CN210123932U - Winding machine capable of automatically adjusting die - Google Patents

Abstract

The utility model provides a coiling machine that can transfer mould automatically, including the base, support the stand of many vertical settings on the base and support the wire winding aircraft nose on the stand through the layer board, the wire winding aircraft nose include the front mould and with front mould complex back mould, the front mould can be along the fore-and-aft direction each other or deviate from the removal with the back mould, the wire winding aircraft nose can along the fore-and-aft direction round trip movement. The front die and the rear die of the winding machine can be far away from or close to each other, and a large die adjusting range can be achieved.

Description

Winding machine capable of automatically adjusting die

Technical Field

The utility model relates to an electric machine coil's production facility especially relates to a coiling machine of mould can be transferred automatically.

Background

The 201610993660.3 patent discloses a die-adjustable winding machine that can increase the distance between the rear die and the front die by adjusting the rear die, thus producing coils of different specifications. However, only the rear die can be adjusted, so that the adjustment distance of the rear die is limited, and the centers of the rear die and the front die are changed in the process of adjusting the rear die, but the positions of the winding flying forks can be changed, so that the rotation center of the winding flying forks is inconsistent with the center of the die, and the stability of winding is affected.

SUMMERY OF THE UTILITY MODEL

A primary object of the present invention is to provide a winding machine capable of automatically adjusting a mold, in which a front mold and a rear mold of the winding machine can be adjusted simultaneously to solve the above problems.

In order to achieve the above purpose, the utility model adopts the technical scheme that: the utility model provides a coiling machine that can transfer mould automatically, includes the base, supports the stand of many vertical settings on the base and supports the wire winding aircraft nose on the stand through the layer board, the wire winding aircraft nose include the front mould and with front mould complex back mould, its characterized in that, the front mould can be along the fore-and-aft direction each other or deviate from the removal with the back mould, the wire winding aircraft nose can along fore-and-aft direction round trip movement.

Preferably, the winding mechanism comprises a suspension plate horizontally suspended below the supporting plate, a die lower pressing plate supported on the suspension plate through a plurality of vertically arranged support rods, and a suspension rod non-rotatably fixed on the die lower pressing plate, wherein the lower end of the suspension rod penetrates through the suspension plate, the lower end of the suspension rod is provided with a die mounting plate, the front die and the rear die are movably mounted on the die mounting plate along the front-rear direction, and the suspension plate is movable relative to the supporting plate along the front-rear direction.

Preferably, the front die and the rear die are provided with adjusting nut pairs with axes parallel to the front-rear direction, the two adjusting nut pairs are arranged oppositely, and the two adjusting nut pairs are in threaded fit with the same adjusting screw rod.

Preferably, a first gear is arranged at the rear end of the adjusting screw rod, a ring of teeth is arranged on the rear end surface of the first gear along the axis of the first gear, an installation frame capable of moving in the front-back direction is arranged on the lower surface of the suspension plate, a second gear is arranged on one side of the installation frame facing the first gear, the second gear is arranged coaxially with the first gear, a ring of teeth is arranged on one end surface of the second gear facing the first gear, and the teeth on the first gear can be meshed with the teeth of the second gear.

Preferably, a machine head fixing plate is arranged at the top end of the supporting rod, a mold pressing screw rod is vertically and rotatably arranged on the machine head fixing plate, a mold pressing nut pair matched with the mold pressing screw rod is arranged on the mold pressing plate, and a mold pressing motor in transmission connection with the mold pressing screw rod is arranged on the machine head fixing plate.

Preferably, the suspension rod is rotatably sleeved with a transmission sleeve, the transmission sleeve is sleeved with a connecting flange, the connecting flange is fixed on the suspension plate through a bearing, a fly fork fixing plate is horizontally arranged at the lower end of the connecting flange, and a winding fly fork for winding a front mold and a rear mold is arranged at one end of the fly fork fixing plate.

Preferably, the upper end of the connecting flange is provided with a first belt pulley, the first belt pulley is connected with the connecting flange through a bolt, the first belt pulley is sleeved on the transmission sleeve, and the first belt pulley is connected with the transmission sleeve in a non-relatively rotatable manner.

Preferably, the upper end of the transmission sleeve is rotatably fixed on the wire pushing plate, the wire pushing plate is supported on the supporting rod in a vertically movable mode, a second belt pulley is fixed at the top end of the transmission sleeve, a spline shaft is rotatably arranged between the machine head fixing plate and the suspension plate, a third belt pulley is arranged on the spline shaft, the third belt pulley and the second belt pulley are in transmission connection through a second belt, the spline shaft penetrates through the wire pushing plate, and the third belt pulley can rotate relative to the wire pushing plate but cannot move relative to the wire pushing plate in the vertical direction.

Preferably, a fourth belt pulley is rotatably arranged on the lower die pressing plate, the fourth belt pulley is rotatably fixed on the fourth belt pulley, a fifth belt pulley in belt transmission connection with the fourth belt pulley is further arranged on the spline shaft, and the fifth belt pulley is rotatably fixed below the lower die pressing plate.

Preferably, a wire guide wheel is arranged on the machine head fixing plate, a through hole is formed in the machine head fixing plate, through holes are formed in the fourth belt pulley, the second belt pulley and the first belt pulley, and copper wires to be wound pass through the wire guide wheel and the through holes and enter the winding flying fork.

Drawings

Fig. 1 and 2 are assembly views of a preferred embodiment according to the present invention;

fig. 3-6 are block diagrams of a winder head according to a preferred embodiment of the present invention;

fig. 7 is an enlarged view at a.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

The winding machine capable of automatically adjusting the die as shown in fig. 1-7 comprises a base 1, a plurality of vertically arranged upright posts 2 supported on the base 1, and a winding machine head 10 supported on the upright posts 2 through a supporting plate 3.

The winding machine head 10 comprises a suspension plate 101 horizontally suspended below a supporting plate 3, a die pressing plate 101 supported on the suspension plate 101 through a plurality of vertically arranged support rods 122, and a suspension rod 102 fixed on the die pressing plate 101 in a non-rotatable manner, wherein the upper end of the suspension rod 102 is fixed with the die pressing plate 101, the lower end of the suspension rod passes through the suspension plate 101, a die mounting plate 103 is arranged at the lower end of the suspension rod 102, a die is arranged on the die mounting plate 103, the die comprises a front die 301 and a rear die 302 matched with the front die, a coil is wound on the front die 301 and the rear die 302 during winding, and the specific winding principle adopts the prior art, and detailed description is omitted here.

Preferably, the front mold 301 and the rear mold 302 are movably mounted on the mold mounting plate 103 in the front-rear direction. Specifically, a mold slider 314 is provided at the upper end of each of the front mold 301 and the rear mold 302, and a mold rail 315 extending in the front-rear direction is provided on the mold mounting plate 103, the mold slider 314 being slidably fitted to the mold rail 315. The front die 301 and the rear die 302 are provided with adjusting nut pairs 313 with axes parallel to the front-rear direction, the two adjusting nut pairs 313 have the same specification and are oppositely arranged, the two adjusting nut pairs 313 are in threaded fit with the same adjusting screw rod 304, the two adjusting nut pairs 313 are oppositely arranged, the turning directions of the two adjusting nut pairs on the adjusting screw rod 304 are opposite, and the front die 301 and the rear die 302 can be driven to move towards or away from each other by rotating the adjusting screw rod 304 to realize die adjustment.

Further, a first gear 305 is disposed at the rear end of the adjusting screw 304, and a ring of teeth is disposed on the rear end surface of the first gear 305 along the axis thereof. A mounting frame 308 which can move in the front-back direction is arranged on the lower surface of the suspension plate 101, a second gear 306 is arranged on one side of the mounting frame 308 facing the first gear 305, the second gear 306 is coaxially arranged with the first gear 305, one end surface of the second gear 306 facing the first gear 305 is provided with a ring of teeth, the teeth on the first gear 305 can be meshed with the teeth of the second gear 306, and further, the rotation of the adjusting screw rod 304 can be realized by controlling the rotation of the second gear 306 so as to adjust the distance between the front mold 301 and the rear mold 302. An adjusting motor 307 is further arranged on the mounting frame 308, the adjusting motor 307 is in transmission connection with the second gear 306, and the front mold 301 and the rear mold 302 can be adjusted by controlling the rotation of the adjusting motor 307.

Specifically, a connecting plate 316 is disposed at a position corresponding to the mounting bracket 308 on the lower surface of the suspension plate 101, a second slider 309 is disposed at an upper end of the mounting bracket 308, a second guide rail 310 extending in the front-rear direction is disposed on the lower surface of the connecting plate 316, the second slider 309 is engaged with the second guide rail 310, a second motor 312 is disposed at a rear end of the connecting plate 316, an output shaft of the second motor 312 extends forward, a second lead screw 311 extending in the front-rear direction is connected to an output shaft of the second motor 312, and the second lead screw 311 is in threaded connection with the mounting bracket 308, so that the engagement and disengagement of the first gear 305 and the second gear 306 can be realized by controlling the rotation of the second motor 312. When winding the wire to the die by the winding flyer 400, since the winding flyer 400 rotates around the die, by providing the adjustment motor 307 in a form separable from the adjustment screw 304, it is possible to avoid interference with the adjustment motor 307 when the winding flyer 400 rotates at a high speed.

The base 1 is further provided with a turntable 21, the turntable 21 is horizontally arranged and can rotate relative to the base 21, the turntable 1 is provided with a plurality of winding cups 22, the winding cups 22 are located on the same circumference relative to the rotation axis of the turntable 21 and are arranged at equal angles, and the winding cups 22 are used for receiving coils wound on a mold. Specifically, after the coil is wound on the mold, the mold is lowered, the front mold 301 is inserted into the winding cup 22 located immediately below the front mold, the winding cup 22 is located at the lower line position, and the plurality of winding cups 22 are alternately moved to the lower line position by rotation.

Since the turntable 21 cannot move back and forth, after the front die 301 and the rear die 302 are adjusted by rotating the adjusting screw 304, the position of the front die 301 moves, and at this time, the front die 301 is no longer aligned with the lower line position, in order to move the front die 301 to be aligned with the winding cup 22 at the lower line position, the suspension plate 101 is movably suspended on the supporting plate 3 along the front-back direction, and the front die 301 and the rear die 302 can be driven to move along the front-back direction by moving the suspension plate 101 along the front-back direction, so that after the distance between the front die 301 and the rear die 302 is adjusted, the front die 301 and the rear die 301 can be driven by the suspension plate 101 to move to be aligned with the winding cup 22 at the lower line position to push the coil on the die to the winding cup 22 at the lower line position.

In order to realize the movement of the suspension plate 101, a first screw rod 121 is rotatably arranged on the lower surface of the supporting plate 3, the axis of the first screw rod 121 is parallel to the front-back direction, the first screw rod 121 is immovable along the axial direction of the supporting plate 3 relative to the supporting plate, the first screw rod 121 is in threaded connection with the suspension plate 101, a first motor 23 is arranged on the supporting plate 3, the output shaft of the first motor 23 is in belt connection with the first screw rod 121, and the first screw rod 121 can be driven to rotate by controlling the first motor 23 so as to drive the suspension plate 101 to move back and forth. Further, the suspension plate 101 and the pallet 3 are connected to a first guide rail 127 via a first slider 120, and a longitudinal direction of the first guide rail 127 is parallel to the front-rear direction.

The top end of the supporting rod 122 is provided with a machine head fixing plate 115, the machine head fixing plate 115 is vertically and rotatably provided with a die pressing screw rod 112, the die pressing plate 111 is provided with a die pressing nut pair 113 matched with the die pressing screw rod 112, the machine head fixing plate 115 is provided with a die pressing motor 114 in transmission connection with the die pressing screw rod 112, and the die pressing plate 111 can be driven to move up and down by controlling the rotation of the die pressing motor 114 so as to drive the front die 301 to be inserted into the winding cup 22 located at the lower line position or be pulled out of the winding cup 22.

The suspension rod 102 is rotatably sleeved with a transmission sleeve 104, the transmission sleeve 104 is provided with a connecting flange 118, and the connecting flange 118 is fixed on the suspension plate 101 through a bearing. The winding fly fork 400 is fixed at the lower end of the connecting flange 118 through a fly fork fixing plate 401, so that the winding fly fork 400 can be driven to rotate when the connecting flange 118 rotates. Preferably, the flying fork fixing plate 401 is sleeved on the transmission sleeve 104 and is symmetrical with respect to the axis of the transmission sleeve 104, so that the stability of the winding flying fork 400 during rotation can be ensured.

The first belt pulley 106 is arranged at the upper end of the connecting flange 118, the first belt pulley 106 is connected with the connecting flange 118 through bolts, and the first belt pulley 106 is sleeved on the transmission sleeve 104. A winding motor 119 is arranged on the suspension plate 101 and on one side of the transmission sleeve 104, a belt pulley is arranged on an output shaft of the winding motor 119, the belt pulley on the output shaft of the winding motor 119 is in transmission connection with the first belt pulley 106 through a first belt 107, and thus the winding fly fork 400 can be driven to rotate by controlling the rotation of the winding motor 119.

The upper end of the transmission sleeve 104 is rotatably fixed on a wire pushing plate 105, and the wire pushing plate 105 is supported on a supporting rod 122 in a manner of moving up and down. The wire pushing cylinder 123 is arranged on the machine head fixing plate 115, a cylinder rod of the wire pushing cylinder 123 is vertically arranged, a connecting rod 124 is arranged on the cylinder rod of the wire pushing cylinder 123, the lower end of the connecting rod 124 penetrates through the lower die pressing plate 111 to be connected with the wire pushing plate 105, and therefore the up-and-down movement of the transmission sleeve 104 can be achieved by controlling the extension and retraction of the wire pushing cylinder 123.

In order to ensure that the first pulley 106 can rotate and cannot move up and down along with the transmission sleeve 104, a key slot 1041 extending up and down is formed in the outer wall surface of the transmission sleeve 104, a sliding key 1061 is arranged on the first pulley 106, one end of the sliding key 1061 extends into the key slot 1041, and the sliding key 1061 can slide in the key slot 1041.

The lower end of the transmission sleeve 104 extends to the lower part of the fly fork fixing plate 401, a wire pushing connecting plate 117 is fixed at the lower end of the transmission sleeve 104, a U-shaped wire pushing rod 116 is arranged on the wire pushing connecting plate 117, and two ends of the wire pushing rod 116 are movably fixed on the wire pushing connecting plate 117 along the front-back direction to move back and forth along the corresponding front mold 301 or rear mold 302. The front die 301 or the rear die 302 is provided with a die groove 303, the horizontal part of the wire pushing rod 116 passes through the die groove 303, and during winding, the horizontal part of the wire pushing rod 116 is arranged at a position close to the upper end of the die groove 303, copper wires are wound on the front die 301 and the rear die 302 which are positioned below the horizontal part of the wire pushing rod 116, after the winding is completed, the front die 301 is inserted into the corresponding winding cup 22, the wire pushing plate 105 moves downwards and pushes the transmission sleeve 104 to move downwards, the transmission sleeve 104 drives the wire pushing connecting plate 117 to move downwards, and the wire pushing connecting plate 11 drives the wire pushing rod 116 positioned on the front die 301 and the rear die 302 to move downwards so as to push coils on the front die 301 and the rear die 302 onto the winding cup 22.

Specifically, the wire pushing connecting plate 117 is fixed at the lower end of the transmission sleeve 104 through a bearing, so that the wire pushing connecting plate 117 is not driven to rotate in the process that the transmission sleeve 104 drives the wire pushing connecting plate 117 to move up and down.

A second belt pulley 108 is arranged at the top end of the transmission sleeve 104, and the second belt pulley 108 is fixed at the top end of the transmission sleeve 104 through a screw. A spline shaft 125 is rotatably arranged between the handpiece fixing plate 115 and the suspension plate 101, a third belt pulley 110 is arranged on the spline shaft 125, and the third belt pulley 110 is in transmission connection with the second belt pulley 108 through a second belt 109. The spline shaft 125 passes through the push plate 105. A bearing 1103 is provided between the spline shaft 125 and the push plate 105. Specifically, in order to fix the bearing 1103, the spline shaft 125 is sleeved with an inner ring 1101, the inner ring of the bearing 1103 is sleeved on the inner ring 1101, two sides of the inner ring of the bearing 1103 are fixed on the inner ring 1101, the inner ring 1101 and the spline shaft 125 are connected by a spline so that the inner ring 1101 can move back and forth relative to the spline shaft 125, two sides of the outer ring of the bearing 1103 are fixed on the wire pushing plate 105, and the upper end of the inner ring 1101 is fixed with the third belt pulley 110, so that the transmission sleeve 104 can drive the second belt pulley 108 to rotate, the second belt pulley 108 can drive the third belt pulley 110 to rotate, and the third belt pulley 110 can drive the spline shaft 125 to rotate. And, because third belt pulley 110 is fixed on line ball 105, second belt pulley 108 passes through transmission sleeve 104 and fixes on line ball 105, can drive second belt pulley 108 and third belt pulley 110 and reciprocate together when the line ball reciprocates like this to can not influence the rotation of transmission sleeve 104, second belt pulley 108 and third belt pulley 110 when removing.

A fourth pulley 126 is rotatably provided on the mold lower platen 111, and the fourth pulley 126 is rotatably fixed to the fourth pulley 126. The spline shaft 125 is further provided with a fifth belt pulley 127 in belt transmission connection with the fourth belt pulley 126, the fifth belt pulley 127 is rotatably fixed below the die pressing plate 111, the connection mode of the fifth belt pulley 127 and the spline shaft 125 is the same as the connection mode of the third belt pulley 110 and the spline shaft 125, the fifth belt pulley 127 can rotate relative to the die pressing plate 111 but cannot move up and down relatively, and meanwhile, the fifth belt pulley 127 can move up and down relative to the spline shaft 125 but cannot rotate relatively, so that when the die pressing plate 111 moves up and down, the fourth belt pulley 126 and the fifth belt pulley 127 can be driven to move up and down without affecting the rotation of the fourth belt pulley 126 and the fifth belt pulley 127.

The wire guide wheel 603 is arranged on the handpiece fixing plate 115, the through hole 601 is arranged on the handpiece fixing plate 603, the through holes 602 are arranged on the fourth belt pulley 126, the second belt pulley 108 and the first belt pulley 106, the copper wire 6 enters the winding fly fork 400 by bypassing the wire guide wheel 603 and the through holes 602, and the rotation of the fourth belt pulley 126, the second belt pulley 108, the first belt pulley 106 and the winding fly fork 400 is driven by the winding motor 119, so that the rotation of the first belt pulley 106 and the winding fly fork 400 is synchronous, and the copper wire 6 can be prevented from being wound on the suspension rod 102 and other structures. Of course, through holes are also provided at positions where the structures actually connected to the fourth pulley 126, the second pulley 108, and the first pulley 106 correspond to the corresponding through holes 602, so that the copper wire 6 can pass through.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the principles of the present invention may be applied to any other embodiment without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a coiling machine that can transfer mould automatically, includes the base, supports the stand of many vertical settings on the base and supports the wire winding aircraft nose on the stand through the layer board, the wire winding aircraft nose include the front mould and with front mould complex back mould, its characterized in that, the front mould can be along the fore-and-aft direction each other or deviate from the removal with the back mould, the wire winding aircraft nose can along fore-and-aft direction round trip movement.

2. The winding machine capable of automatically adjusting the die according to claim 1, wherein the winding mechanism comprises a suspension plate horizontally suspended below the supporting plate, a die pressing plate supported on the suspension plate through a plurality of vertically arranged support rods, and a suspension rod non-rotatably fixed on the die pressing plate, the lower end of the suspension rod penetrates through the suspension plate, the lower end of the suspension rod is provided with a die mounting plate, the front die and the rear die are movably mounted on the die mounting plate along a front-rear direction, and the suspension plate is movable relative to the supporting plate along the front-rear direction.

3. The winding machine capable of automatically adjusting the die as claimed in claim 2, wherein the front die and the rear die are provided with adjusting nut pairs with axes parallel to the front-rear direction, the two adjusting nut pairs are oppositely arranged, and the two adjusting nut pairs are in threaded fit with the same adjusting screw rod.

4. The winding machine capable of automatically adjusting the die according to claim 3, wherein a first gear is arranged at the rear end of the adjusting screw rod, a ring of teeth are arranged on the rear end surface of the first gear along the axis of the first gear, a mounting frame capable of moving in the front-rear direction is arranged on the lower surface of the suspension plate, a second gear is arranged on one side of the mounting frame facing the first gear, the second gear is coaxially arranged with the first gear, a ring of teeth are arranged on one end surface of the second gear facing the first gear, and teeth on the first gear can be meshed with teeth of the second gear.

5. The winding machine capable of automatically adjusting the die according to claim 2, wherein a machine head fixing plate is arranged at the top end of the supporting rod, a die pressing screw rod is vertically and rotatably arranged on the machine head fixing plate, a die pressing nut pair matched with the die pressing screw rod is arranged on the die pressing plate, and a die pressing motor in transmission connection with the die pressing screw rod is arranged on the machine head fixing plate.

6. The winding machine capable of automatically adjusting the die according to claim 2, wherein a transmission sleeve is rotatably sleeved on the suspension rod, a connecting flange is sleeved on the transmission sleeve and fixed on the suspension plate through a bearing, a flying fork fixing plate is horizontally arranged at the lower end of the connecting flange, and a winding flying fork for winding the front die and the rear die is arranged at one end of the flying fork fixing plate.

7. The winding machine capable of automatically adjusting the die as claimed in claim 6, wherein a first belt pulley is arranged at the upper end of the connecting flange, the first belt pulley is connected with the connecting flange through a bolt, the first belt pulley is sleeved on the transmission sleeve, and the first belt pulley is connected with the transmission sleeve in a non-relatively rotatable manner.

8. The automatic die-adjusting winding machine according to claim 7, wherein an upper end of the transmission sleeve is rotatably fixed to a wire pushing plate supported on the support rod in a vertically movable manner, a second pulley is fixed to a top end of the transmission sleeve, a spline shaft is rotatably provided between the head fixing plate and the suspension plate, a third pulley is provided on the spline shaft, the third pulley and the second pulley are in transmission connection through a second belt, the spline shaft penetrates through the wire pushing plate, and the third pulley is rotatable but not movable in a vertical direction relative to the wire pushing plate.

9. The automatic die adjusting winding machine according to claim 8, wherein a fourth pulley is rotatably disposed on the die holding plate, the fourth pulley is rotatably fixed to the fourth pulley, a fifth pulley is disposed on the spline shaft, the fifth pulley is in belt transmission connection with the fourth pulley, and the fifth pulley is rotatably fixed below the die holding plate.

10. The winding machine capable of automatically adjusting the die as claimed in claim 9, wherein a wire guiding wheel is provided on the head fixing plate, a through hole is provided on the head fixing plate, through holes are provided on the fourth belt pulley, the second belt pulley and the first belt pulley, and the copper wire to be wound is wound around the wire guiding wheel and each through hole to enter the winding flying fork.

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