CN203872012U - Automatic integrated wire clamping and threading device used for motor rotor - Google Patents

Abstract

The utility model discloses an automatic integrated wire clamping and threading device used for a motor rotor. The device comprises a support assembly, a manipulator used to clamp, place, chop, pull, and turn around a formed coil assembly, and driving assemblies used to drive the manipulator to move between a wire clamping station and a threading station. The driving assemblies are disposed on the support assembly. The manipulator is provided with a plurality of clamping jaws arranged uniformly around the periphery and clamping and placing driving assemblies driving the plurality of clamping jaws to operate synchronously to clamp and place the coil assembly. The device is advantaged by high production efficiency, high product consistency, accurate operation, stable and reliable operation, and the device can greatly save manpower resources and production cost.

Description

For the automatic integral clamp threader of rotor

Technical field

The utility model relates to motor manufacturing equipment field, is specifically related to a kind of automatic integral clamp threader for rotor.

Background technology

Rotor threading is one important procedure in electric motor of automobile production process.At present, the domestic mode of production is mainly by the enamelled wire cut-out, the curved U that manually by small mould, one volume are rolled up, splits after a tension-torsion moulding, then inserts in rotor manual the line of moulding one by one.Exist production efficiency low, the consistency of product is bad, and disqualification rate is high, cannot meet the requirement of existing market to auto parts and components quality and production capacity.

The coil groups overall time of splitting a tension-torsion moulding is pressed from both sides out from split a tension-torsion shaped device, and to insert in rotor core groove be a key technology that realizes rotor threading process automation.If the line of moulding is one by one inserted in rotor by workman, efficiency is too low, and the end size of line is wayward, causes withstand voltage defective and occur waste product.Therefore the development of the automatic integral clamp threader of rotor, becomes the emphasis problem that realizes rotor threading process automation, improves motor production efficiency and product quality.

Utility model content

The technical problems to be solved in the utility model is to overcome the deficiency that prior art exists, and the automatic integral clamp threader for rotor that a kind of production efficiency is high, the consistency of product is high, action accurate, working stability is reliable, can greatly save human resources and production cost is provided.

For solving the problems of the technologies described above, the utility model by the following technical solutions:

A kind of automatic integral clamp threader for rotor, comprise bracket component, fold up the manipulator of the coil groups of splitting a tension-torsion moulding and the driven unit for driving described manipulator to move for entirety between clamp station and threading station, described driven unit is installed on described bracket component, and described manipulator is provided with around multiple claws of even circumferential layout and for driving described multiple claw synchronization action to fold up the driven unit that folds up of described coil groups.

As further improvement of the utility model:

The drive end of described driven unit is equiped with cylinder holder, the even interval of described multiple claw is installed on the circumferential side wall of described cylinder holder and can folds up described coil groups along radially wobbling of cylinder holder, the described driven unit that folds up comprises tapered sleeve and telescopic drive part, described tapered sleeve is sheathed on the outside of described cylinder holder, each claw is provided with the first wobble drive portion that is positioned at tapered sleeve one end and the second wobble drive portion that is positioned at the tapered sleeve other end, described telescopic drive part is connected with described tapered sleeve and can drives described tapered sleeve to promote described the first wobble drive portion and the second wobble drive portion claw is swung.

Described claw comprises swing arm and is fixedly connected on the clamp of described swing arm lower end, the circumferential side wall of described cylinder holder is provided with installation location notch, described swing arm is by swingable being installed in described installation location notch of bearing pin, the upper end of described swing arm tilts to extend to form described the first wobble drive portion, and the bottom of described swing arm and clamp form described the second wobble drive portion by the conical surface is set.

The bottom surface of described installation location notch is made up of superposed ramped bottom surface and the vertical bottom surface that is positioned at bottom, described ramped bottom surface tilts to extend to the axis of described cylinder holder from bottom to top, described swing arm is provided with swing installation portion, described swing installation portion is U-shaped, and the recess of described U-shaped swing installation portion is fastened on described bearing pin and by bearing pin and ramped bottom surface and is positioned to install in location notch; One end of described tapered sleeve is provided with first conical surface for promoting the first wobble drive portion, between described tapered sleeve and cylinder holder, be provided with wear ring, described cylinder holder is provided with the installation annular groove of arranging around its circumferential side wall, described bearing pin and wear ring are installed in described installation annular groove, and all bearing pins are positioned the bottom of described installation annular groove by described wear ring clamping.

Described cylinder holder is connected with the drive end of described driven unit by single-revolution governor motion, described revolving and adjusting mechanism comprises cylinder revolving bed, connecting rod and the mount pad affixed with the drive end of described driven unit, described cylinder revolving bed is rotating to be installed on described mount pad, described cylinder holder is connected with described cylinder revolving bed by connecting rod, described cylinder revolving bed is provided with adjusting rod, and the both sides of described adjusting rod are equipped with the adjustment screw that cylinder revolving bed is rotated for promoting adjusting rod.

The telescopic drive end of described telescopic drive part is connected with described tapered sleeve by floating junction and guidance set, described guidance set comprises push pedal, connect cover plate, more than two slide-bar and two are with upper support column, described push pedal is connected with the telescopic drive end of described telescopic drive part by floating junction, on described cylinder revolving bed, corresponding each slide-bar is equipped with linear bearing, described mount pad is equipped with mounting hole in the position of each linear bearing, described slide-bar is arranged in corresponding linear bearing and mounting hole, the upper end of all slide-bars is all connected with described push pedal, the lower end of all slide-bars is all connected with the described cover plate that is connected, described tapered sleeve is connected with the described cover plate that is connected with upper support column by described two.

Described driven unit comprises the lifting driven unit of the driven in translation assembly being installed on described bracket component and the drive end that is installed in described driven in translation assembly; Described driven in translation assembly comprises translating base, the first screw mandrel, the first feed screw nut and the first servomotor, described translating base is slidedly arranged on described bracket component by two group of first guide assembly along continuous straight runs, described the first screw mandrel is installed on described bracket component by clutch shaft bearing assembly, described the first feed screw nut is with the installation of on described the first screw mandrel and with described translating base and is connected, and described the first servomotor is connected with described the first screw mandrel by the first shaft coupling.

Described lifting driven unit comprises elevating bracket, the second screw mandrel, the second feed screw nut and the second servomotor, described elevating bracket is vertically slidedly arranged on described translating base by two group of second guide assembly, described the second screw mandrel is installed on described translating base by the second bearing assembly, described the second feed screw nut is with the installation of on described the second screw mandrel and with described elevating bracket and is connected, and described the second servomotor is connected with described the second screw mandrel by the second shaft coupling.

Described driven in translation assembly is provided with three photoelectric sensors that are respectively used to detect initial point, terminal and excess of stroke position that translating base moves horizontally, and described lifting driven unit is provided with three and is respectively used to detect the vertically photoelectric sensors of mobile initial point, terminal and excess of stroke position of elevating bracket.

Described bracket component comprises supporting plate and two root posts, and the bottom of described column is provided with the base for being connected and fixed with workbench, and on each column, locking is provided with anchor ear, and described supporting plate is installed on the anchor ear of described two columns by securing member.

Compared with prior art, the utility model has the advantage of: the utility model is for the automatic integral clamp threader of rotor, manipulator moves between clamp station and threading station by the driving of driven unit, the coil groups overall time of splitting pulling shaping can be extracted from being in splitting a tension-torsion shaped device of clamp station, coil groups being transported to threading station entirety inserts in the iron core slot of rotor again, realize the automatic integral clamp threading of rotor, its production efficiency improves greatly, nearly 10 times are improved than traditional-handwork threading, change motor threading operation by the manual situation completing of labor-intensive, improve the automated production level of electric manufacturing, a large amount of human resources are saved, there is good Social benefit and economic benefit, simultaneously, manipulator is provided with by folding up driven unit and drives synchronization action to fold up multiple claws of coil groups, and all U lines of corresponding synchronous clamping coil groups one by one, have ensured the reliability clamping, and can there is not slippage and radial deformation in coil groups, the consistency of product is high.

Brief description of the drawings

Fig. 1 is the main TV structure schematic diagram of the utility model for the automatic integral clamp threader of rotor.

Fig. 2 is the fragmentary top TV structure schematic diagram of the utility model for the automatic integral clamp threader of rotor.

Fig. 3 is the mounting structure schematic diagram of the utility model for the automatic integral clamp threader lifting driven unit of rotor.

Fig. 4 is the main TV structure schematic diagram of the utility model for the automatic integral clamp threader claw of rotor.

Fig. 5 broken section structural representation in unwrapping wire state that is the utility model for the automatic integral clamp threader manipulator of rotor.

Fig. 6 broken section structural representation in clamp state that is the utility model for the automatic integral clamp threader manipulator of rotor.

Fig. 7 structural representation in propradation that is the utility model for the automatic integral clamp threader manipulator of rotor.

Fig. 8 structural representation in decline state that is the utility model for the automatic integral clamp threader manipulator of rotor.

Marginal data:

1, bracket component; 11, supporting plate; 12, column; 121, base; 13, anchor ear; 2, driven in translation assembly; 21, translating base; 22, the first screw mandrel; 23, the first feed screw nut; 24, the first servomotor; 25, the first guide assembly; 26, clutch shaft bearing assembly; 27, the first shaft coupling; 3, lifting driven unit; 31, elevating bracket; 32, the second screw mandrel; 33, the second feed screw nut; 34, the second servomotor; 35, the second guide assembly; 36, the second bearing assembly; 37, the second shaft coupling; 4, manipulator; 41, claw; 411, swing arm; 412, clamp; 413, the first wobble drive portion; 414, the second wobble drive portion; 415, swing installation portion; 42, cylinder holder; 421, location notch is installed; 43, tapered sleeve; 44, telescopic drive part; 45, bearing pin; 46, revolving and adjusting mechanism; 461, cylinder revolving bed; 462, connecting rod; 463, mount pad; 464, adjusting rod; 465, adjustment screw; 47, floating junction; 48, guidance set; 481, push pedal; 482, connect cover plate; 483, slide-bar; 484, support column; 49, wear ring; 50, elastic cylindrical pin.

Embodiment

Below in conjunction with the drawings and specific embodiments, the utility model is described in further detail.

As shown in Figure 1, the utility model is for the automatic integral clamp threader of rotor, comprise bracket component 1, the driven unit that folds up the manipulator 4 of the coil groups of splitting a tension-torsion moulding and move between clamp station (splitting the position of a tension-torsion shaped device) and threading station (position of rotor) for driving device hand 4 for entirety, this driven unit comprises the lifting driven unit 3 of the driven in translation assembly 2 being installed on bracket component 1 and the drive end that is installed in driven in translation assembly 2, manipulator 4 is installed in the drive end of lifting driven unit 3, lifting driven unit 3 can be driven and be done translational motion by driven in translation assembly 2, lifting driven unit 3 can move up and down by driving device hand 4, and then can make manipulator 4 reciprocating motion between clamp station and threading station.Manipulator 4 is provided with 29 claws 41 and folds up driven unit, and 29 claws 41 are arranged around even circumferential, fold up driven unit and can drive all claw 41 synchronization actions to fold up coil groups, and then will fold up coil groups overall clamping or the relieving of splitting a tension-torsion moulding.Claw 41 quantity of manipulator 4 are determined according to the quantity of rotor actual needs threading, consistent and corresponding one by one with the quantity of U line in coil groups.The utility model is for the automatic integral clamp threader of rotor, by driven in translation assembly 2, the cooperation of lifting driven unit 3 and manipulator 4, the coil groups overall time of splitting pulling shaping (for example can be split to a tension-torsion shaped device from what be in clamp station, publication No. is the patent application document of CN103545999A disclosed " a kind of rotor U line entirety doubling split a tension-torsion shaped device ") in extract, coil groups being transported to threading station entirety inserts in the iron core slot of rotor again, realize the self-threading of rotor, its production efficiency improves greatly, nearly 10 times are improved than traditional-handwork threading, change motor threading operation by the manual situation completing of labor-intensive, improve the automated production level of electric manufacturing, a large amount of human resources are saved, there is good Social benefit and economic benefit, simultaneously, manipulator 4 is provided with by folding up driven unit and drives synchronization action to fold up multiple claws 41 of coil groups, and all U lines of corresponding synchronous clamping coil groups one by one, have ensured the reliability clamping, and can there is not slippage and radial deformation in coil groups, the consistency of product is high.Especially be applied in auto parts and components manufacture field, this automatic integral clamp threader can improve the manufacturing automated production level of car electrics, and the effectively development of driving automobile electrical component industry, promotes the progress of industry technology, and its development potentiality is huge.

In the present embodiment, as depicted in figs. 1 and 2, bracket component 1 comprises supporting plate 11 and two root posts 12, supporting plate 11 is the platy structure of a rectangle, column 12 is the revolving body of a hollow, on each column 12, anchor ear 13 is all installed, the agent structure of anchor ear 13 is a cuboid, it is sheathed on column 12 and by screw lock structure and is locked on column 12, each anchor ear 13 is equipped with a step surface, supporting plate 11 is fixed on the step surface of two anchor ears 13 by securing member (screw), the setting height(from bottom) of anchor ear 13 on column 12 can be adjusted, and then the setting height(from bottom) of adjusting pole plate 11.The bottom of each column 12 is provided with base 121, is convenient to adopt the just whole bracket component 1 of screw to install and is fixed on workbench.

In the present embodiment, as shown in Figure 1 to Figure 3, driven in translation assembly 2 comprises translating base 21, the first screw mandrel 22, the first feed screw nut 23 and the first servomotor 24, translating base 21 is slidedly arranged on bracket component 1 by two group of first guide assembly 25, two group of first slide block that guide assembly 25 includes linear slide rail and is slidably matched with linear slide rail, wherein the linear slide rail of one group of first guide assembly 25 is arranged on the front side lower part of supporting plate 11 by screw along continuous straight runs, another linear slide rail of organizing the first guide assembly 25 is arranged on supporting plate 11 tops by screw along continuous straight runs, translating base 21 is L-type, a limit of L-type translating base 21 is connected with the slide block of the linear slide rail of supporting plate 11 front side portions, another limit of L-type translating base 21 is connected with the slide block of the linear slide rail at supporting plate 11 tops, form a reliable and stable slide construction, make the translating base 21 can be steady, horizontal slip accurately.The first screw mandrel 22 is installed in the rear sides of supporting plate 11 by clutch shaft bearing assembly 26, wherein, the first screw mandrel 22 is ball screw, the left end of ball screw is arranged on by deep groove ball bearing and back-up ring in the axis hole of left socle, this left socle is fixed by screws on supporting plate 11, the right-hand member of ball screw passes through lining, oil seal without framework, deep groove ball bearing, bearing (ball) cover and screw are arranged in the axis hole of bearing pedestal, this bearing pedestal is fixed by screws on supporting plate 11, the axis hole center line of left socle and the axis hole center line of bearing pedestal are located along the same line, and maintenance sustained height.The first feed screw nut 23 is with the installation of and on the first screw mandrel 22, forms a ball wire bar pair, the first feed screw nut 23 is installed on a screw rodb base, slide block that this screw rodb base is connected with translating base 21 is connected, and the output shaft of the first servomotor 24 is connected by the first shaft coupling 27 and the first screw mandrel 22.Simultaneously, be equiped with three photoelectric sensors along the linear slide rail at supporting plate 11 front tops, three photoelectric sensors are for coordinating initial point, terminal and the excess of stroke position controlling respectively translating base 21 and move horizontally with PLC, change initial point, terminal and excess of stroke position that the installation site of three photoelectric sensors can corresponding adjustment translating base 21 moves horizontally, to ensure that manipulator 4 accurately moves to the position of splitting a tension-torsion shaped device and rotor.The first servomotor 24 drives the first screw mandrel 22 to rotate, and can make the first feed screw nut 23 and translating base 21 move left and right along the linear slide rail of the first guide assembly 25.

In the present embodiment, as shown in figures 1 and 3, lifting driven unit 3 comprises elevating bracket 31, the second screw mandrel 32, the second feed screw nut 33 and the second servomotor 34, elevating bracket 31 is slidedly arranged on translating base 21 by two group of second guide assembly 35, two group of second slide block that guide assembly 35 includes linear slide rail and is slidably matched with linear slide rail, wherein the linear slide rail of one group of second guide assembly 35 is vertically arranged on the left side of translating base 21 front side portions by screw, another linear slide rail of organizing the second guide assembly 35 is vertically arranged on the right side of translating base 21 front side portions by screw, elevating bracket 31 is connected with the slide block on two linear slide rails.The second screw mandrel 32 is installed in the front side portion of translating base 21 by the second bearing assembly 36, and the second screw mandrel 32 is between two group of second guide assembly 35, wherein, the second screw mandrel 32 is ball screw, the lower end of ball screw is arranged on by deep groove ball bearing and back-up ring in the axis hole of lower carriage, this lower carriage is fixed by screws on translating base 21, lining is passed through in the upper end of ball screw, oil seal without framework, deep groove ball bearing, bearing (ball) cover and screw are arranged in the axis hole of bearing pedestal, this bearing pedestal is fixed by screws on translating base 21, the axis hole center line of lower carriage and the axis hole center line of bearing pedestal are located along the same line.The second feed screw nut 33 is with the installation of on the second screw mandrel 32 and forms a ball wire bar pair, and the second feed screw nut 33 is installed on a screw rodb base, and two slide blocks that screw rodb base is connected with elevating bracket 31 by slide block mounting panel are connected, and form a bridge.The output shaft of the second servomotor 34 is connected by the second shaft coupling 37 and the second screw mandrel 32.Simultaneously, be equiped with three photoelectric sensors along the linear slide rail of elevating bracket 31, three photoelectric sensors control for coordinating with PLC initial point, terminal and the excess of stroke position that elevating bracket 31 vertically moves, change the installation site of three photoelectric sensors can be corresponding vertically mobile initial point, terminal and excess of stroke position of adjustment elevating bracket 31, to ensure that the accurate elevating movement of manipulator 4 extracts coil groups or coil groups is inserted in the iron core slot of rotor from split a tension-torsion shaped device.The second servomotor 34 drives the second screw mandrel 32 to rotate, and can make the second feed screw nut 33 and elevating bracket 31 move up and down along the linear slide rail of the second guide assembly 35.

In the present embodiment, as shown in Fig. 4 to Fig. 8, elevating bracket 31 is equiped with axis and is vertically installed on the circumferential side wall of cylinder holder 42 at the even interval of 42,29 claws of cylinder holder 41 of layout, and each claw 41 can fold up coil groups along radially wobbling of cylinder holder 42.Specifically, each claw 41 includes swing arm 411 and is connected in the clamp 412 of swing arm 411 lower ends, on clamp 412, offer a groove, a step is established in the lower end of swing arm 411, the step of swing arm 411 inserts in the groove of clamp 412, then adopts elastic cylindrical pin 50 that swing arm 411 and clamp 412 are connected and fixed.The making material of claw 41 adopts 40Cr, the manufacture craft of swing arm 411 and clamp 412 is first made an annular workpieces to carry out entirety processing and modified heat treatment, after heat treatment, again annular workpieces is carried out to monolithic and be cut into swing arm 411 one by one, the geomery of all claws 41 is all identical, guarantee in clamping process, the distance that all clamps 412 move radially is consistent, guarantee to clamp accurately and reliably, after clamping, whole coil groups of splitting pulling shaping once can be extracted from split a tension-torsion shaped device by manipulator 4, and can there is not slippage and radial deformation in coil groups.Cylinder holder 42 is a cylindrical revolving body, on the circumferential side wall of cylinder holder 42, offer vertically 29 installation location notchs 421, article 29, installation location notch 421 is corresponding one by one with 29 claws 41, the width that location notch 421 is installed is consistent with the width of swing arm 411, each bottom surface that location notch 421 is installed is made up of superposed ramped bottom surface and the vertical bottom surface that is positioned at bottom, and ramped bottom surface tilts to extend to the axis of cylinder holder 42 from bottom to top.Swing arm 411 is provided with and swings installation portion 415, swing installation portion 415 and be U-shaped, the recess of U-shaped swing installation portion 415 is fastened on bearing pin 45, and be positioned to install in location notch 421 by bearing pin 45 and ramped bottom surface, swing arm 411 entirety after installation are arranged in installs location notch 421, and can swing around bearing pin 45.Clamp 412 is positioned at the below of cylinder holder 42, the corresponding radial direction reciprocating motion along cylinder holder 42 of clamp 412 in the time that swing arm 411 swings, thus can clamp or decontrol coil groups.Fold up driven unit and comprise tapered sleeve 43 and telescopic drive part 44, telescopic drive part 44 adopts cylinder, tapered sleeve 43 is sheathed on the outside of cylinder holder 42, the expansion link of cylinder is connected with tapered sleeve 43 and can drives vertically reciprocating motion of tapered sleeve 43, the upper end of swing arm 411 tilts to extend to the upper end of tapered sleeve 43, formation can be moved upward and be promoted to make outwards the first wobble drive portion 413 of swing of claw 41 by tapered sleeve 43, the bottom of swing arm 411 arranges the consistent conical surface of tapering with clamp 412 simultaneously and forms the second wobble drive portion 414, tapered sleeve 43 moves downward the second wobble drive portion 414 that can promote inwardly swings claw 41.

Above-mentioned tapered sleeve 43 is a cylindrical sleeve, the upper end of its endoporus is provided with first conical surface for promoting the first wobble drive portion 413, the lower end of endoporus is provided with second conical surface for promoting the second wobble drive portion 414, and the tapering of second conical surface is consistent with the tapering of the second wobble drive portion 414.First conical surface and second conical surface play promotion guide effect, ensure that tapered sleeve 43 promotes the first wobble drive portion 413 and the second wobble drive portion 414 reliably, smoothly, the definite of second conical surface is to adopt adaptive method, by contrast test data, obtain best wedging angle, when clamping, make coil groups toward interior contraction 0.1mm, can guarantee coil overall clamping the smooth iron core slot that inserts rotor.Between cylinder holder 42 and tapered sleeve 43, be also provided with wear ring 49, cylinder holder 42 is provided with the installation annular groove of arranging around its circumferential side wall, bearing pin 45 and wear ring 49 are installed in this installation annular groove, and the bearing pin 45 of 29 claws 41 all clamps by wear ring 49 bottom that is positioned to install annular groove, be bearing pin 45 outsides that wear ring 49 is set in 29 claws 41,29 claws 41 are connected with tapered sleeve 43.

In the present embodiment, cylinder holder 42 is connected with the drive end of lifting driven unit 3 by single-revolution governor motion 46, this revolving and adjusting mechanism 46 comprises cylinder revolving bed 461, connecting rod 462 and mount pad 463, mount pad 463 is installed on elevating bracket 31, the upper end of mount pad 463 is provided with an incomplete cylindrical step hole, rotating being installed in cylindrical step hole and by compact heap of cylinder revolving bed 461 positions, one end of connecting rod 462 is connected and fixed through the through hole at mount pad 463 middle parts and the bottom of cylinder revolving bed 461, the other end of connecting rod 462 and cylinder holder 42 are connected and fixed.The front portion of cylinder revolving bed 461 is provided with an adjusting rod 464, this adjusting rod 464 is for being connected in the screw rod of cylinder revolving bed 461, on mount pad 463, be fixedly installed adjustment block, adjustment block is provided with two adjustment screw 465 that threaded engagement connects, two adjustment screw 465 are symmetry shape and are divided into the left and right sides of adjusting rod 464, and the end of two adjustment screw 465 all offsets with adjusting rod 464, regulating two adjustment screw 465 can promote adjusting rod 464 swings, make cylinder revolving bed 461 also corresponding rotation change its rotary position on mount pad 463, cylinder holder 42 is also with the corresponding rotation of rotation of cylinder revolving bed 461, and then change is installed on the rotary position of the claw 41 on cylinder holder 42, can make like this position of each claw 41 just in time corresponding one by one with the position of U line, ensure to clamp precisely reliable, arrange after revolving and adjusting mechanism 46 mechanisms, greatly facilitate the installment and debugging of equipment, also reduced and manufactured difficulty.

In the present embodiment, cylinder is arranged on the upper end of elevating bracket 31, and the expansion link of cylinder is connected with tapered sleeve 43 by floating junction 47 and guidance set 48.Wherein, guidance set 48 comprises push pedal 481, connect cover plate 482, three slide-bars 483 and four support columns 484, push pedal 481 is connected with the expansion link of cylinder by floating junction 47, on cylinder revolving bed 461, corresponding each slide-bar 483 is equipped with linear bearing, mount pad 463 is equipped with mounting hole in the position of each linear bearing, slide-bar 483 is vertically arranged in corresponding linear bearing and mounting hole, mounting hole works the effect of dodging in the time that slide-bar 483 rotates with cylinder revolving bed 461, the upper end of three slide-bars 483 is all connected with push pedal 481, the lower end of three slide-bars 483 all be connected cover plate 482 and be connected, connecting cover plate 482 middle parts is provided with through hole and is set on connecting rod 462.The top of tapered sleeve 43 is provided with a flange arrangement, and four support columns 484 are connected in flange arrangement by securing member and connect between cover plate 482, tapered sleeve 43 are fastened on to the lower end that connects cover plate 482.Cylinder drives tapered sleeve 43 to move up and down by floating junction 47, push pedal 481, slide-bar 483, connection cover plate 482 and support column 484, and then drives the corresponding swing of claw 41.

The utility model is as follows for the operation principle of the automatic integral clamp threader of rotor:

Coil groups is split after a tension-torsion moulding through splitting a tension-torsion shaped device, upwards eject and make coil groups part expose mould by splitting ejecting mechanism in a tension-torsion shaped device, the first servomotor 24 drives translating base 21 along the first guide assembly 25 translational motions, manipulator 4 is moved to split a tension-torsion shaped device directly over, now, the axis of cylinder holder 42 and the center line of coil groups of manipulator 4 overlap, and 29 claws 41 of manipulator 4 are in open configuration.

The second servomotor 34 drives elevating bracket 31 to move down along the second guide assembly 35, makes manipulator 4 move to clamp position, and 29 claws 41 of manipulator 4 are corresponding one by one with the position of 29 U lines of coil groups.The expansion link of cylinder stretches out, and orders about tapered sleeve 43 and moves down with respect to cylinder holder 42, and tapered sleeve 43 promotes the second wobble drive portion 414 of all claws 41, makes claw 41 radially inwardly swing and clamp coil groups.

The expansion link of cylinder keeps stretching out state, makes the tight coil groups of claw 41 retaining clip, and the second servomotor 34 drives elevating bracket 31 to move up along the second guide assembly 35, and manipulator 4 moves up coil groups is extracted from split a tension-torsion shaped device.The first servomotor 24 drives translating base 21 along the first guide assembly 25 translational motions, make manipulator 4 just in time move to rotor directly over.The second servomotor 34 drives elevating bracket 31 to move down along the second guide assembly 35, and manipulator 4 moves down coil groups is inserted in the iron core slot of rotor.

The expansion link retraction of cylinder, orders about tapered sleeve 43 and moves up with respect to cylinder holder 42, and tapered sleeve 43 promotes the first wobble drive portion 413 of all claws 41, makes claw 41 radially outward swing and unclamp coil groups.The second servomotor 34 drives elevating bracket 31 to move up along the second guide assembly 35, and manipulator 4 is also moved up, and completes the threading to rotor.

Finally, make manipulator 4 move reset by the first servomotor 24 and the second servomotor 34, prepare to carry out threading action next time.

The above is only preferred implementation of the present utility model, and protection range of the present utility model is also not only confined to above-described embodiment.For those skilled in the art, do not departing from the improvement that obtains under the utility model technical conceive prerequisite and conversion also should be considered as protection range of the present utility model.

Claims (10)

1. the automatic integral clamp threader for rotor, it is characterized in that: comprise bracket component (1), fold up the manipulator (4) of the coil groups of splitting a tension-torsion moulding and the driven unit for driving described manipulator (4) to move for entirety between clamp station and threading station, it is upper that described driven unit is installed in described bracket component (1), and described manipulator (4) is provided with around multiple claws (41) of even circumferential layout and for driving described multiple claw (41) synchronization action to fold up the driven unit that folds up of described coil groups.

2. the automatic integral clamp threader for rotor according to claim 1, it is characterized in that: the drive end of described driven unit is equiped with cylinder holder (42), described multiple claw (41) evenly interval is installed on the circumferential side wall of described cylinder holder (42) and can folds up described coil groups along radially wobbling of cylinder holder (42), the described driven unit that folds up comprises tapered sleeve (43) and telescopic drive part (44), described tapered sleeve (43) is sheathed on the outside of described cylinder holder (42), each claw (41) is provided with the first wobble drive portion (413) that is positioned at tapered sleeve (43) one end and the second wobble drive portion (414) that is positioned at tapered sleeve (43) other end, described telescopic drive part (44) is connected with described tapered sleeve (43) and can drives described tapered sleeve (43) to promote described the first wobble drive portion (413) and the second wobble drive portion (414) and makes claw (41) swing.

3. the automatic integral clamp threader for rotor according to claim 2, it is characterized in that: described claw (41) comprises swing arm (411) and is fixedly connected on the clamp (412) of described swing arm (411) lower end, the circumferential side wall of described cylinder holder (42) is provided with installs location notch (421), described swing arm (411) is by swingable being installed in described installation location notch (421) of bearing pin (45), the upper end of described swing arm (411) tilts to extend to form described the first wobble drive portion (413), the bottom of described swing arm (411) and clamp (412) form described the second wobble drive portion (414) by the conical surface is set.

4. the automatic integral clamp threader for rotor according to claim 3, it is characterized in that: the bottom surface of described installation location notch (421) is made up of superposed ramped bottom surface and the vertical bottom surface that is positioned at bottom, described ramped bottom surface tilts to extend to the axis of described cylinder holder (42) from bottom to top, described swing arm (411) is provided with and swings installation portion (415), described swing installation portion (415) is U-shaped, the recess of described U-shaped swing installation portion (415) is fastened in described bearing pin (45) and goes up and pass through bearing pin (45) and ramped bottom surface is positioned to install in location notch (421), one end of described tapered sleeve (43) is provided with first conical surface for promoting the first wobble drive portion (413), between described tapered sleeve (43) and cylinder holder (42), be provided with wear ring (49), described cylinder holder (42) is provided with the installation annular groove of arranging around its circumferential side wall, described bearing pin (45) and wear ring (49) are installed in described installation annular groove, and all bearing pins (45) are positioned the bottom of described installation annular groove by described wear ring (49) clamping.

5. the automatic integral clamp threader for rotor according to claim 2, it is characterized in that: described cylinder holder (42) is connected with the drive end of described driven unit by single-revolution governor motion (46), described revolving and adjusting mechanism (46) comprises cylinder revolving bed (461), connecting rod (462) and the mount pad (463) affixed with the drive end of described driven unit, described cylinder revolving bed (461) is rotating to be installed on described mount pad (463), described cylinder holder (42) is connected with described cylinder revolving bed (461) by connecting rod (462), described cylinder revolving bed (461) is provided with adjusting rod (464), the both sides of described adjusting rod (464) are equipped with the adjustment screw (465) that cylinder revolving bed (461) is rotated for promoting adjusting rod (464).

6. the automatic integral clamp threader for rotor according to claim 5, it is characterized in that: the telescopic drive end of described telescopic drive part (44) is connected with described tapered sleeve (43) by floating junction (47) and guidance set (48), described guidance set (48) comprises push pedal (481), connect cover plate (482), more than two slide-bar (483) and two are with upper support column (484), described push pedal (481) is connected with the telescopic drive end of described telescopic drive part (44) by floating junction (47), the upper corresponding each slide-bar (483) of described cylinder revolving bed (461) is equipped with linear bearing, described mount pad (463) is equipped with mounting hole in the position of each linear bearing, described slide-bar (483) is arranged in corresponding linear bearing and mounting hole, the upper end of all slide-bars (483) is all connected with described push pedal (481), the lower end of all slide-bars (483) is all connected with the described cover plate (482) that is connected, described tapered sleeve (43) is connected with the described cover plate (482) that is connected with upper support column (484) by described two.

7. according to the automatic integral clamp threader for rotor described in any one in claim 1 to 6, it is characterized in that: described driven unit comprises the lifting driven unit (3) of the driven in translation assembly (2) being installed on described bracket component (1) and the drive end that is installed in described driven in translation assembly (2), described driven in translation assembly (2) comprises translating base (21), the first screw mandrel (22), the first feed screw nut (23) and the first servomotor (24), described translating base (21) is slidedly arranged on described bracket component (1) by two group of first guide assembly (25) along continuous straight runs, described the first screw mandrel (22) is installed on described bracket component (1) by clutch shaft bearing assembly (26), described the first feed screw nut (23) is with the installation of described the first screw mandrel (22) above and is connected with described translating base (21), described the first servomotor (24) is connected with described the first screw mandrel (22) by the first shaft coupling (27).

8. the automatic integral clamp threader for rotor according to claim 7, it is characterized in that: described lifting driven unit (3) comprises elevating bracket (31), the second screw mandrel (32), the second feed screw nut (33) and the second servomotor (34), described elevating bracket (31) is vertically slidedly arranged on described translating base (21) by two group of second guide assembly (35), described the second screw mandrel (32) is installed on described translating base (21) by the second bearing assembly (36), described the second feed screw nut (33) is with the installation of described the second screw mandrel (32) above and is connected with described elevating bracket (31), described the second servomotor (34) is connected with described the second screw mandrel (32) by the second shaft coupling (37).

9. the automatic integral clamp threader for rotor according to claim 8, it is characterized in that: described driven in translation assembly (2) is provided with three photoelectric sensors that are respectively used to detect initial point, terminal and excess of stroke position that translating base (21) moves horizontally, and described lifting driven unit (3) is provided with three and is respectively used to detect the vertically photoelectric sensors of mobile initial point, terminal and excess of stroke position of elevating bracket (31).

10. according to the automatic integral clamp threader for rotor described in any one in claim 1 to 6, it is characterized in that: described bracket component (1) comprises supporting plate (11) and two root posts (12), the bottom of described column (12) is provided with the base (121) for being connected and fixed with workbench, the upper locking of each column (12) is provided with anchor ear (13), and described supporting plate (11) is installed on the anchor ear (13) of described two columns (12) by securing member.