CN117133540A - Production equipment for medical high-current inductor - Google Patents

Abstract

The invention discloses production equipment for a medical high-current inductor, which comprises an equipment carrying box, an active paying-off machine, a wire passing resistance wheel, a cross skeleton mechanism, a skeleton transposition mechanism, an XYZ shaft moving mechanism and a cutting mechanism, wherein the X and Y shafts are connected with the equipment carrying box through a wire passing resistance wheel; after an operator introduces the skeleton into the cross skeleton mechanism, starting the active paying-off machine and the wire passing resistance wheel cable, introducing the wire passing resistance wheel cable into the XYZ shaft moving mechanism and the cutting mechanism, winding the cable onto the skeleton through the movement of the XYZ shaft moving mechanism, starting the skeleton transposition mechanism, then adopting a specific winding method to wire the skeleton in a complex manner such as rotation and arrangement according to the manufacturing flow of the product, and starting the cutting mechanism to cut the wire after the winding is completed; the device has simple design, greatly reduces the manual operation difficulty in the actual operation process, effectively avoids the non-uniformity of line sequence caused by the winding ordering problem, improves the consistency of product quality, and is effectively applicable to the field and the manufacture and use of other related products.

Description

Production equipment for medical high-current inductor

Technical Field

The invention belongs to the technical field of inductor production, and particularly relates to production equipment for a medical high-current inductor.

Background

An inductor is a component capable of converting electric energy into magnetic energy and storing the magnetic energy, and has a certain inductance, which only blocks the change of current. If the inductor is in a state where no current is passing, it will attempt to block the flow of current through it when the circuit is on; if the inductor is in a state where current is flowing, it will attempt to maintain the current unchanged when the circuit is open. The inductor is also called choke, reactor and dynamic reactor.

In the actual production process of the medical high-current inductor, due to a special winding process, workers pull wires in the existing mode, machine-assisted rotation is performed to wind products, and single products can be wound for 8 times, so that the efficiency is low, the difficulty is high, the manual processing is low, and the quality cannot be ensured; the coil winding needs to be crossed and staggered, the manual operation sequence is reversed, the operation is complex, once the layering arrangement is wrong, the number of turns is wrong, the damage to the lead is very serious, the product quality is directly affected, and the wire body resistant to high current is thicker, the production and manufacturing difficulty is very high, so that the manual operation can be realized in the current production process, and the direction can be satisfied; the manufacturing process of the device at present is basically in a manual production mode, and the main problems are concentrated on low production efficiency, unstable quality and poor product consistency, and the labor intensity of workers cannot be reduced in a manual mode.

Disclosure of Invention

In order to solve the above problems in the prior art, the present invention aims to provide a production device for a medical high-current inductor, which reduces the manual operation content and effectively improves the consistency of products.

The technical scheme adopted by the invention is as follows: a production facility for a medical high current inductor, characterized in that: comprises an equipment carrying box, an active paying-off machine, a wire passing resistance wheel, a cross framework mechanism, a framework transposition mechanism, an XYZ shaft moving mechanism and a cutting mechanism, wherein the active paying-off machine is arranged on the side of the equipment carrying box, the wire passing resistance wheel is arranged above the equipment carrying box, the cross framework mechanism is arranged on one side of an inner cavity of the equipment carrying box far away from the active paying-off machine, the cross framework mechanism comprises a cross rotating shaft and a double-rod cross rotating frame fixed above the cross rotating shaft, a framework is sleeved in a long rod arranged on the double-rod cross rotating frame, a rotating shaft fixing plate in rotary connection is arranged in the middle of the cross rotating shaft, the rotating shaft fixing plate is fixedly connected with the equipment carrying box,

the framework transposition mechanism comprises a transverse displacement member, a longitudinal displacement member and a lifting displacement member, wherein the longitudinal displacement member is arranged on the transverse displacement member, the lifting displacement member is arranged on the longitudinal displacement member, and a fixed rotating member is arranged below the lifting displacement member;

an XYZ-axis moving mechanism is arranged below the active paying-off machine, the XYZ-axis moving mechanism is far away from the cross framework mechanism and is arranged in the inner cavity of the equipment receiving box, the XYZ-axis moving mechanism comprises an X-axis moving part, a Y-axis moving part and a Z-axis moving part, the X-axis moving part is provided with a Y-axis moving part, and the Y-axis moving part is provided with a Z-axis moving part;

the utility model discloses a Z axle moving part, including Z axle moving part, Z axle moving part one side be equipped with decide the mechanism and include the movable plate and fixedly connected with in the spool of movable plate, the spool inboard is equipped with the multiunit and decides the pole, it is equipped with the slide bar to decide pole one end, the other end swivelling joint has rotatory mount, rotatory mount fixed connection is in the spool.

As the preferable mode of the invention, a first motor is arranged below the cross rotating shaft, the first motor is fixedly connected with a first motor fixing plate, the first motor fixing plate is fixedly connected with the inner cavity of the equipment receiving box, a belt is arranged on the rotating shaft of the first motor, and the belt is simultaneously connected with the cross rotating shaft.

As the optimization of the invention, the transverse displacement member comprises a transposition support frame, a motor fixing plate, a second motor, a first sliding wheel, a limiting plate, a first guide rod and a bearing plate, wherein the transposition support frame is fixedly connected above an equipment bearing box, two groups of transposition support frames are arranged, the bearing plate is arranged between the two groups of transposition support frames, the motor bearing plate is provided with two groups of motor fixing plates, the motor fixing plate is provided with a second motor, a first sliding wheel is fixedly connected with a rotating shaft of the second motor, the first sliding wheel is attached to the top surface of the transposition support frame, the connecting shaft of the second motor simultaneously penetrates through the limiting plate, the limiting plate is fixedly connected with the bearing plate, the first guide rod is arranged between the two groups of limiting plates, and a rectangular sliding groove is arranged in the middle of the bearing plate.

As the preferable mode of the invention, the longitudinal displacement piece comprises an L-shaped sliding plate, a third motor, a second sliding wheel and a rectangular guide block, wherein the rectangular guide block is attached to the surface of the bearing plate, the L-shaped sliding plate is fixedly connected with the third motor, a rotating rod of the third motor penetrates through the L-shaped sliding plate, the rotating rod of the third motor is fixedly connected with the second sliding wheel, the second sliding wheel is attached to the bearing plate, the L-shaped sliding plate is provided with the rectangular guide block, the rectangular guide block is led into the rectangular sliding groove, and the rectangular guide block is connected with the first guide rod in a sliding way;

the present invention is preferably characterized in that: the lifting displacement piece comprises a rectangular connecting frame, a fourth motor, a lifting threaded rod, a polygonal lifting rod, a polygonal buckling gear, a connecting gear and a fifth motor, wherein the rectangular connecting frame is fixedly connected with an L-shaped sliding plate, the rectangular connecting frame is provided with the fourth motor, a lifting threaded rod is fixedly connected with a rotating shaft of the fourth motor, the lifting threaded rod is led into the polygonal lifting rod long rod and is rotationally connected with the polygonal lifting rod, the polygonal lifting rod penetrates through the L-shaped sliding plate and is rotationally connected with the L-shaped sliding plate, a polygonal buckling gear in sliding connection is arranged in the middle of the polygonal lifting rod, the polygonal buckling gear is meshed with the connecting gear, and the connecting gear is fixedly connected with a rotating shaft of the fifth motor;

as the optimization of the invention, the fixed rotating piece comprises a through hole supporting block, a double-mouth buckle plate, a rectangular guide block, a T-shaped rod, a sliding buckle plate and a spring, wherein the through hole supporting block is fixedly connected with one end of a polygonal lifting rod, a bayonet rotating motor is arranged on the through hole supporting block and is connected with the double-mouth buckle plate, the double-mouth buckle plate is provided with a plurality of T-shaped rods, the T-shaped rod is connected with the sliding buckle plate in a penetrating way, the sliding buckle plate is provided with the spring, and one end of the spring is fixedly connected with the expansion end of the T-shaped rod.

As the preference of the invention, the X-axis movable piece comprises a motor support frame, a double-rod support plate, a second guide rod, a first threaded rod, a sixth motor and a lifting sliding block, wherein the motor support frame is fixedly connected to the top end of the equipment carrying box, the motor support frame is provided with the sixth motor, a rotating shaft of the sixth motor penetrates through one end of the motor support frame, which is fixedly connected with the first threaded rod, the other end of the first threaded rod is rotatably connected with the double-rod support plate, the double-rod support plate is fixedly connected with the inner cavity of the equipment carrying box, the second guide rod is arranged between the double-rod support plate and the motor support frame, the middle part of the second guide rod is slidably connected with the lifting sliding block, and the lifting sliding block penetrates through the first threaded rod.

As the preferable choice of the invention, the Y-axis moving part comprises a C-port displacement block, a second threaded rod, a third guide rod, a transverse sliding block and a seventh motor, wherein the middle part of the C-port displacement block is fixedly connected with the lifting sliding block, the third guide rod is connected with the two ends of the C-port displacement block in a penetrating way, the seventh motor is arranged at one end of the C-port displacement block, the rotating shaft of the seventh motor is connected with one end of the second threaded rod in a penetrating way, and the other end of the second threaded rod is connected with the other end of the C-port displacement block far away from the fixed seventh motor in a rotating way.

As a preferable mode of the invention, the Z-axis moving member includes a fourth guide rod, a third threaded rod, a rotating gear, a power gear, an eighth motor and an eighth motor fixing plate, wherein one end of the fourth guide rod is fixedly connected with a transverse slider, one end of the third threaded rod is simultaneously and rotatably connected with the transverse slider, the fourth guide rod is adjacent to the third threaded rod, the third threaded rod is rotatably connected with the rotating gear, the rotating gear is meshed with the power gear, the power gear is fixedly connected with a rotating shaft of the power gear, the eighth motor is provided with the eighth motor fixing plate, and the eighth motor fixing plate is fixedly connected with the transverse slider.

As the preferable mode of the invention, the cutting mechanism further comprises a rectangular groove frame, a rectangular guide groove is arranged in the rectangular groove frame, the sliding rod is placed in the rectangular guide groove, a displacement guide block is arranged in the middle of the rectangular groove frame, a fourth threaded rod is connected in a penetrating mode with the displacement guide block, one end of the fourth threaded rod is fixedly connected with a ninth motor, the ninth motor is fixedly connected with a moving plate, a connecting rod is arranged in the middle of the rectangular groove frame, the connecting rod is fixedly connected with a cable fixing ring, a cable restraining hole is formed in the cable fixing ring, and a cable through hole is formed in the winding frame.

The beneficial effects of the invention are as follows: the invention is used as production equipment for medical high-current inductors, which reduces manual operation content and effectively improves product consistency, and the specific operation mode is that after a cable is placed in an active paying-off machine, the active paying-off machine is started, the cable is sent into a cable restraining hole in a cutting mechanism through a wire resistance wheel and then is led out of a cable through hole, and a framework sleeved on a double-rod cross rotating frame is wound;

during the period, as the cutting mechanism is fixed on the XYZ-axis moving mechanism, the circumferential movement of winding by the cutting mechanism is realized through the X-axis moving part, the Y-axis moving part and the Z-axis moving part, and the specific working modes are as follows: the sixth motor rotates the first threaded rod to enable the lifting slide block to slide along the second guide rod to realize X-axis displacement, the seventh motor rotates the second threaded rod to enable the transverse slide block to slide along the third guide rod to realize Y-axis displacement, the eighth motor rotates the power gear to drive the rotary gear to rotate the third threaded rod, the third threaded rod further pushes the movable plate to slide along the fourth guide rod to realize Z-axis displacement, and spiral circular motion of the cutting mechanism can be realized through mutual cooperation of displacement modes of the X-axis, the Y-axis and the Z-axis, and winding is further realized;

the wire cutting mechanism is characterized in that a wire cutting process exists in the wire winding process, the working mode of the wire cutting mechanism is that a ninth motor is started, a fourth threaded rod is rotated to push a displacement guide block, the displacement guide block drives a rectangular groove frame to move outwards, and further the sliding rod is restrained to fold inwards along the rectangular guide groove;

because the winding modes of the product are different, the skeleton is required to be transposed and rotated during winding, skeleton transposition mechanisms are required to sort and rotate the skeleton, the winding machine is specifically operated, the second motor drives the first sliding wheel to push the bearing plate to move along the top plane of the transposition support frame, the transverse displacement of the fixed rotating part is realized, the third motor rotates the second sliding wheel to drive the axial movement of the first guide rod to realize the longitudinal displacement of the fixed rotating part, the fourth motor rotates the lifting threaded rod to push the polygonal lifting rod to move downwards to realize the lifting of the fixed rotating part, the fifth motor drives the connecting gear to rotate so as to drive the polygonal buckling gear to rotate, the polygonal lifting rod is rotated while the polygonal buckling gear to realize the rotation of the fixed rotating part, after the fixed rotating part descends to the side of the skeleton, the fixed rotating part is close to the skeleton, the double-mouth buckle plate and the sliding buckle plate are pushed by springs on the T-shaped rod, the fixed rotating part can be buckled after the skeleton is pushed by the springs on the T-shaped rod, the transverse displacement part, the longitudinal displacement part and the lifting displacement part can be realized along with the axial movement of the first guide rod to realize the longitudinal displacement of the fixed rotating part, the polygonal lifting part can be matched with the transverse displacement part, the longitudinal displacement part and the lifting part can be matched with the lifting part to move to the two sides of the double-bar cross rotating frame to rotate the skeleton, and the winding wire winding can be changed in the winding process when the winding is required to rotate for a plurality of times.

Through the mode, the framework can be taken, the cables are wound and cut off, the proportion of manual participation in the working process is reduced, the labor intensity is effectively reduced, the uniformity of products is realized, and the working difficulty is reduced.

Drawings

The invention will be described in further detail with reference to the accompanying drawings and detailed description.

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic perspective view of a cross-section of the present invention;

FIG. 3 is a schematic perspective view of a cross-frame mechanism of the present invention;

FIG. 4 is a schematic perspective view of a skeleton transposition mechanism according to the present invention;

FIG. 5 is a second perspective view of the skeleton transposition mechanism of FIG. 4 according to the present invention;

FIG. 6 is a third perspective view of the skeleton transposition mechanism of FIG. 4 according to the present invention;

FIG. 7 is a schematic perspective view of a fourth embodiment of the skeleton transposition mechanism of FIG. 4 according to the present invention;

FIG. 8 is a schematic perspective view of a second perspective view of the skeleton transposition mechanism of FIG. 7 according to the present invention;

FIG. 9 is a schematic perspective view of the XYZ-axis moving mechanism of the present invention;

FIG. 10 is a second perspective view of the XYZ-axis moving mechanism of the present invention;

FIG. 11 is a schematic perspective view of a cutting mechanism of the present invention;

FIG. 12 is a second perspective view of the cutting mechanism of the present invention;

reference numerals: 1. an equipment receiving box; 2. an active paying-off machine; 3. a wire passing resistance wheel; 4. a cross skeleton mechanism; 41. a first motor; 42. a first motor fixing plate; 43. a belt; 44. a rotation shaft fixing plate; 45. a cross-shaped rotating shaft; 46. a double-rod cross rotating frame; 47. a skeleton; 5. a skeleton transposition mechanism; 51. a transposition support frame; 52. a motor fixing plate; 53. a second motor; 54. a first sliding wheel; 55. a limiting plate; 56. a first guide bar; 57. a rectangular sliding groove; 58. a bearing plate; 59. an L-shaped sliding plate; 510. a third motor; 511. a second sliding wheel; 512. rectangular guide blocks; 513. a rectangular connecting frame; 514. a fourth motor; 515. lifting the threaded rod; 516. polygonal lifting rod; 517. polygonal buckling gear; 5171. a connecting gear; 518. a fifth motor; 519. a through hole support block; 520. a double-mouth buckle plate; 521. sliding buckle plates; 522. a T-bar; 523. a spring; 6. an XYZ-axis moving mechanism; 61. a motor support; 62. a double-rod support plate; 63. a second guide bar; 64. a first threaded rod; 65. a sixth motor; 66. a lifting slide block; 67. a C-port displacement block; 68. a second threaded rod; 69. a third guide bar; 610. a transverse slide block; 611. a seventh motor; 612. a fourth guide bar; 613. a third threaded rod; 614. a rotary gear; 615. a power gear; 616. an eighth motor; 617. an eighth motor fixing plate; 7. a cutting mechanism; 71. a moving plate; 72. a bobbin; 73. cutting the rod; 74. rotating the fixing frame; 75. a slide bar; 76. rectangular groove rack; 77. rectangular guide grooves; 78. a displacement guide block; 79. a fourth threaded rod; 710. a ninth motor; 711. a cable through hole; 712. a cable fixing ring; 713. the cable restrains the hole.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the particular embodiments described herein are illustrative only and are not intended to limit the invention, i.e., the embodiments described are merely some, but not all, of the embodiments of the invention. The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be made by a person skilled in the art without making any inventive effort, are intended to be within the scope of the present invention.

The following describes embodiments of the present invention with reference to fig. 1 to 12, a production apparatus for a medical high-current inductor, characterized in that: the device comprises a device carrying box 1, an active paying-off machine 2, a wire passing resistance wheel 3, a cross framework mechanism 4, a framework 47 transposition mechanism, an XYZ shaft moving mechanism and a cutting mechanism 7, wherein the active paying-off machine 2 is arranged on the left side of the device carrying box 1, the wire passing resistance wheel 3 is arranged above the device carrying box 1, the cross framework mechanism 4 is arranged on one side, far away from the active paying-off machine 2, of an inner cavity of the device carrying box 1, the cross framework mechanism 4 comprises a cross rotary shaft 45 and a double-rod cross rotary frame 46 fixed above the cross rotary shaft 45, a framework 47 is sleeved in a long rod arranged on the double-rod cross rotary frame 46, a rotary shaft fixing plate 44 which is in rotary connection is arranged in the middle of the cross rotary shaft 45, the rotary shaft fixing plate 44 is fixedly connected with the device carrying box 1, the framework 47 transposition mechanism is arranged above the cross framework mechanism 4, the framework 47 transposition mechanism comprises a transverse displacement piece, a longitudinal displacement piece and a lifting displacement piece, the lifting displacement piece is arranged on one side of the transverse displacement piece, and a fixed rotary piece is arranged below the lifting displacement piece; an XYZ-axis moving mechanism is arranged below the active paying-off machine 2, the XYZ-axis moving mechanism is far away from the cross framework mechanism 4 and is placed in the inner cavity of the equipment receiving box 1, the XYZ-axis moving mechanism comprises an X-axis moving part, a Y-axis moving part and a Z-axis moving part, the X-axis moving part is provided with a Y-axis moving part which is vertically connected, and the Y-axis moving part is connected with a Z-axis moving part.

Advantageously, referring to fig. 2, a first motor 41 is disposed below the cross-shaped rotation shaft 45, the first motor 41 is fixedly connected with a first motor 41 fixing plate, the first motor 41 fixing plate is fixedly connected to the right side of the inner cavity of the equipment receiving box 1, a belt 43 is disposed on the rotation shaft of the first motor 41, and the belt 43 is simultaneously connected with the cross-shaped rotation shaft 45.

In a specific implementation, the first motor 41 drives the belt 43 to rotate the cross rotating shaft 45, so that the double-rod cross rotating frame 46 can be rotated.

The transverse displacement member comprises a transposition support frame 51, motor fixing plates 52, a second motor 53, a first sliding wheel 54, a limiting plate 55, a first guide rod 56 and a bearing plate 58, wherein the transposition support frame 51 is fixedly connected above two side plates of the equipment receiving box 1, two groups of transposition support frames 51 are arranged, a bearing plate 58 attached to the inner side of the support frame is arranged between the two groups of transposition support frames 51, two groups of motor fixing plates 52 are arranged on two sides of the motor bearing plate 58, the second motor 53 is arranged on the two groups of motor fixing plates 52, a first sliding wheel 54 is fixedly connected with a rotating shaft of the second motor 53, a rolling plane of the first sliding wheel 54 is attached to the top surface of the transposition support frame 51, a limiting plate 55 is simultaneously penetrated through a connecting shaft of the second motor 53, the limiting plate 55 is fixedly connected to two ends of the bearing plate 58, a first guide rod 56 is arranged below the bearing plate 58 between the two groups of limiting plates 55, and a rectangular sliding groove 57 is arranged in the middle of the bearing plate 58; the longitudinal displacement member comprises an L-shaped sliding plate, a third motor 510, a second sliding wheel 511 and a rectangular guide block 512, referring to fig. 5, the rectangular guide block 512 is attached to the upper surface of the bearing plate 58, the short plate of the L-shaped sliding plate is provided with the third motor 510, a rotating rod of the third motor 510 penetrates through the L-shaped sliding plate, the rotating rod of the third motor 510 is fixedly connected with the second sliding wheel 511, the second sliding wheel 511 is positioned below the L-shaped sliding plate and attached to the bearing plate 58, the rectangular guide block 512 is arranged in the middle of the bottom plane of the L-shaped sliding plate, the rectangular guide block 512 is led into the rectangular sliding groove 57, and the bottom of the rectangular guide block 512 is connected with the first guide rod 56 in a sliding manner; referring to fig. 6, the lifting displacement member includes a rectangular connecting frame 513, a fourth motor 514, a lifting threaded rod 515, a polygonal lifting rod 516, a polygonal fastening gear 517, a connecting gear 5171 and a fifth motor 518, wherein the rectangular connecting frame 513 is fixedly connected to the other end of the L-shaped sliding plate far away from the third motor 510, the fourth motor 514 is arranged above the rectangular connecting frame 513, the lifting threaded rod 515 is fixedly connected to the end of the rotating shaft of the fourth motor 514, the lifting threaded rod 515 is led into the center of the long rod of the polygonal lifting rod 516 and is rotatably connected to the polygonal lifting rod 516, the bottom of the polygonal lifting rod 516 penetrates through the L-shaped sliding plate and is rotatably connected to the L-shaped sliding plate, the polygonal fastening gear 517 is slidably connected to the middle of the polygonal lifting rod 516, the polygonal fastening gear 517 is meshed with the connecting gear 5171, and the connecting gear 5171 is fixedly connected to the rotating shaft of the fifth motor 518.

In an actual scheme, the second motor 53 drives the first sliding wheel 54 to push the bearing plate 58 to move along the top plane of the transposition support frame 51, so as to realize the transverse displacement of the fixed rotating member, then the third motor 510 rotates the second sliding wheel 511 to drive the second sliding wheel 511 to move along the axial direction of the first guide rod 56, so as to realize the longitudinal displacement of the fixed rotating member, the fourth motor 514 rotates the lifting threaded rod 515 to push the polygonal lifting rod 516 to move downwards, so as to realize the lifting of the fixed rotating member, the fifth motor 518 drives the connecting gear 5171 to rotate, and then drives the polygonal buckling gear 517 to rotate, and the polygonal lifting rod 516 is rotated to realize the rotation of the fixed rotating member, so that the transposition mechanism of the framework 47 can realize the transposition of the framework 47 on the axial direction.

Advantageously, referring to fig. 7 and 8, the fixed rotator includes a through hole supporting block 519, a double-mouth buckle 520, a rectangular guiding block 512, a t-bar 522, a sliding buckle 521 and a spring 523, the top of the through hole supporting block 519 is fixedly connected to the bottom of the polygonal lifting rod 516, a bayonet rotating motor 524 is arranged on the through hole supporting block 519, the bayonet rotating motor 524 is connected with the double-mouth buckle 520, four groups of t-bars 522 are arranged at the bottom of the double-mouth buckle 520, the t-bars 522 are connected with the sliding buckle 521 in a penetrating manner, the spring 523 is arranged at the bottom of the sliding buckle 521, and one end of the spring 523 is fixedly connected to the bottom of the t-bar 522.

In practice, the framework 47 is fixed by the framework 47 transposition mechanism.

The device comprises an X-axis movable piece, as shown in fig. 9 and 10, and comprises a motor support frame 61, a double-rod support plate 62, a second guide rod 63, a first threaded rod 64, a sixth motor 65 and a lifting slide block 66, wherein the motor support frame 61 is fixedly connected to the top end of the right side of the device receiving box 1, the motor support frame 61 is provided with the sixth motor 65, a rotating shaft of the sixth motor 65 penetrates through one end of the first threaded rod 64 fixedly connected with the motor support frame 61, the other end of the first threaded rod 64 is rotatably connected with the double-rod support plate 62, the double-rod support plate 62 is fixedly connected to the right side of the inner cavity of the device receiving box 1, a second guide rod 63 is arranged between the double-rod support plate 62 and the motor support frame 61, the middle part of the second guide rod 63 is slidably connected with the lifting slide block 66, and the lifting slide block 66 penetrates through the first threaded rod 64; the Y-axis movable piece comprises a C-shaped opening displacement block, a second threaded rod 68, a third guide rod 69, a transverse sliding block 610 and a seventh motor 611, one side, close to the lifting sliding block 66, of the middle part of the C-shaped opening displacement block is fixedly connected with the lifting sliding block 66, the two ends of the C-shaped opening displacement block are connected with the third guide rod 69 in a penetrating manner, one end of the C-shaped opening displacement block is provided with the seventh motor 611, a rotating shaft of the seventh motor 611 penetrates through the C-shaped opening displacement block and is connected with one end of the second threaded rod 68, and the other end of the second threaded rod 68 is connected with the other end of the C-shaped opening displacement block far away from the fixed seventh motor 611 in a rotating manner; the Z-axis moving part comprises a fourth guide rod 612, a third threaded rod 613, a rotary gear 614, a power gear 615, an eighth motor 616 and an eighth motor 616 fixing plate, one end of the fourth guide rod 612 is fixedly connected with the transverse sliding block 610, the transverse sliding block 610 is simultaneously and rotatably connected with one end of the third threaded rod 613, the fourth guide rod 612 is adjacent to the third threaded rod 613, the third threaded rod 613 is rotatably connected with the rotary gear 614, the rotary gear 614 is meshed with the power gear 615, the power gear 615 is fixedly connected with a rotary shaft of the power gear 615, the eighth motor 616 is provided with the eighth motor 616 fixing plate, and the eighth motor 616 fixing plate is fixedly connected with the transverse sliding block 610.

In practice, the circumferential movement of winding by the cutting mechanism 7 is realized by the X-axis moving part, the Y-axis moving part and the Z-axis moving part

Advantageously, referring to fig. 11 and 12, the cutting mechanism 7 further includes a rectangular groove frame 76, a rectangular guide groove 77 is provided in the rectangular groove frame 76, a sliding rod 75 is placed in the rectangular guide groove 77, a displacement guide block 78 is provided in the middle of the rectangular groove frame 76, the displacement guide block 78 is connected with a fourth threaded rod 79 in a penetrating manner, one end of the fourth threaded rod 79 is fixedly connected with a ninth motor 710, the ninth motor 710 is fixedly connected with a moving plate 71, a connecting rod 714 is provided in the middle of the rectangular groove frame 76, a cable fixing ring 712 is fixedly connected with the connecting rod 714, a cable constraint hole 713 is provided on the cable fixing ring 712, and a cable through hole 711 is provided on the winding frame 72.

In a specific operation, the cable can be fixed by the constraint of the cable constraint holes 713 and the cable through holes 711, so that the cutting and the winding of the follow-up reserved wires are facilitated.

The working principle of the invention is as follows: the invention is used as production equipment for medical high-current inductors, which reduces manual operation content and effectively improves product consistency, and the production equipment is specifically operated in the manner that after a cable is placed in an active paying-off machine 2, the active paying-off machine 2 is started, the cable is fed into a cable constraint hole 713 in a cutting mechanism 7 through a wire passing resistance wheel 3 and then is led out of a cable through hole 711, a framework 47 sleeved on a double-rod cross rotating frame 46 is wound, meanwhile, a first motor 41 drives a belt 43 to rotate a cross rotating shaft 45, so that the double-rod cross rotating frame 46 can be rotated, and the addition and winding of different numbers of frameworks 47 can be realized;

during this period, since the cutting mechanism 7 is fixed to the XYZ-axis moving mechanism, the circumferential movement of winding by the cutting mechanism 7 is realized by the provided X-axis moving member, Y-axis moving member, and Z-axis moving member, and the specific operation modes are as follows: the sixth motor 65 rotates the first threaded rod 64 to enable the lifting sliding block 66 to slide along the second guide rod 63 to realize X-axis displacement, the seventh motor 611 rotates the second threaded rod 68 to enable the transverse sliding block 610 to slide along the third guide rod 69 to realize Y-axis displacement, the eighth motor 616 rotates the power gear 615 to drive the rotary gear 614 to rotate the third threaded rod 613, the third threaded rod 613 further pushes the moving plate 71 to slide along the fourth guide rod 612 to realize Z-axis displacement, and spiral circular motion of the cutting mechanism 7 can be realized through mutual cooperation of X-axis displacement, Y-axis displacement and Z-axis displacement modes, so that winding is realized;

because the wire cutting process exists in the wire winding process, the working mode of the cutting mechanism 7 is that the ninth motor 710 is started, the fourth threaded rod 79 is rotated to push the displacement guide block 78, the displacement guide block 78 drives the rectangular groove frame 76 to move outwards, the sliding rod 75 is further restrained to be folded inwards along the rectangular guide groove 77, and one side of the cutting rod 73 is rotationally connected with the rotary fixing frame 74, so that the cutting rod 73 is folded inwards to clamp a wire which penetrates between the wire through hole 711 and the wire restraining hole 713, and further the wire cutting is realized;

because of the difference of the winding modes of the product, the skeleton 47 needs to be transposed and rotated during the winding of the skeleton 47, so that the skeleton 47 is required to be ordered and rotated by a skeleton 47 transposition mechanism, the skeleton 47 transposition mechanism is specifically operated, the second motor 53 drives the first sliding wheel 54 to push the bearing plate 58 to move along the top plane of the transposition support frame 51, the transverse displacement of the fixed rotating member is realized, the third motor 510 rotates the second sliding wheel 511 to drive the movable support frame 56 along the axial direction to realize the longitudinal displacement of the fixed rotating member, the fourth motor 514 rotates the lifting threaded rod 515 to push the polygonal lifting rod 516 to move downwards to realize the lifting of the fixed rotating member, the fifth motor 518 drives the connecting gear 5171 to rotate so as to drive the polygonal buckling gear 517 to rotate, the polygonal lifting rod 516 is rotated to realize the rotation of the fixed rotating member when the polygonal buckling gear 517 rotates, after the fixed rotating member descends to the side of the skeleton 47, the fixed rotating member is close to the skeleton 47, the double-mouth buckling plate 520 and the sliding buckling plate 522 are pushed by the spring 523 to the rear skeleton 47, the movable support frame 47 can finish the longitudinal displacement of the fixed rotating member through the transverse displacement member, the longitudinal displacement member and the lifting member 47 to be separated from the movable support frame 46 to the two sides of the movable support frame 46, and the movable support frame 46 can be matched with the movable support frame 47 in the direction when the two sides of the movable support frame and the movable support frame is changed in the direction, and the longitudinal displacement of the movable support frame is required to change the direction of the movable support frame 47.

Through the working principle, the following operations can be performed:

firstly, after a first framework 47 is led into one single rod of a double-rod cross rotary frame 46, a second framework 47 is led into an adjacent single rod in the same direction, a cable head is manually fixed to one end of the first framework 47 and then wound, an XYZ shaft moving mechanism is closed after winding is completed, an active paying-off machine 2 is continuously started to send wires, a cutting mechanism 7 is started to cut wires after the wire sending length is consistent with the winding length, and a reserved wire is pulled out from a cable through hole 711;

then, manually fixing the cable head to one end of the second framework 47, continuing winding, closing the XYZ shaft moving mechanism after winding is completed, continuing to start the active paying-off machine 2 to send wires, starting the cutting mechanism 7 to cut wires after the wire sending length is consistent with the winding length, pulling out the reserved wires from the cable through holes 711, starting the framework 47 transposition mechanism to separate the second framework 47 from the double-rod cross rotating frame 46, rotating 180 degrees along the axis direction, introducing the single rod of the first framework 47, separating the framework 47 transposition mechanism from the second framework 47, reversely introducing the reserved wires on the first framework 47 into the cable through holes 711, starting the XYZ shaft moving mechanism to wind the reserved wires above the second framework 47 after the reserved wires are completely introduced, and fixing the tail of the reserved wires and the wire heads of the first framework 47 after the reserved wires completely flow out of the cable through holes 711;

then, manually introducing a third framework 47 into a single rod perpendicular to the single rod in which the first framework 47 is placed, introducing a fourth framework 47 into the single rod adjacent to the single rod and leading into the single rod, starting a first motor 41 to drive a double-rod cross rotating frame 46 to rotate 90 degrees, enabling the surface of the third framework 47 to be close to an XYZ shaft moving mechanism, continuously starting an active paying-off machine 2, manually fixing a cable head to one end of the third framework 47, winding, closing the XYZ shaft moving mechanism after winding is completed, continuously starting the active paying-off machine 2 to send wires, starting a cutting mechanism 7 to cut wires after the wire sending length is consistent with the winding length, and pulling out reserved wires from cable through holes 711; the fourth skeleton 47 repeats the above operation, then the skeleton 47 transposition mechanism is started to separate the second skeleton 47 from the double-rod cross rotating frame 46, the second skeleton 47 is rotated 180 degrees along the axial direction, after the single rod of the third skeleton 47 is introduced, the skeleton 47 transposition mechanism is separated from the fourth skeleton 47, the reserved wire on the third skeleton 47 is reversely introduced into the wire through hole 711, after the reserved wire is completely introduced, the XYZ-axis movable mechanism is started to wind the reserved wire above the fourth skeleton 47 until the reserved wire completely flows out of the wire through hole 711, and then the tail of the reserved wire of the third skeleton 47 is fixed with the wire head of the wire wound by the fourth skeleton 47;

then, after the third framework 47 and the fourth framework 47 are separated from the single rods of the double-rod cross rotary frame 46, the framework 47 transposition mechanism is started, the double-rod cross rotary frame 4690 degrees is rotated along the axial direction, the first motor 41 is started to rotate, the second framework 47 surface is close to the XYZ-axis moving mechanism, the framework 47 transposition mechanism is started to lead the third framework 47 and the fourth framework 47 into adjacent and same-direction single rods, the framework 47 transposition mechanism is started to lead the first framework 47 and the second framework 47 to be separated from the single rods of the double-rod cross rotary frame 46, the first framework 47 and the second framework 47 are rotated 180 degrees along the axial direction, the single rods which are adjacent to the third framework 47 and the fourth framework 47 and are same-direction are led into the single rods, the reserved wire on the fourth skeleton 47 is reversely led into the cable through hole 711, the XYZ shaft moving mechanism is started to wind the reserved wire above the first skeleton 47 after the reserved wire is completely led into the cable through hole 711, the tail of the reserved wire is fixed with the wire head of the wire wound on the first skeleton 47, the reserved wire on the second skeleton 47 is reversely led into the cable through hole 711, the XYZ shaft moving mechanism is started to wind the reserved wire above the third skeleton 47 after the reserved wire is completely led into the cable through hole 711, the tail of the reserved wire is fixed with the wire head of the wire wound on the third skeleton 47, and the medical high-current inductor winding is completed.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

The foregoing is merely illustrative of the structures of this invention and various modifications, additions and substitutions for those skilled in the art can be made to the described embodiments without departing from the scope of the invention or from the scope of the invention as defined in the accompanying claims.

Claims (10)

1. A production facility for a medical high current inductor, characterized in that: comprises a device bearing box (1), an active paying-off machine (2), a wire passing resistance wheel (3), a cross framework mechanism (4), a framework (47) transposition mechanism, an XYZ shaft movable mechanism and a cutting mechanism (7), wherein the active paying-off machine (2) is arranged on the side of the device bearing box (1), the wire passing resistance wheel (3) is arranged above the device bearing box (1), the cross framework mechanism (4) is arranged on one side, far away from the active paying-off machine (2), of the inner cavity of the device bearing box (1), the cross framework mechanism (4) comprises a cross rotary shaft (45) and a double-rod cross rotary frame (46) fixed above the cross rotary shaft (45), the framework (47) is sleeved in a long rod arranged in the double-rod cross rotary frame (46), a rotary shaft fixing plate (44) in rotary connection is arranged in the middle of the cross rotary shaft (45), the rotary shaft fixing plate (44) is fixedly connected with the device bearing box (1),

the cross framework mechanism (4) is provided with a framework (47) transposition mechanism above, the framework (47) transposition mechanism comprises a transverse displacement member, a longitudinal displacement member and a lifting displacement member, the transverse displacement member is provided with the longitudinal displacement member, the longitudinal displacement member is provided with the lifting displacement member, and a fixed rotating member is arranged below the lifting displacement member;

an XYZ-axis moving mechanism is arranged below the active paying-off machine (2), the XYZ-axis moving mechanism is far away from the cross framework mechanism (4) and is placed in the inner cavity of the equipment carrying box (1), the XYZ-axis moving mechanism comprises an X-axis moving part, a Y-axis moving part and a Z-axis moving part, the X-axis moving part is provided with a Y-axis moving part, and the Y-axis moving part is provided with a Z-axis moving part;

the utility model discloses a Z axle moving part, including Z axle moving part, Z axle moving part one side be equipped with decide mechanism (7) including movable plate (71) and fixed connection in bobbin (72) of movable plate (71), bobbin (72) inboard is equipped with multiunit and decides pole (73), it is equipped with slide bar (75) to decide pole (73) one end, the other end swivelling joint has rotatory mount (74), rotatory mount (74) fixed connection in bobbin (72).

2. A production facility for a medical high current inductor according to claim 1, characterized in that: the utility model discloses a cross rotation axis (45) of equipment, including cross rotation axis (45) and cross rotation axis (45) of equipment, be equipped with first motor (41) below cross rotation axis (45), first motor (41) fixedly connected with first motor (41) fixed plate, first motor (41) fixed plate fixed connection is in equipment and is accepted case (1) inner chamber, be equipped with belt (43) on the rotation axis of first motor (41), belt (43) are connected with cross rotation axis (45) simultaneously.

3. A production facility for a medical high current inductor according to claim 1, characterized in that: the transverse displacement piece comprises a transposition support frame (51), a motor fixing plate (52), a second motor (53), a first sliding wheel (54), a limiting plate (55), a first guide rod (56) and a bearing plate (58), wherein the transposition support frame (51) is fixedly connected to the upper portion of the equipment carrying box (1), the transposition support frame (51) is provided with two groups, the bearing plate (58) is arranged between the two groups of transposition support frames (51), the motor fixing plate (58) is provided with two groups of motor fixing plates (52), the motor fixing plate (52) is provided with the second motor (53), the second motor (53) is fixedly connected with the first sliding wheel (54), the first sliding wheel (54) is attached to the top end plane of the transposition support frame (51), the limiting plate (55) is penetrated through by a connecting shaft of the second motor (53), the limiting plate (55) is fixedly connected to the bearing plate (58), the first guide rod (56) is arranged between the two groups of limiting plates (55), and a rectangular sliding groove (57) is formed in the middle of the bearing plate (58).

4. A production facility for a medical high current inductor according to claim 1, characterized in that: the vertical displacement piece includes L type sliding plate, third motor (510), second movable pulley (511) and rectangle guide block (512), rectangle guide block (512) laminating is in bearing plate (58) surface, L type sliding plate fixedly connected with third motor (510), the rotary rod of third motor (510) runs through L type sliding plate, rotary rod fixedly connected with second movable pulley (511) of third motor (510), second movable pulley (511) laminating is in bearing plate (58), L type sliding plate is equipped with rectangle guide block (512), rectangle guide block (512) lets in rectangle sliding tray (57), rectangle guide block (512) sliding connection is in first guide bar (56).

5. A production facility for a medical high current inductor according to claim 1, characterized in that: the lifting displacement piece comprises a rectangular connecting frame (513), a fourth motor (514), a lifting threaded rod (515), a polygonal lifting rod (516), a polygonal buckling gear (517), a connecting gear (5171) and a fifth motor (518), wherein the rectangular connecting frame (513) is fixedly connected to an L-shaped sliding plate, the rectangular connecting frame (513) is provided with the fourth motor (514), a lifting threaded rod (515) is fixedly connected to a rotating shaft of the fourth motor (514), the lifting threaded rod (515) is led into a long rod of the polygonal lifting rod (516) and is rotatably connected to the polygonal lifting rod (516), the polygonal lifting rod (516) penetrates through the L-shaped sliding plate and is rotatably connected to the L-shaped sliding plate, the polygonal buckling gear (517) is in meshed connection with the connecting gear (5171), and the connecting gear (5171) is fixedly connected to a rotating shaft of the fifth motor (518).

6. A production facility for a medical high current inductor according to claim 1, characterized in that: the fixed rotating member comprises a through hole supporting block (519), a double-opening buckle plate (520), a rectangular guide block (512), a T-shaped rod (522), a sliding buckle plate (521) and a spring (523), wherein the through hole supporting block (519) is fixedly connected to one end of the polygonal lifting rod (516), a bayonet rotating motor (524) is arranged on the through hole supporting block (519), the bayonet rotating motor (524) is connected with the double-opening buckle plate (520), the double-opening buckle plate (520) is provided with a plurality of T-shaped rods (522), the T-shaped rods (522) are connected with the sliding buckle plate (521) in a penetrating manner, the sliding buckle plate (521) is provided with the spring (523), and one end of the spring (523) is fixedly connected to the expansion end of the T-shaped rod (522).

7. A production facility for a medical high current inductor according to claim 1, characterized in that: the X-axis movable part comprises a motor support frame (61), a double-rod support plate (62), a second guide rod (63), a first threaded rod (64), a sixth motor (65) and a lifting slide block (66), wherein the motor support frame (61) is fixedly connected to the top end of the equipment carrying box (1), the motor support frame (61) is provided with the sixth motor (65), a rotating shaft of the sixth motor (65) penetrates through one end of the motor support frame (61) fixedly connected with the first threaded rod (64), the other end of the first threaded rod (64) is rotatably connected with the double-rod support plate (62), the double-rod support plate (62) is fixedly connected to the inner cavity of the equipment carrying box (1), the second guide rod (63) is arranged between the double-rod support plate (62) and the motor support frame (61), the lifting slide block (66) is slidably connected to the middle part of the second guide rod (63), and the lifting slide block (66) penetrates through and is connected with the first threaded rod (64).

8. A production facility for a medical high current inductor according to claim 1, characterized in that: the Y-axis movable piece comprises a C-port displacement block, a second threaded rod (68), a third guide rod (69), a transverse sliding block (610) and a seventh motor (611), wherein the middle part of the C-port displacement block is fixedly connected with a lifting sliding block (66), the two ends of the C-port displacement block are connected with the third guide rod (69) in a penetrating manner, one end of the C-port displacement block is provided with the seventh motor (611), a rotating shaft of the seventh motor (611) penetrates through the C-port displacement block and is connected with one end of the second threaded rod (68), and the other end of the second threaded rod (68) is connected with the other end of the C-port displacement block far away from the fixed seventh motor (611) in a rotating manner.

9. A production facility for a medical high current inductor according to claim 1, characterized in that: the Z-axis movable piece comprises a fourth guide rod (612), a third threaded rod (613), a rotary gear (614), a power gear (615), an eighth motor (616) and an eighth motor (616) fixing plate, one end of the fourth guide rod (612) is fixedly connected with a transverse sliding block (610), one end of the transverse sliding block (610) is simultaneously and rotatably connected with the third threaded rod (613), the fourth guide rod (612) is adjacent to the third threaded rod (613), the third threaded rod (613) is rotatably connected with the rotary gear (614), the rotary gear (614) is meshed with the power gear (615), the power gear (615) is fixedly connected with a rotary shaft of the power gear (615), the eighth motor (616) is provided with an eighth motor (616) fixing plate, and the eighth motor (616) fixing plate is fixedly connected with the transverse sliding block (610).

10. A production facility for a medical high current inductor according to claim 1, characterized in that: cutting mechanism (7) still include rectangular channel frame (76), be equipped with rectangle guide way (77) in rectangle channel frame (76), slide bar (75) are placed in rectangle guide way (77), rectangle channel frame (76) middle part is equipped with displacement guide block (78), displacement guide block (78) through-connection has fourth threaded rod (79), the one end fixed connection of fourth threaded rod (79) is in ninth motor (710), ninth motor (710) fixed connection is in movable plate (71), rectangle channel frame (76) middle part is equipped with connecting rod (714), connecting rod (714) fixedly connected with cable retainer plate (712), be equipped with cable restriction hole (713) on cable retainer plate (712), reel (72) are equipped with cable through-hole (711).