US2393804A - Wire coiling machine - Google Patents

Wire coiling machine Download PDF

Info

Publication number
US2393804A
US2393804A US539471A US53947144A US2393804A US 2393804 A US2393804 A US 2393804A US 539471 A US539471 A US 539471A US 53947144 A US53947144 A US 53947144A US 2393804 A US2393804 A US 2393804A
Authority
US
United States
Prior art keywords
arbor
coil
wire
tang
coiling
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US539471A
Inventor
Nigro Henry
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
AIRCRAFT SCREW PROD CO
AIRCRAFT SCREW PRODUCTS COMPANY Inc
Original Assignee
AIRCRAFT SCREW PROD CO
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by AIRCRAFT SCREW PROD CO filed Critical AIRCRAFT SCREW PROD CO
Priority to US539471A priority Critical patent/US2393804A/en
Application granted granted Critical
Publication of US2393804A publication Critical patent/US2393804A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21FWORKING OR PROCESSING OF METAL WIRE
    • B21F11/00Cutting wire
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21FWORKING OR PROCESSING OF METAL WIRE
    • B21F23/00Feeding wire in wire-working machines or apparatus
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21FWORKING OR PROCESSING OF METAL WIRE
    • B21F3/00Coiling wire into particular forms
    • B21F3/02Coiling wire into particular forms helically
    • B21F3/06Coiling wire into particular forms helically internally on a hollow form

Definitions

  • the present invention relates to a machine for coiling wire in the shape of springs, and more particularly to a machine of the kind described in U. S. Patent No. 2,119,002 of May 31, 1938.
  • a machine of that type the wire is intermittently fed and passed between astationary arbor and a cooperating tool, which is denoted as the coiling point.
  • the position of the coiling point in relation to th'atpoint where the wire runs tangentiaily on the arbor defines the curve into which the wire is bent, and if the coiling point is stationary a cylindrical coil will be produced whereas by changing the relative position of the coiling point the diameter and hence the shape of th'e coil can also be changed.
  • Another adjustable tool is provided to bend the wire convolution having left the coiling point, out of its plane so as to give the convolutions the desired pitch.
  • feeding is temporarily stopped when the desired length of a coil has been obtained. andra cutting tool moves against a sharp edge of the arbor so as to cut the wire at a distance behind the coiling point. After the cutting tool has returned to its original position, the feeding device is started again, and the subsequent coil will be produced in the manner just described.
  • the invention aims, therefore, to provide means whereby a machine of the mentioned type can be rendered useful to produce tanged coils or springs in a continuous train of automatic oper ations.
  • the stationary arbor cooperates not only with a coiling point to coil the wire but also with a periodically operative tool to form a tang, and that the tang of each coil may be formed before the cutting tool severs the precedingly completed coil from the subsequent one.
  • the invention also consists in a combination of a tang-forming tool with a cutting tool for common movement.
  • the invention furthermore, contemplates to produce a substantially straight tang of a wire portion which was first bent into the shape of a coilconvolution or part of a 'coil convolution, the diameter of such convolution or part convolution being either equal to or different from that of the maior por. tion o.- the coil.'
  • FIG. 4 and 5 are partial cross-sections along lines 4 4 and l-5, respectively, of Fig. 3;
  • Fig. 6 is a diagram illustrating the timing of the movement of several elements of the machine in relation to each other;
  • Fig. 'l is a front view of a tang-provided coil
  • Fig. 8 is a side elevation of two coils as produced by the machine, and placed close to each other
  • Fig. 9 is a front elevation of a modified arbor Il and a pair of freely rotatable rollers i9.
  • rollers are grooved according to the' cross-section of the wire to be coiled as clearly shown at 20 in Figs. 4 and 5, the rollers i8 being omitted in Fig. 4 in order to prevent overcrowding of the drawings.
  • the rollers are grooved for a diamond-shaped wire, but it will be clear that any other wire cross-section mayy be worked if th'e rollers are exchanged for such with corresponding grooves.
  • a wire guide 2i is provided between the rollers and the arbor I4, so that the wire I2 is fed in a tangential direction to the top of the arbor which may be stationarily secured with itsfoot 22 towall i0 by suitable means such as screws 23.
  • One portion 24 of the arbor periphery is an arc which' may be an arc of a circle, cooperating with a surface 25 of the shoe I! which constitutes the coiling point.
  • the surface of the shoe may be curved with a diameter similar to that of the arbor portion 24. If the wireto be coiled is round it is sufllcient if one of the two cooperating members is grooved.
  • both the arbor portion 2l and the shoe face 2l are grooved according to the wire cross-section in order to prevent the wire from turning about its own axis
  • the wire will be continuously subjected to the same bending stress so as to be coiled into a convolution 26.
  • Iii-.he pitch tool I1 projects somewhat forward witl respect to the plane of arbor and coiling shoe, a portion of the convolution just formed will slide on the front face of the pitch tool with the result that the convolution will be bent in a direction at right angles to said plane. Consequently, when the ceiling continues the convolutions will be spaced from each other according to the spacing of the pitch member I1 from the said plane and a cylindrical coil of a predetermined pitch will be produced.
  • the ceiling shoe I5 and the pitch member I1 are adjustable in order to vary Within limits the diameter and pitch of the coil. 'I'he diameter of the coil depends on the spacing of the coiling shoe from the arbor so that the closer the two are positionedin relation to each other the smaller will be the diameter of the coil produced, and the more the 'shoe' is remote from the arbor the larger will be the coil diameter, provided the wire is constantly fed in tangential direction to the same point of the arbor.
  • Carriage 21 can slide in a guide frame 29 and be actuated for to and fro movement by means of a lever 30 engaging a pin 3
  • Fig. 1 fBy shifting the carriage during the feeding to the right hand side in the drawings 1 in a position as shown for instance in Fig. 3, the coil diameter will be Vreduced so as to form a conical coil portion tapering from a larger to a smaller diameter, and by returning the carriage to its abutting position an inverse taper will be formed.
  • the pitch member I1 can be shifted in a direction at right angles to the plane of the wall I0 as clearly shown in Fig. 4. Shifting can be accomplished by means of abell crank lever 34 pivoted at 35 and engaging projections 36 on the shank 31 of the memlber I1.
  • the member I1 .is shown by solid lines in projected position whereas the dotv and dash line contour indicates the member in retracted position.
  • the conventional machine is also provided with a cutter which can be operated when a coil of desired length has been produced.
  • the conventional machine comprising parts as hereinbeforementioned is capable of producing coils of various diameters either in cylindrical or conical form by moving the wire relatively to two substantially stationary members.
  • this principle of operation is not readily applicable to -provide a. so produced coil with a tang.
  • the tang is made, according to the present invention, of a wire portion which previously had been bent into the form of a coil convolution or part of a. coil convolution.
  • a portion of the stock wire which originally was straight as in guide 2l is rst curved to form a portion of a.
  • the present invention is to be applied to a process and machine of the just mentioned kind, it is advisable to accomplish the forming of the tang during such period of rest, and where the operation of a cutter constitutes a part of a cycle, it is another fetaure of the invention that the forming of the tang may be so combined or timed with the cutting that the tang may be completed or almost completed before it is severed from the4 preceding coil or the first part convolution of the subsequent coil.
  • a mechanism for forming a tang according to the invention either constitutes a separate machine, or it may be embodied in a coiling machine, or it may be constructed as an attachment to an existing machine of e. g. the type disclosed in the mentioned Patent No. 2,119,002.
  • the tang-former of the illustrated machine comprises a tool 38 which can be reciprocated about a pivot 39 sol as to cooperate with a substantially straight face 40 of the arbor I4.
  • the tang former 39 maybe combined with a cutter 42 for common movement so that the cutting edge 43 cooperates with an edge 44 of the arbor. Both the tang former and the cutter42 are secured to a lever 45-by means of a plate 46 and screws 41 as clearly shown in Figs. 1 and 4. Lever 45 can be actuated by a lever arm 49 mounted on the pivot axle 39.
  • the tang former operates in the followving manner: i.
  • the coil convolution, or a substantial portion thereof, immediately following the tang be of a smaller diameter than the larger portion of the coil. 'I'he change from smaller to larger diameter should occur gradually so that the tang provided coil end' convolution forms a spiral as shown in Fig. 7 where the spiral form of the first convolution is denoted by l and the larger cylindrical part of the coil with maximum diameter by 38.
  • the other end of the coil, how- 'to indicate that the cross-section of the wire is immaterial as far as the present invention is concerned except for what has 'been stated with g reference to the grooves of arbor and coiling shoe,
  • this difficulty can be overcome by reducing the diameter of a coil portion immediately following the desired length ⁇ of a first coil and selecting the length of the said portion so that it is approximately equal to the length of wire required for forming the tang.
  • the connected coils are severed between the front end of the tang of the second coil and the rear end of the preceding coil, the latter will end with a maximum diameter -whereas the following coil has the desired forward end of a tang and a first convolution with increasing diameter.
  • the first coil is denoted by l1 and the secondcoil by 5B. Both coils are shown connected with each other so that they may be severed from each other at I9. If this is done the portion 60 of the coil I8 forms a tang followed by a convolution 46i of increasing diameter and the rear end 82 of the coil has the same diameter as the preceding convolution. It is to be noted, however, that Fig.
  • FIG. 8 is only illustrative insofar as in practice there need not be two completecoils connected to each other because severing of the coil 51 from the subsequent coil at the point 58 mayoccur at the time when only a small portion of the convolution Il is completed. Furthermore. the coils of Fig. 8 are shown as produced of a round wire in contradistinction to the diamond-'shaped wire I2. 'Ihis is done in order 75 and that practically any desired wire cross-section may be used, provided the cross-section is sch that coiling between arbor and shoe is D96- s e.
  • the forming of coils in the indicated manner requires a special timing of themovements of the various machine elements. This can be accomplished by drives of various well-known and suitable types. However. it is required that a certain relationship between the actuations oi' the different parts is maintained. In the illustrated embodiment a drive has been shown which is useful -to accomplish the .desired results. The particular drive is selected in this example because it illustrates with particular clearness all requirements although it is possible to reduce the num- .ber of parts by using ⁇ some other drive which accomplishes the same functions.
  • the drive shown in Figs. 3, 4 and 5 comprises a motor 62 driving a main shaft 83 with a gear wheel 84 secured thereto by key I 65.
  • Wheel 84 is part of a transmission constituted by gear wheels 35, 3B and 61 driving an intermediate shaft 8B. (Fig. 5).
  • the movable member B9 of a releasable clutch is splined on shaft ⁇ 83 and a spring 10 is so arranged as vto urge member 89 into engagement with the other clutch member 1I which is freely rotatable on the same shaft 83.
  • Clutch membery pet 1l cooperates with the lower portion of thev vcam 11 clutch member. will engage member 1i so that rollersl I3 wilibe drivenffrom shaft I3 through transmission .Il toil, shaft 68, clutch II,
  • gear wheels 12 'and 13 When the tappet 1Q is in engagement wltha higher portion of the cam 11 the clutch il willbe disengagedA so that rollers il will come to a standstill.
  • Motor l2 is also geared to drive three vadditional cam shafts 1I, 19 Vand 30.
  • gear wheel Il is in mesh with wheel 3i (Fig. 3) se- I cured to shaft 13 which ,carries another wheel 32 engaging a wheel s3 on shaft 1l.
  • Wheel 83 drives a wheel Il on an auxiliary shaft 35, and wheel Il meshes with a wheel 3B secured to shaft 30.
  • diameter of wheel 84 is equal to that of wheel Il
  • Cam 81 actuates a tappet 94 provided with a spring 95 and guided by a bracket 86.
  • the tappet engages the bell crank lever 34 of the pitch member I1 so as to retract the latter when the tappet is ,raised by the cam crest 90 and to protract it when the tappet is lowered by the action' of the spring 35.
  • the tang-forming tool lever 45 and the coiling shoe lever 3U are operated by cam 88 and tappet 91 with spring 98 and guide-89, and by lcam lo and tappet
  • the total length of a cycle will be equal to 13.51. A cycle.
  • FIG. 6 line I relates to the operation of the feedthrough the guide 2i andbetweenthe arbor I4 ⁇ ing device I3; line II to the movement -of the coilingshoe I5, line III to that of the pitch member I1, and line IV to the reciprocation of the tang-forming and cutting tool I6.
  • line I relates to the operation of the feedthrough the guide 2i andbetweenthe arbor I4 ⁇ ing device I3; line II to the movement -of the coilingshoe I5, line III to that of the pitch member I1, and line IV to the reciprocation of the tang-forming and cutting tool I6.
  • line II indicates the change of the diameter between the points i 1.01 and 1.5m whereas the increase ofthediameter to its original size occurs ⁇ between the a points 2.5 and 4a-f
  • the pitch tool should be inoperative during the time the wire portion with decreasing diameter is coiled.
  • the wire portion with increasing diameter should be coiled with pitch, but will require some time, after feeding starts at point V2.51r until it reaches. the active face of the pitch member.
  • line III indicates, close to 1.01r," a preferably zero pitch and near 3.01" a reverse change of position which may occur somewhat less rapidly.
  • Line IV indicates the movement of the tangforming and cutting tool between the points 1.5m and 2.51, i. e. during the no feeding period. The motion is more slowly during the working stroke than during the return stroke.
  • the cams l'I, 81, 88 and 89 are shown shaped substantially according to the diagram of Fig. 6.
  • the correlation of points of lines I to IV and of the cams can be easily ascertained if it is considered that the' cycle of 13.51 of Fig. 6 corresponds to the 360 peripheries of the cams, which in the present embodiment .are geared to rotate with the same R, P. M. o
  • the machine operates in the following manner: The free end of a wire I2. taken from a supply is passed between the feeding rollers I8 andA I 9.
  • tappet 94 Shortly after the starting of the feeding device, tappet 94 will be lowered so that the pitch member will be protracted under. the action of spring 95. When all tappets are again in their lowermost positions, convolutions of the desired maximum diameter will be coiled. When the coil has obtained the desired length, operation of the tools will start again in the manner Just described so that the cutting tool will sever a complete coil from the tang of thesubsequent coil.
  • thel arbor portion 24 which cooperates with shoe I5 may be formed according to an arc of a circle.
  • 24 of the arbor II4 is an arc of a spiral increasing its radius from thebend
  • 24 is so shaped that it substantially corresponds to the ⁇ first portion of the convolution 55 in Fig. 7.
  • the machine may, then, be so operated and timed that first a cylindrical coil of desired maximum diameter is produced by cooperation of the arbor II4 and shoe I5 in the described manner. During this step the Wire will contact these two' members each substantially in one point only. In other words there will be a gap between the wire and a portion of the arbor arc I 24.
  • feeding is stopped and lever45 with tang-former 38 and cutter 42 turned about its pivot 39 into the position of Fig. 9.
  • the one portionI of the arbor periphery should be shaped according to a spiral. However, this 'appears to be necessary only if a very high grade of accuracy of the uniformity of increase of the iirst coil convolution is required. Otherwise, the arbor portion here in consideration may be an arc of a circle or any other suitable curve depending on the resiliency of the wire material provided the arbor diameter is by no means larger, preferably appreciably smaller than the smallest diameter Yof the iirst coil convolution.
  • the tang-forming tool starts its operation it will not only straighten the portion of the convolution which it engages, but will also bend the subsequent coil portion towards the arbor thereby decreasing the diameter of that portion.
  • This bending may be assisted by the shoe il,.so timed that it is simultaneously moved towards the atbor. Or the bending by the tang-forming tool may be followed by such movement of the shoef the feeding device isin operation, and preferably while the tang-forming tool is moving. This will permit shortening the time to a minimum during which the feeding device is standing still, or in other words, it will permit raising of the output of the machine to a maximum.
  • each completed coil is severed from the subsequent coil while the latter is in its first stage of produc- I tion. In certain instances, however, it may -be tion of a cutter with the arbor. In that event shape will be turned out by the machine.
  • all the mentioned modifications have in common that the tang is formed of a wire portion which was originally straight, then, coiled into at least s, ,portion of a convolution. and finally straightened out again into the shape of the desired tang, and that the consecutive coils are severed .from each other between the one end of a tang and the adjoining convolution after the shaping of the tang h'as been completed.
  • the combinationl ofa stationary arbor having two working faces of its periphery, the iirst one being curved, the second one adjoining thefirst one and beingsubstantially diametrical with respect thereto, a coiling member in cooperative relation to the first one of said arbor faces, so as to coil a wire passed between said first arborface and said ceiling member, a tool having a face .adapted to cooperate with said second arbor face, means to guide said tool in a path across a wire convolution formed between said arbor and said coiling member, said path havingone component substantially parallel to said second arbor face and another component substantially perpendicular thereto, and means to reciprocate said tool so as to cause said tool to urge a portion of said convolution against said first arbor face owing to said first path component and to press another portion of said convolution in the shape of a tang between said tool face and said second arbor face owing to the other path component.
  • a stationary arbor havingl two working faces of its peripl-iei'y, the 'first one being curved, the second one adjoining the first one and being substantially.diametrical with respect thereto, and having a sharp edge at its end remote from said first face, a coiling member in cooperative relation to said iirst arbor face so as to coil a wire vpassed between said mst arbor face and said coiling member, a tool movable across the path of a coil formed by said arbor and said coiling member, and having aface cooperative with said second arbor' face so as to engage a portion of said coil intermediate its free end and the coiling member, means to reciprocate said tool so as to press said coil portion against said second arbor face and to subcooperation o! said cutter and tang-former with stantially straighten it in the form of ⁇ a tang,
  • vand a cutter adapted to cooperate with 'said arbor edge, to sever the wire between said tang and the preceding coil convolution.
  • the combination ora stationary arbor having two work- -ing faces' o'f its periphery, the irst one being curved, the second one adjoining the first one and being substantially diametrical with respect thereto, and having a sharp edge at its'end remote from said first face, a coiling member in cooperative relation to said rst arbor face so as to coil a wire passed between said rst arbor face and said coiling member, a tool movable across the path of a coil formed by said arbor and said coilingmernber, and having a face cooperative with said second arbor face so as to engage a portion of said coil intermediate its free end and the coiling member, a pivoted means adapted to hold said tool, the pivot of said means being located eccentrically with regardy the arbor center and towards the side remote from said coiling member, and operative means for oscillating said pivoted means about the pivot axis whereby said tool when engaging said coil portion will cause friction tending to pull the wire between the coiling member
  • a machine of the typedescribed including a stationary arbor, a coiling member co operative with said arbor for coiling a wire passed between said arbor and said member, and a retractable and projectable pitch member adapted to bend a formed convolution out of'its original plane, the combination of a tool movable in" relation to said arbor and across the path of a wire said stationary member.
  • the method of forming a wire coil to include adjacent arcuate and rectilinear portions, which consists in so feeding a wire stock against an abutment as to form the Wire stock into arcuate convolutions, periodically straightening portions of the stock by deflection of such portions out of their normal pattern of curvature thence subjecting the deected portions to a straightening pressure, interruptingthe feed of the wire stock while subjecting it to straighten ing pressure, and severing the wire stock to cut away a completed coil unit, while the feed is interrupted and substantially during the straightening period.
  • a machine ofthe type described including a stationary arbor, a coiling member cooperative with said arbor for coiling a wire passed between said member and said arbor, and adjustable as toits spacing from said arbor to change the'diameter of the coilv to be formed, and an intermittently operating feeding device, the combination of a tool movable in relation to said arbor and across the vpath of a Wire convolution coiled between said arbor and said coiling member, said arbor and said tool having cooperating faces to bend a portion of said convolution into the form of a tang, first means operative to start and stop said feeding device, second means operative to reciprocate said coiling member, third means to reciprocate said tool so that said tool face engages said portion of a convolution and presses it against-l said arbor face, and, then releases the tang Athus formed, and a drive for said first, second and third means, said drive comprising timing elements so as to cause one reciprocation of said tool during each period of rest of said feeding device, and to cause a movement of said coiling member
  • timing elements comprise a cam in operative connection with said coiling member, said cam having one slope for shifting said coiling member in the one direction and another slope for shifting it in the other direction, the length and shape of the one slope and the speed of the cam being so selected in relation to the speed of said feeding device that the coiling member will be moved from a first to a second end position during the time a Wire length will be fed according to the length of a desired tapering portion of a coil to be formed, and the length and shape of the other slope being so selected that the coiling member will be moved from said second to said first end position during the time a wire length will be fed substantially according to the length of said tang.
  • a device asvclaimed in claim 14 further comprising a cutter in connection with said tool and. movable simultaneously therewith so as to sever a completed coil from the remainder of the wire in the machine during the ⁇ period of rest of the feeding device.
  • a device as claimed in claim 14 further 4comprising a retractable and projectable pitch member adapted to bend a formed convolution out of its original plane, and a fourth means to reciprocate said pitch member, said drive being adapted to operate said pitch member in -timed relationship to said other means so as to cause projection of said pitch member into operative positionl shortly before saidl coiling member is moved in its one direction, and to cause retraction of said pitch member shortly after said coiliiiig member starts to move in the opposite'direct on.
  • a coiling member cooperative with said arbor for coiling a wire passed between said member'and said arbor, and adjustable as to its spacingfrom' said arbor to change the diameter of the coil to be formed, and an interf ber
  • said arborand-said tool having cooperating v faces to bend a portion of ,said convolution into ithe form of a tang
  • first means operative to start and stop said feeding device
  • second means operative to reciprocate said coiling member
  • said drive comprising timing elements so as to cause one reciprocation of said tool during each period of rest of said feeding device, and to cause a movement of said coiling member in the one direction during said period of rest, and a movement of said coiling member in the opposite direction subsequently to said period of rest.
  • a stationary arbor having two working faces of its periphery, the rst one being curved substantially according vto an arc of a spiral decreasing in diameter towards the second one, said second one adjoining the first one and being substantially diametrical with respect thereto, a coiling member in cooperative relation to the first one of 'said larbor faces, so as to coil a wire passed between said arbor face and said coiling member, a tool having a face adapted to cooperate with said lsecond arbor face and being movablev across the path of a wire convolution formed between said arbor and said coiling member, and means to reciprocate said tool so as to press a portion of said convolution inv the shape of a tang between said tool face and said second arbor face.
  • An attachment for a wire coiling machine of the coiling-point-and-arbor type comprising a tool including a punching face and a cutting edge projecting from said 'face, said edge and said face being adapted for cooperation with a correspondingly shaped edge and face respecattachment is destined, so as to cut' the wire stock and to press a portion of a previously formed coil convolution in a manner to form a tang thereof, and means to operate said tool along a path intersecting the curve line of cer-'- tainofthe coil convolutions,"said cutting edge and said punching face being so arranged in relation to each other and to said path'4 that Vsaid edge is leading said face when the tool. is operated and that completion 'of the cutting slightly precedes the completion of the pressing operation.

Description

Jan. 29, 1946. H N|GR0 WIRE comme MACHINE' Filed June 9. 1944 4 Sheets-Sheet 1 Jan. 29, 1946. H. NIGR WIRE COILING MACHINE Filed June 9, 1944 4 Shsets-Shest 2 @v vv Mm. E
vlllT Jan. 29, 1946. H, Nlco WIRE comme MACHINE 4 She'ets-Sheet v3 Fild vJune 9, 1944 Jan. 29, 1946. H, N|GR0 V WIRE 001mm;A MACHINE Filed June 9, 1944 4 Sheets-Sheet 4 NN E. AN. ,N
B mh Nm.
Patented Jan. 29, 1946 vorifice:
WIRE COILING MACHINE Henry Nigro, Torrington, Conn., assignor to Aircraft Screw Products Company, I'nc., Long Island City, N. Y., a corporation of New York Application June 9, 1944, Serial No.l 539.471
22 Claims.
The present invention relates to a machine for coiling wire in the shape of springs, and more particularly to a machine of the kind described in U. S. Patent No. 2,119,002 of May 31, 1938. In a machine of that type the wire is intermittently fed and passed between astationary arbor and a cooperating tool, which is denoted as the coiling point. The position of the coiling point in relation to th'atpoint where the wire runs tangentiaily on the arbor defines the curve into which the wire is bent, and if the coiling point is stationary a cylindrical coil will be produced whereas by changing the relative position of the coiling point the diameter and hence the shape of th'e coil can also be changed. Another adjustable tool is provided to bend the wire convolution having left the coiling point, out of its plane so as to give the convolutions the desired pitch. In the automatically operating machine feeding is temporarily stopped when the desired length of a coil has been obtained. andra cutting tool moves against a sharp edge of the arbor so as to cut the wire at a distance behind the coiling point. After the cutting tool has returned to its original position, the feeding device is started again, and the subsequent coil will be produced in the manner just described.
Although the machine of the mentioned type is useful for the manufacture of springs of various forms. it is not fitted for the production of springs or coils which have a tang at one of their ends. Such tangs are frequently needed, for instance, where it is required to contract or expand a cylindrical or conical wire coil by torsion. An example of such coil is described in U. S. Patent No. 2,150,876 of March 14,v 1939, as an element of a screw connection between a tapped member and an exteriorly threaded bolt lor stud.
The invention aims, therefore, to provide means whereby a machine of the mentioned type can be rendered useful to produce tanged coils or springs in a continuous train of automatic oper ations.
'Ihe inventionconsists in that the stationary arbor cooperates not only with a coiling point to coil the wire but also with a periodically operative tool to form a tang, and that the tang of each coil may be formed before the cutting tool severs the precedingly completed coil from the subsequent one. The invention also consists in a combination of a tang-forming tool with a cutting tool for common movement. The invention. furthermore, contemplates to produce a substantially straight tang of a wire portion which was first bent into the shape of a coilconvolution or part of a 'coil convolution, the diameter of such convolution or part convolution being either equal to or different from that of the maior por. tion o.- the coil.'
Further objects `and details of the invention will be apparent from the description given here- Figs. 4 and 5 are partial cross-sections along lines 4 4 and l-5, respectively, of Fig. 3;
Fig. 6 is a diagram illustrating the timing of the movement of several elements of the machine in relation to each other;
Fig. 'l is a front view of a tang-provided coil; Fig. 8 is a side elevation of two coils as produced by the machine, and placed close to each other: and Fig. 9 is a front elevation of a modified arbor Il and a pair of freely rotatable rollers i9. The
rollers are grooved according to the' cross-section of the wire to be coiled as clearly shown at 20 in Figs. 4 and 5, the rollers i8 being omitted in Fig. 4 in order to prevent overcrowding of the drawings. In the present example, the rollers are grooved for a diamond-shaped wire, but it will be clear that any other wire cross-section mayy be worked if th'e rollers are exchanged for such with corresponding grooves. A wire guide 2i is provided between the rollers and the arbor I4, so that the wire I2 is fed in a tangential direction to the top of the arbor which may be stationarily secured with itsfoot 22 towall i0 by suitable means such as screws 23. One portion 24 of the arbor periphery is an arc which' may be an arc of a circle, cooperating with a surface 25 of the shoe I! which constitutes the coiling point. The surface of the shoe may be curved with a diameter similar to that of the arbor portion 24. If the wireto be coiled is round it is sufllcient if one of the two cooperating members is grooved. For
other wires, however. preferably both the arbor portion 2l and the shoe face 2l are grooved according to the wire cross-section in order to prevent the wire from turning about its own axis Now it Will be clear that if wire I2 is fed by rollers I8 and I9 through guide 2| and between arbor I4 and coiling shoe I5 in their relative position shown in Fig. 1, the wire will be continuously subjected to the same bending stress so as to be coiled into a convolution 26. Iii-.he pitch tool I1 projects somewhat forward witl respect to the plane of arbor and coiling shoe, a portion of the convolution just formed will slide on the front face of the pitch tool with the result that the convolution will be bent in a direction at right angles to said plane. Consequently, when the ceiling continues the convolutions will be spaced from each other according to the spacing of the pitch member I1 from the said plane and a cylindrical coil of a predetermined pitch will be produced.
In the conventional machine the ceiling shoe I5 and the pitch member I1 are adjustable in order to vary Within limits the diameter and pitch of the coil. 'I'he diameter of the coil depends on the spacing of the coiling shoe from the arbor so that the closer the two are positionedin relation to each other the smaller will be the diameter of the coil produced, and the more the 'shoe' is remote from the arbor the larger will be the coil diameter, provided the wire is constantly fed in tangential direction to the same point of the arbor. In order to adjust the relative position of the coiling shoe I5, it is secured to a carriage 21 by means of a halter 28. Carriage 21 can slide in a guide frame 29 and be actuated for to and fro movement by means of a lever 30 engaging a pin 3| and pivoted at 32. The
' guide frame29 is also provided with a set screw in Fig. 1. fBy shifting the carriage during the feeding to the right hand side in the drawings 1 in a position as shown for instance in Fig. 3, the coil diameter will be Vreduced so as to form a conical coil portion tapering from a larger to a smaller diameter, and by returning the carriage to its abutting position an inverse taper will be formed. In lorder to alter thepitch of the coil the pitch member I1 can be shifted in a direction at right angles to the plane of the wall I0 as clearly shown in Fig. 4. Shifting can be accomplished by means of abell crank lever 34 pivoted at 35 and engaging projections 36 on the shank 31 of the memlber I1. In Fig. 4 the member I1 .is shown by solid lines in projected position whereas the dotv and dash line contour indicates the member in retracted position. The conventional machine is also provided with a cutter which can be operated when a coil of desired length has been produced.
The conventional machine comprising parts as hereinbeforementioned is capable of producing coils of various diameters either in cylindrical or conical form by moving the wire relatively to two substantially stationary members. However, this principle of operation is not readily applicable to -provide a. so produced coil with a tang. Now, in order to maintain, in the production of tang-provided coils, the continuity oi' operation prevailing in the conventional process of making tangless wire coils, the tang is made, according to the present invention, of a wire portion which previously had been bent into the form of a coil convolution or part of a. coil convolution. In other words, a portion of the stock wire which originally was straight as in guide 2l, is rst curved to form a portion of a. coil convolution and, then, bent back intoI the more or less straight form of a tang. This forming of the tang may be accomplished by moving a tool in relation to the stationary arbor and a coil con- `volution which has already been formed by the cooperation of arbor andcoiling shoe. In certain well-known cycles of operation in a process of making wire coils, a period exists in which the feedingis interrupted as, e. g. in the machine of the abovementioned Patent No. 2,119,002, in which a period of rest of the feeder mechanism is provided while the cutter is in operation. Where the present invention is to be applied to a process and machine of the just mentioned kind, it is advisable to accomplish the forming of the tang during such period of rest, and where the operation of a cutter constitutes a part of a cycle, it is another fetaure of the invention that the forming of the tang may be so combined or timed with the cutting that the tang may be completed or almost completed before it is severed from the4 preceding coil or the first part convolution of the subsequent coil.
A mechanism for forming a tang according to the invention either constitutes a separate machine, or it may be embodied in a coiling machine, or it may be constructed as an attachment to an existing machine of e. g. the type disclosed in the mentioned Patent No. 2,119,002. In the illustrated embodiment of the invention, the tangforming parts and their accessories are so designed, that the foregoing statement will be readily understood. The tang-former of the illustrated machine comprises a tool 38 which can be reciprocated about a pivot 39 sol as to cooperate with a substantially straight face 40 of the arbor I4. However, it is preferable to make the cooperating faces 4I of tool 38 and 40 of the arbor I4 very slightly curved for reasons to be explained hereinafter. These faces may also be grooved according tothe Wire cross-section as indicated at 50 and 5I, respectively (Fig.4). The tang former 39 maybe combined with a cutter 42 for common movement so that the cutting edge 43 cooperates with an edge 44 of the arbor. Both the tang former and the cutter42 are secured to a lever 45-by means of a plate 46 and screws 41 as clearly shown in Figs. 1 and 4. Lever 45 can be actuated by a lever arm 49 mounted on the pivot axle 39. The tang former operates in the followving manner: i.
Let it be assumed that the feed rollers I8 and I 9 are at a standstill and the various elements in the position of Fig. 1, the pitch member I1 being retracted. A coil has been formed and projects with convolution 26 forward from the wall I0 with the coil axis substantially at right angles to the Wall. If now, the lever 45 is turned in a clockwise direction l(Fig. i) about the pivot 39, the cutting edge 43 will first contact the convolution 26 and, upon lfurther movement, shift the convolution 29 upward and towards the right hand side so as to bend it about the round corner 52 0f the arbor I4.- This is shown in Fig. 2. When the movement of lever 46 continues the face 4I of tool 38 comes closer to the convolution 26 so as to press vit against the face 40 of the arbor. Thereby, the tang is formed. with a slight upward curve according to the tool faces. Simultaneously the cutting edge 43 cooperates with arbor corner 44 so as to sever the preceding coil from that portion of the convolution 26 which is used to form the tang. The relative positionof the parts is shown in Fig. 3 in which the dash and dot line circle 53 indicates the-position of the preceding coil immediately before it has been cut oif and dropped down. If now. the lever Il is returned to its original position and the pressure inbei'ore. If now, the feeding isstarted again and` the pitch member I1 moved back into its more or less protracted position, s. new coil will be produced the forward end of which is constituted by the tang Just formed.
In many instances, particularly if the coil is to be,r used as an insert for screw connections, it is desirable that the coil convolution, or a substantial portion thereof, immediately following the tang be of a smaller diameter than the larger portion of the coil. 'I'he change from smaller to larger diameter should occur gradually so that the tang provided coil end' convolution forms a spiral as shown in Fig. 7 where the spiral form of the first convolution is denoted by l and the larger cylindrical part of the coil with maximum diameter by 38. The other end of the coil, how- 'to indicate that the cross-section of the wire is immaterial as far as the present invention is concerned except for what has 'been stated with g reference to the grooves of arbor and coiling shoe,
ever, should not differ in diameter from the larger l coil portion. As stated herelnbefore, the change in diameter of the coil can be brought about by varying the spacing of the coil shoe I5 from the arbor Il, but obviously, movement of the shoe in the one direction in order to increase the diameter must be followedv or preceded by a movement in the opposite direction in order to insure continuity of the cycles of operation. Considering on the other hand, the shape 0f two `coils placed close to leach other as shown in Fig. 8 to be produced in two consecutive cycles, there is anincrease of the diameter' between a tang and the maximum diameter of the one adjacent coil 'whereas a convolutionof maximum diameteris directly adjacent to the other tang end. vIn other words, there is no apparent coil length in which a reduction of the diameter takes placein order' to permit the'increase between theftangs and the cylindrical coil portions, as 'it is seemingly' necessary if continuity of operation is desired.
According to the invention, this difficulty can be overcome by reducing the diameter of a coil portion immediately following the desired length` of a first coil and selecting the length of the said portion so that it is approximately equal to the length of wire required for forming the tang. If
this is done, and the connected coils are severed between the front end of the tang of the second coil and the rear end of the preceding coil, the latter will end with a maximum diameter -whereas the following coil has the desired forward end of a tang and a first convolution with increasing diameter. In Fig. 8, the first coil is denoted by l1 and the secondcoil by 5B. Both coils are shown connected with each other so that they may be severed from each other at I9. If this is done the portion 60 of the coil I8 forms a tang followed by a convolution 46i of increasing diameter and the rear end 82 of the coil has the same diameter as the preceding convolution. It is to be noted, however, that Fig. 8 is only illustrative insofar as in practice there need not be two completecoils connected to each other because severing of the coil 51 from the subsequent coil at the point 58 mayoccur at the time when only a small portion of the convolution Il is completed. Furthermore. the coils of Fig. 8 are shown as produced of a round wire in contradistinction to the diamond-'shaped wire I2. 'Ihis is done in order 75 and that practically any desired wire cross-section may be used, provided the cross-section is sch that coiling between arbor and shoe is D96- s e.
The forming of coils in the indicated manner requires a special timing of themovements of the various machine elements. This can be accomplished by drives of various well-known and suitable types. However. it is required that a certain relationship between the actuations oi' the different parts is maintained. In the illustrated embodiment a drive has been shown which is useful -to accomplish the .desired results. The particular drive is selected in this example because it illustrates with particular clearness all requirements although it is possible to reduce the num- .ber of parts by using` some other drive which accomplishes the same functions. The drive shown in Figs. 3, 4 and 5 comprises a motor 62 driving a main shaft 83 with a gear wheel 84 secured thereto by key I 65. Wheel 84 is part of a transmission constituted by gear wheels 35, 3B and 61 driving an intermediate shaft 8B. (Fig. 5). The movable member B9 of a releasable clutch is splined on shaft `83 and a spring 10 is so arranged as vto urge member 89 into engagement with the other clutch member 1I which is freely rotatable on the same shaft 83. Clutch membery pet 1l cooperates with the lower portion of thev vcam 11 clutch member. will engage member 1i so that rollersl I3 wilibe drivenffrom shaft I3 through transmission .Il toil, shaft 68, clutch II,
1| Aand gear wheels 12 'and 13. When the tappet 1Q is in engagement wltha higher portion of the cam 11 the clutch il willbe disengagedA so that rollers il will come to a standstill. Motor l2 is also geared to drive three vadditional cam shafts 1I, 19 Vand 30. For this purpose gear wheel Il is in mesh with wheel 3i (Fig. 3) se- I cured to shaft 13 which ,carries another wheel 32 engaging a wheel s3 on shaft 1l. Wheel 83 drives a wheel Il on an auxiliary shaft 35, and wheel Il meshes with a wheel 3B secured to shaft 30. The
diameter of wheel 84 is equal to that of wheel Il,
and the diameters of the wheels 82, 8 3 and 38 are equal to each other so that-'the shafts 63, 1l, 18 and 30 rotate with the same R. P. M. although in different directions. Cams 81, 88 and 89 are mounted on the shafts 13, 19 and 80, respectively,
and their crests 90, 9| and 92 and the crest. of cam 11 are differently shaped as will be explained hereinafter. Cam 81 actuates a tappet 94 provided with a spring 95 and guided by a bracket 86. The tappet engages the bell crank lever 34 of the pitch member I1 so as to retract the latter when the tappet is ,raised by the cam crest 90 and to protract it when the tappet is lowered by the action' of the spring 35. `In a similarmanner, the tang-forming tool lever 45 and the coiling shoe lever 3U are operated by cam 88 and tappet 91 with spring 98 and guide-89, and by lcam lo and tappet |00 with spring lill and guide |02, respectively.
The correct shape and relative position of the 1 cams can be ascertained by the following conrequires a length of time equal to that in which one-half convolution of the maximum coil diameter can be formed, then, the entire time of a. cycle can be expressed in units of wire length or in units oi arcs of a coil convolution. In the pres- 'ent example an arc of 180"=1|l has been selected as such unit. If it is further assumed that the length of the tang is to be approximately equal to an arc of 90, and the coil portion with increasing diameter equal to an arc of approximately 270o4 of a convolution with maximum diameter, and that the coil shall have five and a half convolutions of maximum diameter, then, the total length of a cycle will be equal to 13.51. A cycle.
of this kind is illustrated in Fig. 6. In this diagram line I relates to the operation of the feedthrough the guide 2i andbetweenthe arbor I4` ing device I3; line II to the movement -of the coilingshoe I5, line III to that of the pitch member I1, and line IV to the reciprocation of the tang-forming and cutting tool I6. As the zero point ofv the diagram that instant of the cycle has been selected where four convolutions of maximum diameter of a coil have been completed. Consequently, feeding continues uniformly for a length of 1.51r to be interrupted for a length of l1r, so as to start again at point 2.51r and tol continue to the end of the cycle. It has been stated hereinbefore, that the tang is to be formed of a portion of a wire convolution with decreasing diameter and that its length shall be equal to an arc of 90=.51r. This decrease must be completed before the tang-former operates during'the nofeeding" period. Hence, line II indicates the change of the diameter between the points i 1.01 and 1.5m whereas the increase ofthediameter to its original size occurs `between the a points 2.5 and 4a-f As it is desired that the'tang is located in a plane at right angles to the coil axis, the pitch tool should be inoperative during the time the wire portion with decreasing diameter is coiled. On the other hand, the wire portion with increasing diameter should be coiled with pitch, but will require some time, after feeding starts at point V2.51r until it reaches. the active face of the pitch member. Thus line III indicates, close to 1.01r," a preferably zero pitch and near 3.01" a reverse change of position which may occur somewhat less rapidly. Line IV, finally, indicates the movement of the tangforming and cutting tool between the points 1.5m and 2.51, i. e. during the no feeding period. The motion is more slowly during the working stroke than during the return stroke.
In Fig. 3, the cams l'I, 81, 88 and 89 are shown shaped substantially according to the diagram of Fig. 6. The correlation of points of lines I to IV and of the cams can be easily ascertained if it is considered that the' cycle of 13.51 of Fig. 6 corresponds to the 360 peripheries of the cams, which in the present embodiment .are geared to rotate with the same R, P. M. o
The machine operates in the following manner: The free end of a wire I2. taken from a supply is passed between the feeding rollers I8 andA I 9.
.and coiling shoe I5. This is best accomplished when ali tappets are in their lowered positions. Then, motor 62 may be started. whereupon the wire will .be automatically fed by the device I8 and cornvolutions will be coiled. The first crest of a cam to reach its tappet is the crest of cam 81 which retracts the pitch member I1 to inoperative position. Immediately thereafter, cam 89 causes shoe I5 to -move towards arbor I4 whereby the coil diameter will be reduced. When the shoe has reached its position close` to the arbor, feeding is interrupted owingto the action of cam 11 Simultaneously cam 88 begins to lift its tappet 91 thereby turning the lever 45 with its tools 88 and 42. This movement causes the forming of a tang and cutting of the preceding convolutions as hereinbefore described. The rst coil, thus cut off, is scrap since it is neither of the desired length nor provided with a tang. the tang just formed belonging to .the subsequent coil. After the tools 38 and 42 have completed their operation, lever 46 returns to its original position. When this is reached or shortly before that time, tappet 18 drops from crest 93 of cam 11 to start the feeding device, and simultaneously tappet |00 begins to slide dofwn the long slope of its cam 89, thereby gradually retractin'gw the shoe I5 toits end position where it abuts against screw 88. Thus the coil diameter increases from its minimum to maximum. Shortly after the starting of the feeding device, tappet 94 will be lowered so that the pitch member will be protracted under. the action of spring 95. When all tappets are again in their lowermost positions, convolutions of the desired maximum diameter will be coiled. When the coil has obtained the desired length, operation of the tools will start again in the manner Just described so that the cutting tool will sever a complete coil from the tang of thesubsequent coil.
In formingI coils with a tang and increasing diameter at I4one end, another mode of operating the machine may be used also with satisfactory result. This requires a slightlymodied arbor form and some change in the above-described timing.- It has been `stated with reference to Fig. 3 that thel arbor portion 24 which cooperates with shoe I5 may be formed according to an arc of a circle. Now,\in the modification shown in Fig. 9, the portion |24 of the arbor II4 is an arc of a spiral increasing its radius from thebend |30 of thetang-formingvface I4ll` to the point where the wire I2 runs on the arbor. The arc |24 is so shaped that it substantially corresponds to the` first portion of the convolution 55 in Fig. 7. .The machine may, then, be so operated and timed that first a cylindrical coil of desired maximum diameter is produced by cooperation of the arbor II4 and shoe I5 in the described manner. During this step the Wire will contact these two' members each substantially in one point only. In other words there will be a gap between the wire and a portion of the arbor arc I 24. When suicient wire has been coiled, feeding is stopped and lever45 with tang-former 38 and cutter 42 turned about its pivot 39 into the position of Fig. 9. In so` doing these tools move in a path having a component substantially parallel to the arbor face |40 and another component substantially perpendicular to the firstv assasos and wu; be accordingly bent inte the shape of the first portion of a convolution -with increasing diameter such as Il in Fig. '7. While this occurs, the shoe IB may be moved towards the arbor into auch a position that it can continue it will be necessary only to remove the cutting tool I! whereupon connected coils of the desired forming the convolution l by returning to its diameter of the coil whereas in the ilrst described Y manner the tang portion was originally a part of a convolution with decreasing diameter. Both methods have in common that the length of the coil portion with increasing diameter can be selected as desired. Ifl this length is very short, i. e. less than approximately 90, the forming may be accomplished on the arbor arc |24 alone without movement of the shoe I5 which may be held stationary according to the maximum diameter of the coil.` The means for timing the various parts of the machhie do not require additional explanation. Their construction and arrangement will be apparent in view of the description given hereinabove.
It has been stated that in the modification Just described with reference to Fig. 9, the one portionI of the arbor periphery should be shaped according to a spiral. However, this 'appears to be necessary only if a very high grade of accuracy of the uniformity of increase of the iirst coil convolution is required. Otherwise, the arbor portion here in consideration may be an arc of a circle or any other suitable curve depending on the resiliency of the wire material provided the arbor diameter is by no means larger, preferably appreciably smaller than the smallest diameter Yof the iirst coil convolution. If, then, the tang-forming tool starts its operation it will not only straighten the portion of the convolution which it engages, but will also bend the subsequent coil portion towards the arbor thereby decreasing the diameter of that portion. This bending may be assisted by the shoe il,.so timed that it is simultaneously moved towards the atbor. Or the bending by the tang-forming tool may be followed by such movement of the shoef the feeding device isin operation, and preferably while the tang-forming tool is moving. This will permit shortening the time to a minimum during which the feeding device is standing still, or in other words, it will permit raising of the output of the machine to a maximum.
In the foregoing, the operation of the machine in forming coils with a tang and increasing diameter has been described. It is, of course, also possible to use the machine for the production of entirely cylindrical coils with tang. In that event it is merely necessary to remove the cam 89. so that the shoe il remains, in an adjusted position, abutting against screw 33. Theoperation of the other tools need not be changed.
Furthermore, in the described machine, each completed coil is severed from the subsequent coil while the latter is in its first stage of produc- I tion. In certain instances, however, it may -be tion of a cutter with the arbor. In that event shape will be turned out by the machine. However, all the mentioned modifications have in common that the tang is formed of a wire portion which was originally straight, then, coiled into at least s, ,portion of a convolution. and finally straightened out again into the shape of the desired tang, and that the consecutive coils are severed .from each other between the one end of a tang and the adjoining convolution after the shaping of the tang h'as been completed.
Although I have described only one embodiment of my invention, it will be apparent to those skilled in the art that many alterations and modifications thereof may be made without departing from the spirit and essence of the invention, which shall be .limited only by the scope of the appended claims.
I claim:
l. In a machine of the type described including a stationary arbor `and a coiling member in cooperative relation to said arbor, for ceiling a wire passed between a curved peripheral face portion oi' said arbor and said member, the combination of a substantially straight peripheral face portion 'of said arbor, said substantially straight face portion being, in the direction of the portion oi'` a convolution whereby to press said portion against said substantially straight arbor face, thereafter releasing the tang thus formed.
2. In a machine of the type described, the combinationl ofa stationary arbor having two working faces of its periphery, the iirst one being curved, the second one adjoining thefirst one and beingsubstantially diametrical with respect thereto, a coiling member in cooperative relation to the first one of said arbor faces, so as to coil a wire passed between said first arborface and said ceiling member, a tool having a face .adapted to cooperate with said second arbor face, means to guide said tool in a path across a wire convolution formed between said arbor and said coiling member, said path havingone component substantially parallel to said second arbor face and another component substantially perpendicular thereto, and means to reciprocate said tool so as to cause said tool to urge a portion of said convolution against said first arbor face owing to said first path component and to press another portion of said convolution in the shape of a tang between said tool face and said second arbor face owing to the other path component. 3. In a machine of the type described, the combination of a stationary arbor havingl two working faces of its peripl-iei'y, the 'first one being curved, the second one adjoining the first one and being substantially.diametrical with respect thereto, and having a sharp edge at its end remote from said first face, a coiling member in cooperative relation to said iirst arbor face so as to coil a wire vpassed between said mst arbor face and said coiling member, a tool movable across the path of a coil formed by said arbor and said coiling member, and having aface cooperative with said second arbor' face so as to engage a portion of said coil intermediate its free end and the coiling member, means to reciprocate said tool so as to press said coil portion against said second arbor face and to subcooperation o! said cutter and tang-former with stantially straighten it in the form of `a tang,
vand a cutter adapted to cooperate with 'said arbor edge, to sever the wire between said tang and the preceding coil convolution.
4. A device as claimed in claim 3 wherein said tool and said cutter are combined and said means is operative to reciprocate said tool and said cutter simultaneously. l
f5. A device as claimed in claim 3 wherein of the coacting faces of the tool and arbor, one such face is slightly concave and the other one slightly convex.
6. In a machine of the type described, the combination ora stationary arbor having two work- -ing faces' o'f its periphery, the irst one being curved, the second one adjoining the first one and being substantially diametrical with respect thereto, and having a sharp edge at its'end remote from said first face, a coiling member in cooperative relation to said rst arbor face so as to coil a wire passed between said rst arbor face and said coiling member, a tool movable across the path of a coil formed by said arbor and said coilingmernber, and having a face cooperative with said second arbor face so as to engage a portion of said coil intermediate its free end and the coiling member, a pivoted means adapted to hold said tool, the pivot of said means being located eccentrically with regardy the arbor center and towards the side remote from said coiling member, and operative means for oscillating said pivoted means about the pivot axis whereby said tool when engaging said coil portion will cause friction tending to pull the wire between the coiling member and arbor inA the direction of the coiling.- 1
7. In a machine of the typedescribed including a stationary arbor, a coiling member co operative with said arbor for coiling a wire passed between said arbor and said member, and a retractable and projectable pitch member adapted to bend a formed convolution out of'its original plane, the combination of a tool movable in" relation to said arbor and across the path of a wire said stationary member.
9. The method of forming a wire coil `with adjacent arcuate and straight portions which ,L
consists in so coiling a wire` stock as to form alternately first and second 4coiled portions ofl desired length and angular extent, periodically dellecting said second portions out of the curve line of said first portions and subjecting the wire of the deflected portions to a straightening pressure.
l 10. The method of forming a coiled wire unit with adjacent arcuate and rectilinear portions, which consists in so feeding a wire 'stock against an abutment as to form an arcuate portion and periodically deflecting parts of the ,arcuate formed stock, in a direction toward the center on which the arc is drawn, and ysubjecting such deflected portions to a pressure tending to straighten the wire of such portions.
11. The method of forming a wire coil to include adjacent arcuate and rectilinear portions, which consists in so feeding a wire stock against an abutment as to form the Wire stock into arcuate convolutions, periodically straightening portions of the stock by deflection of such portions out of their normal pattern of curvature thence subjecting the deected portions to a straightening pressure, interruptingthe feed of the wire stock while subjecting it to straighten ing pressure, and severing the wire stock to cut away a completed coil unit, while the feed is interrupted and substantially during the straightening period.
12. The method of forming in continuous cycles of operation, wire coils, each of which having a tang at one of its ends, which comprises coiling a rst length of wire according to the desired shape of a coil, continuing coiling a second length of Wire according to the desired length of the tang, continuing coiling first-'and second lengths of wire, applying pressure `to eachsecond length of coiled wire so. as-tostraighten the wire while still connected with its precedingand subsequent ilrst lengths of wire.and/ severing the wire atJAoneend of the so formed-tanga before said pressure is relieved;
convolution coiled between said arbor andfsaid coiling member, said arbor and said tool having cooperating faces to bend a portion of said convolution into the form of a tang, first operative means in connection with said tool to reciprocate it so that said tool face engages said portion of a convolution and presses it against said arbor face and,l then, releases the tang thus formed, second means to reciprocate said pitch member, and a drive for said first and lsaid second means, said drive comprising timing elements so as to cause retraction of said pitch member 'prior to a reciprocation ofsaid tool, and projec- A,13. The method of forming, lincontinuous cycles of operation, wire coils each of vwhich having a cylindrical portion, a` tang at one of its ends and a tapering portionl intermediateusaid tang and said cylindrical portion, whichv comprises coiling a first length of ywire while gradually changing the diameter during the coiling to yproducerthe desired taper and then, maintaining the diameter constant to form a desired cylindrical portion of the coil, continuingcoiling a second length of wire substantially equal -to that of the desired tang while changing the diameter so as to produce an opposite taper, continuing coiling in the stated manner alternatingly first and second lengths, .straightening the convolutions formed of said second lengths, and severing the wire at one end of each second length.
14..In a machine ofthe type described including a stationary arbor, a coiling member cooperative with said arbor for coiling a wire passed between said member and said arbor, and adjustable as toits spacing from said arbor to change the'diameter of the coilv to be formed, and an intermittently operating feeding device, the combination of a tool movable in relation to said arbor and across the vpath of a Wire convolution coiled between said arbor and said coiling member, said arbor and said tool having cooperating faces to bend a portion of said convolution into the form of a tang, first means operative to start and stop said feeding device, second means operative to reciprocate said coiling member, third means to reciprocate said tool so that said tool face engages said portion of a convolution and presses it against-l said arbor face, and, then releases the tang Athus formed, and a drive for said first, second and third means, said drive comprising timing elements so as to cause one reciprocation of said tool during each period of rest of said feeding device, and to cause a movement of said coiling member in the one direction immediately preceding said period of rest and a movement of said coiling member in the opposite direction subsequently to said period of rest.
15. A device as claimed in claim 14 wherein said timing elements comprise a cam in operative connection with said coiling member, said cam having one slope for shifting said coiling member in the one direction and another slope for shifting it in the other direction, the length and shape of the one slope and the speed of the cam being so selected in relation to the speed of said feeding device that the coiling member will be moved from a first to a second end position during the time a Wire length will be fed according to the length of a desired tapering portion of a coil to be formed, and the length and shape of the other slope being so selected that the coiling member will be moved from said second to said first end position during the time a wire length will be fed substantially according to the length of said tang.
16. A device asvclaimed in claim 14 further comprising a cutter in connection with said tool and. movable simultaneously therewith so as to sever a completed coil from the remainder of the wire in the machine during the` period of rest of the feeding device.
17. A device as claimed in claim 14 further 4comprising a retractable and projectable pitch member adapted to bend a formed convolution out of its original plane, and a fourth means to reciprocate said pitch member, said drive being adapted to operate said pitch member in -timed relationship to said other means so as to cause projection of said pitch member into operative positionl shortly before saidl coiling member is moved in its one direction, and to cause retraction of said pitch member shortly after said coiliiiig member starts to move in the opposite'direct on.
18. In a machine of the type described includ-' ing a stationary arbor, a coiling member cooperative with said arbor for coiling a wire passed between said member'and said arbor, and adjustable as to its spacingfrom' said arbor to change the diameter of the coil to be formed, and an interf ber, said arborand-said tool having cooperating v faces to bend a portion of ,said convolution into ithe form of a tang, first means operative to start and stop said feeding device, second means operative to reciprocate said coiling member, third means to' reciprocate said tool soV that vsaid toolA ce engages said portion of a convolution and.
presses it against said arbor face, and, then releases the tang thus formed, and a drive for said first, second and third means, said drive comprising timing elements so as to cause one reciprocation of said tool during each period of rest of said feeding device, and to cause a movement of said coiling member in the one direction during said period of rest, and a movement of said coiling member in the opposite direction subsequently to said period of rest.
19. In a machine of the type described, the combination of a stationary arbor having two working faces of its periphery, the rst one being curved substantially according vto an arc of a spiral decreasing in diameter towards the second one, said second one adjoining the first one and being substantially diametrical with respect thereto, a coiling member in cooperative relation to the first one of 'said larbor faces, so as to coil a wire passed between said arbor face and said coiling member, a tool having a face adapted to cooperate with said lsecond arbor face and being movablev across the path of a wire convolution formed between said arbor and said coiling member, and means to reciprocate said tool so as to press a portion of said convolution inv the shape of a tang between said tool face and said second arbor face.
' face when moving in the lone direction of its tively of the arbor ofthe machine `for which the 20. In a machine of the type described, the combination of a stationary arbor having two working faces of' its periphery, the iirst'one being curved, the second one being adjacent and substantially diametrical with respect thereto and constituting a dieface of an extension substantially according to the lengh of a coil portion intended to be subjected toa tang-forming operation, a coiling member in cooperative relation to the first one of said arbor faces so as to coil a wire passed between said first arbor face reciprocation.
21. A device as claimed in claim 20 wherein said second arbor face and said punch face are provided with grooves the cross-sections' of which substantially ycomplement each other to the cross-sectional shape ofthe wire.
22. An attachment for a wire coiling machine of the coiling-point-and-arbor type, comprising a tool including a punching face and a cutting edge projecting from said 'face, said edge and said face being adapted for cooperation with a correspondingly shaped edge and face respecattachment is destined, so as to cut' the wire stock and to press a portion of a previously formed coil convolution in a manner to form a tang thereof, and means to operate said tool along a path intersecting the curve line of cer-'- tainofthe coil convolutions,"said cutting edge and said punching face being so arranged in relation to each other and to said path'4 that Vsaid edge is leading said face when the tool. is operated and that completion 'of the cutting slightly precedes the completion of the pressing operation. Y v
Y HENRY lNIGltO.
US539471A 1944-06-09 1944-06-09 Wire coiling machine Expired - Lifetime US2393804A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US539471A US2393804A (en) 1944-06-09 1944-06-09 Wire coiling machine

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US539471A US2393804A (en) 1944-06-09 1944-06-09 Wire coiling machine

Publications (1)

Publication Number Publication Date
US2393804A true US2393804A (en) 1946-01-29

Family

ID=24151352

Family Applications (1)

Application Number Title Priority Date Filing Date
US539471A Expired - Lifetime US2393804A (en) 1944-06-09 1944-06-09 Wire coiling machine

Country Status (1)

Country Link
US (1) US2393804A (en)

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2820488A (en) * 1953-11-02 1958-01-21 Perkins Machine & Gear Co Spring forming apparatus
US2871910A (en) * 1956-04-24 1959-02-03 Jansen Willem Johan Bernard Machine for winding spiral springs
US2937688A (en) * 1956-09-04 1960-05-24 Leggett & Platt Helical spring winding machine with terminal eye forming means
US3010491A (en) * 1958-06-13 1961-11-28 Heli Coil Corp Wire coiling machine
US3028904A (en) * 1959-07-16 1962-04-10 Sleeper & Hartley Inc Wire coiling machine and looper
US3031004A (en) * 1958-12-03 1962-04-24 Heli Coil Corp Method of producing self locking wire inserts
US3048201A (en) * 1959-12-29 1962-08-07 Westinghouse Electric Corp Article-forming device
DE1137711B (en) * 1958-06-13 1962-10-11 Heli Coil Corp Wire winding machine
US3083751A (en) * 1958-07-01 1963-04-02 Yoder Co Ring coiling and cut-off machine
US3099310A (en) * 1961-09-14 1963-07-30 Heckethorn Mfg & Supply Co Spring forming device
US3145760A (en) * 1959-12-04 1964-08-25 Elek Ska Svetsningsaktiebolage Wire coiling
US3172450A (en) * 1961-09-28 1965-03-09 Gen Motors Corp Stretch bending machine and method
US3320787A (en) * 1962-11-07 1967-05-23 Eckhardt Vilem Apparatus for producing helical seam pipes
US3934445A (en) * 1974-06-24 1976-01-27 Torin Corporation Dual purpose spring coiling machine
US4173135A (en) * 1976-04-12 1979-11-06 Enrico Lamperti Machine for coiling metal wire

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2820488A (en) * 1953-11-02 1958-01-21 Perkins Machine & Gear Co Spring forming apparatus
US2871910A (en) * 1956-04-24 1959-02-03 Jansen Willem Johan Bernard Machine for winding spiral springs
US2937688A (en) * 1956-09-04 1960-05-24 Leggett & Platt Helical spring winding machine with terminal eye forming means
US3010491A (en) * 1958-06-13 1961-11-28 Heli Coil Corp Wire coiling machine
DE1137711B (en) * 1958-06-13 1962-10-11 Heli Coil Corp Wire winding machine
US3083751A (en) * 1958-07-01 1963-04-02 Yoder Co Ring coiling and cut-off machine
US3031004A (en) * 1958-12-03 1962-04-24 Heli Coil Corp Method of producing self locking wire inserts
US3028904A (en) * 1959-07-16 1962-04-10 Sleeper & Hartley Inc Wire coiling machine and looper
US3145760A (en) * 1959-12-04 1964-08-25 Elek Ska Svetsningsaktiebolage Wire coiling
US3048201A (en) * 1959-12-29 1962-08-07 Westinghouse Electric Corp Article-forming device
US3099310A (en) * 1961-09-14 1963-07-30 Heckethorn Mfg & Supply Co Spring forming device
US3172450A (en) * 1961-09-28 1965-03-09 Gen Motors Corp Stretch bending machine and method
US3320787A (en) * 1962-11-07 1967-05-23 Eckhardt Vilem Apparatus for producing helical seam pipes
US3934445A (en) * 1974-06-24 1976-01-27 Torin Corporation Dual purpose spring coiling machine
US4173135A (en) * 1976-04-12 1979-11-06 Enrico Lamperti Machine for coiling metal wire

Similar Documents

Publication Publication Date Title
US2393804A (en) Wire coiling machine
US2441580A (en) Method of forming screw threads
US2337881A (en) Wire drawing machine and method
US2963048A (en) Apparatus for bending wire articles
US3009510A (en) Apparatus and method for corrugating sheet metal strip
US2245407A (en) Apparatus for roll forming strip material
US2686442A (en) Machine for deforming billets
US3023789A (en) Machines for manufacturing sockets for use in cooperation with plug-in members
US1676598A (en) Spring-forming machine
US3010491A (en) Wire coiling machine
US2360047A (en) Means for coiling inserts
US1973667A (en) Coiling of springs
US1869501A (en) Apparatus for and method of manufacturing springs
US1083501A (en) Machine for making coil-springs.
US2116971A (en) Tube forming machine
US1713964A (en) Method of forming eyes in wire
US2689360A (en) Combined wire drawing and forging machine
US2295953A (en) Material handling apparatus
US3025891A (en) Wire forming mechanism with selectively operable forming tools
US2085570A (en) End forming device
US2111574A (en) Ring forming machine and method
US2689596A (en) Process and apparatus for bending tubes to small radii
US3580030A (en) Coil former
US2193661A (en) Washer and method of making
US819543A (en) Machine for making washers.