable at successive levels corresponding to said passage of said Wires through said articles from successive sides of said articles.

4. A core matrix stringing machine for concurrently stringing a plurality of fine wires through respective rows of aligned annular cores comprising a core enclosure means arranged to individually support said cores and having parallel guide slots aligned with the center openings in said cores and extending across said enclosure to provide access to said coresfrom the exterior of said enclosure, means for supporting said core enclosure, a wire supply means operative to store individual quantities of said fine Wires, wire handling means, wire restraining means arranged to position each of said wires in mutually spaced apart paths from said supply means to said wire handling means, said handling means including a drive means operative to concurrently propel said fine wires, 3 wire guide means operative to precisely locate each wire and an integral leader forming means operative to simultaneously form an individual leader end in each of said wires while said wires are in said handling means, and jig means operative to position said handling means adjacent to said enclosure with said wires being aligned with said guide slots.

5. A core matrix stringing machine as set forth in claim 4, wherein said means for supporting said core enclosure is a turntable and said guide slots are arranged in two groups extending across said enclosure to form right angle intersections at said cores, said turntable being operative to allow access to successive sides of said enclosure and Wire locking means arranged to lock said wires after each passage through said enclosure in said slots in a predetermined mutually spaced apart relationship.

6. A core matrix stringing machine as set forth in claim 5, wherein said guide slots each having a width capable of accommodating one of said wires and a depth capable of accommodating more than one of said wires and said turntable includes a turntable elevating means operative to position said turntable at successive levels corresponding to said passage of. said wires through said 9 10 enclosure from successive sides of said enclosure to prO- 3,376,635 4/1968 Moesker 29-413 duce more than one layer of said Wires in said guide slots. 3,381,357 5/ 1968 Billingsley et al. 29-604 References Cited CHARLES W. LANHAM, Primary Examiner.

UNITED STATES PATENTS 5 L. A. LARSON, Assistant Examiner.

3,314,131 4/1967 Judge 29203 US. Cl. X.R.

3,331,126 7/1967 Fielder et a1. 29-203 29203, 413