CN114669690A

CN114669690A - Calculating device for winding wire diameter of brushless motor

Info

Publication number: CN114669690A
Application number: CN202210204240.8A
Authority: CN
Inventors: 徐有询
Original assignee: Sangu Technology Dongguan Co ltd
Current assignee: Sangu Technology Dongguan Co ltd
Priority date: 2022-03-03
Filing date: 2022-03-03
Publication date: 2022-06-28
Anticipated expiration: 2042-03-03
Also published as: CN114669690B

Abstract

The invention relates to the technical field of motors and discloses a calculating device of the winding wire diameter of a brushless motor, which comprises a bottom plate and a side plate, wherein the top of the bottom plate is fixedly connected with a limiting block, the limiting block is hinged with a coil, the size of the limiting block is matched with the distance between the coil and the point, one side of the limiting block is provided with the coil, the outer side of the coil is provided with a groove of which the size is matched with that of the metal wire, the outer side of the coil is provided with the metal wire, the outer side of one end, close to the coil, of the metal wire is provided with a limiting block, the inside of the limiting block is provided with a through hole, the size of the through hole is matched with that of the metal wire, and one side of the limiting block is fixedly connected with a first wedge block; according to the device for calculating the wire diameter of the winding of the brushless motor, one end of a metal wire wound on a coil passes through the limiting block, then passes through the through holes formed in the roller and the positioning block, passes through the groove formed in the outer surface of the steering wheel, and finally is placed in the clamping block, and at the moment, the motor is started by an operator, so that the rotating gear starts to rotate.

Description

Calculating device for winding wire diameter of brushless motor

Technical Field

The invention relates to the technical field of motors, in particular to a device for calculating the wire diameter of a winding of a brushless motor.

Background

The stator in a brushless motor is a winding coil, the winding of which is essentially entirely operated using mechanical equipment, before the wire is wound into the stator, however, the operator needs to straighten the wire in a bent state, and then wind it around the stator by a mechanical device, because the wire may be left in an outdoor environment for a period of time before use, a long period of time may cause some dust to accumulate on the outer surface of the wire, these impurities, if left untreated before the winding of the coil, may have an effect on the use of subsequent equipment, and also require the insulation paper cut to a certain size to be manually inserted between the slits of the stator before the winding of the winding coil, which is a complicated process, and requires careful handling by the operator due to the size of the insulation paper, which is too time consuming and cumbersome.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a device for calculating the wire diameter of a winding of a brushless motor, which has the advantages of straightening a metal wire in a winding state or a bending state, measuring the wire diameter of the metal wire, cleaning dust generated on the outer surface of the metal wire placed for a long time and conveniently loading insulating paper, and solves the problems that the metal wire in the winding state or the bending state cannot be directly used, the wire diameter of the metal wire is unknown, the number of winding turns of a winding coil cannot be calculated, and the outer surface of the metal wire possibly has dust and the insulating paper is inconvenient to install due to long-time placement.

(II) technical scheme

In order to achieve the above-mentioned purpose of straightening the metal wire in a winding state or a bending state, measuring the wire diameter of the metal wire, cleaning dust generated on the outer surface of the metal wire which is placed for a long time and conveniently loading the dust into the insulating paper, the invention provides the following technical scheme: a calculating device for the winding wire diameter of a brushless motor comprises a bottom plate and a side plate, wherein a limiting block is fixedly connected to the top of the bottom plate, the limiting block is hinged to a coil, the size of the limiting block is matched with the distance between the coil and the point, a coil is arranged on one side of the limiting block, a groove matched with the metal wire in size is formed in the outer side of the coil, a metal wire is arranged on the outer side of the coil, a limiting block is arranged on the outer side of the metal wire, which is close to one end of the coil, a through hole is formed in the limiting block, the size of the through hole is matched with the metal wire, a first wedge block is fixedly connected to one side of the limiting block, a roller is hinged to the top of the first wedge block, the size of the roller is matched with that of a rotating block, a supporting piece is sleeved on the outer side of the first wedge block, the number of the supporting pieces is two, the two supporting pieces are respectively hinged to the first wedge block and the second wedge block, a through hole is formed in the top end of the supporting piece, the size of the through hole is matched with that of the first wedge block and the second wedge block, the size of the supporting piece is matched with the distance between the first wedge block and the bottom plate, the second wedge block is arranged inside the other supporting piece, the size of the second wedge block is the same as that of the first wedge block, the first wedge block and the second wedge block are in axial symmetry distribution by taking the limiting block as a symmetry axis, the inner side of the top end of the metal wire is provided with a steering wheel, the outer side of the steering wheel is provided with a groove of which the size is matched with that of the metal wire, the outer side of one end, away from the coil, of the metal wire is provided with a clamping block, the inside of the clamping block is provided with a clamp, the inside of the clamping block is provided with a through hole of which the size is matched with that of the metal wire, the top of the bottom plate is provided with a laser measuring instrument, the top of the second wedge block is provided with a rotating block which is composed of two cylinders of which the same sizes are respectively positioned right above the first wedge block and the second wedge block, one side of the rotating block is fixedly connected with a rotating gear which is meshed with a transmission gear, one side of the side plate is provided with the transmission gear, two sides of the transmission gear are respectively meshed with the rotating gear and a driven gear, the top of the transmission gear is engaged with a driven gear, the outer side of the driven gear is engaged with the transmission gear, one side of the driven gear close to the side plate is hinged with the connecting rod, a connecting rod is arranged on one side of the driven gear close to the side plate, two ends of the connecting rod are respectively hinged with the driven gear and the driven piece, the size of the connecting rod is matched with the distance between the driven gear and the driven piece, one end of the connecting rod, which is far away from the driven gear, is hinged with a driven piece, one side of the driven piece, which is close to the side plate, is hinged with the connecting rod, one side of the driven part far away from the connecting rod is provided with two rotating parts, the two rotating parts are connected with the driven gear respectively, and the size of each rotating part is matched with the chain.

Preferably, the outside of rotating the piece is provided with the chain, and the chain size is rotated the piece phase-match with two, one side that the follower was kept away from to the chain is provided with the fixture block, and the recess phase-match that fixture block size and cylinder surface were seted up, one side that the fixture block was back to the follower is provided with the cylinder, and size and wire assorted through-hole are seted up to cylinder inside, and size and fixture block assorted recess are seted up to the surface, and the recess phase-match that the cylinder bottom size and locating piece top were seted up.

Preferably, the bottom of the roller is provided with a coil spring, the coil spring is positioned in a groove formed in the top of the positioning block, the size of the coil spring is matched with that of the groove formed in the bottom of the roller and the top of the positioning block, the positioning block is arranged on the outer side of the coil spring, the top of the positioning block is provided with a groove, and the size of the groove is matched with that of the roller and the coil spring.

Preferably, the inner side of the top of the fixing part is provided with a rotating wheel, the size of the rotating wheel is matched with a groove formed in the top end of the fixing part, one side of the rotating wheel is fixedly connected with an expansion piece, and the size of the expansion piece is matched with the distance between the rotating wheel and the embedded piece.

Preferably, the other side of the telescopic piece is fixedly connected with an embedded piece, and the size of the embedded piece is matched with a through hole formed in the stator.

Preferably, the top of bottom plate fixedly connected with two opposite branches, two opposite branch's opposite face is provided with two relative telescopic links, and the telescopic link size and branch are to the distance phase-match between the extruded piece.

Preferably, two opposite extrusion parts are arranged on opposite sides of the two opposite telescopic rods, and the sizes of the extrusion parts are matched with those of the stators.

Preferably, the opposite sides of the two said extrusions which face each other are provided with stators.

Preferably, one side of the stator is provided with a stop block, and the size of the stop block is slightly larger than that of the embedded part and smaller than that of a through hole formed in the stator.

(III) advantageous effects

Compared with the prior art, the invention provides a device for calculating the wire diameter of a winding of a brushless motor, which has the following beneficial effects:

1. the device for calculating the winding wire diameter of the brushless motor is characterized in that an operator enables one end of a metal wire wound on a coil to pass through a through hole formed in a roller and a positioning block through the inside of a limiting block and then pass through a groove formed in the outer surface of a steering wheel and finally place the metal wire into a clamping block, the operator starts a motor at the moment to enable a rotary gear to start rotating, the rotary gear is fixedly connected with a rotary block, the rotary block is located right above a wedge block I and a wedge block II, the size of the rotary block is matched with that of the wedge block I and the wedge block II, the wedge block I and the wedge block II are respectively hinged with a supporting piece, when the rotary block rotates, the wedge block I and the wedge block II are driven by the rotary block to do periodic motion by taking a hinged point with the supporting piece as a fulcrum, and due to the angle setting of the wedge block I and the wedge block II, when the wedge block I is located at the top end, the wedge block II is located at the bottom end, and is fixedly connected with the clamping block II, therefore, the clamping block moves along with the second wedge block, when the second wedge block moves downwards from the highest position under the drive of the rotating block, the clamping block moves from the topmost end to the bottommost end, in the moving process, the clamping block clamps the metal wire in the clamping block, so that the metal wire wound on the coil is pulled out, when the second wedge block and the clamping block move from the bottommost end to the topmost end under the drive of the rotating block, the clamping block loosens the metal wire, the metal wire wound outside the coil is pulled out and matched with the steering wheel to straighten the metal wire in a bending state, the straightened metal wire extends out from the bottom of the clamping block, the diameter of the metal wire is measured by the laser measuring instrument, and the purposes of straightening the metal wire in the bending state and measuring the diameter of the metal wire are achieved.

2. The device for calculating the winding wire diameter of the brushless motor starts the motor through an operator, so that the rotating gear starts to rotate, because the rotating gear is meshed with the transmission gear which is meshed with the driven gear, the rotating gear can drive the transmission gear and the driven gear to start to rotate, so that one rotating part fixedly connected with the driven gear is driven to start to rotate, because one side, close to the side plate, of the driven gear is connected with the driven part through the connecting rod, two ends of the connecting rod are hinged with the driven gear and the driven part, one side, far away from the side plate, of the driven part is fixedly connected with the other rotating part, so that the driven gear can be driven by the connecting rod to synchronously rotate the driven part, so that the other rotating part fixedly connected with the driven part is driven to start to move, because the size of the chain is matched with the two rotating parts, one side, close to the roller, of the chain is fixedly connected with a clamping block, the size of the clamping block is matched with the groove arranged on the outer surface of the roller, so the chain can start to move under the drive of the two rotating blocks to drive the clamping block to move, so that the clamping block moves periodically according to the movement track of the chain, the clamping block moves along the groove formed on the outer surface of the roller at the same time, thereby driving the roller to start rotating, at the moment, the coil spring connected with the bottom of the roller is in an extending state, when the roller rotates for a circle under the drive of the clamping block, the clamping block is not contacted with the groove on the outer surface of the roller, the roller in the state is driven by the retracted coil spring to rotate reversely to recover the initial motion, when the clamping block moves to the initial position under the driving of the chain, the clamping block is connected with the roller again to reciprocate circularly, and then under the matching of the clamping block, the clamping block cleans dust passing through the outer surface of the metal wire in the roller, thereby achieving the purpose of cleaning dust on the outer surface of the metal wire caused by long-time placement.

3. The device for calculating the wire diameter of the brushless motor winding is characterized in that an operator puts cut insulating paper on the embedded part, the telescopic part is started at the moment to enable the embedded part to move towards the direction of the stator, because the size of the extrusion part is matched with that of the stator, the extrusion part can clamp the stator under the action of the telescopic rod, because the size of the embedded part is matched with that of the through hole formed in the stator, therefore, when the embedded part passes through one side of the stator under the driving of the telescopic part, the insulating paper placed on the outer surface of the embedded part enters the inside of the stator along with the embedded part, because the side of the stator far away from the embedded part is provided with the baffle block, the size of the through hole arranged in the baffle block is slightly larger than that of the embedded part, therefore, when the embedded part passes through the stator through the inside of the stator, the insulating paper on the outer surface of the embedded part is left in the stator under the action of the stop block, and the purpose of conveniently inserting the insulating paper in the stator is achieved.

Drawings

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

FIG. 2 is a schematic front view of the overall structure of the present invention;

FIG. 3 is a schematic view of the cleaning and straightening mechanism of the present invention;

FIG. 4 is a detailed view of the back of the cleaning and straightening mechanism of the present invention;

FIG. 5 is a schematic front view of the cleaning and straightening mechanism of the present invention;

FIG. 6 is a schematic detail view of the cleaning mechanism of the present invention;

FIG. 7 is an exploded view of the structure at the drum of the present invention;

FIG. 8 is a schematic cross-sectional view of the drum of the present invention;

FIG. 9 is a schematic view of the mechanism for mounting insulation paper according to the present invention;

FIG. 10 is a schematic view of the back side of the mechanism for mounting insulation paper according to the present invention.

In the figure: 101. a base plate; 102. a limiting block; 103. a coil; 104. a metal wire; 105. a limiting block; 106. a first wedge block; 107. a support member; 108. a second wedge block; 109. a steering wheel; 110. a clamping block; 111. a laser measuring instrument; 112. rotating the block; 113. a rotating gear; 201. a side plate; 202. a transmission gear; 203. a driven gear; 204. a connecting rod; 205. a driven member; 206. a rotating member; 207. a chain; 208. a clamping block; 209. a drum; 210. a coil spring; 211. positioning blocks; 301. a fixing member; 302. a rotating wheel; 303. a telescoping member; 304. an insert; 305. a strut; 306. a telescopic rod; 307. an extrusion; 308. a stator; 309. and a stop block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

Referring to fig. 1 to 4, a device for calculating the winding wire diameter of a brushless motor includes a bottom plate 101, where the bottom plate 101 defines positions of structures such as a side plate 201, a defining block 102, and a supporting member 107; the top of the bottom plate 101 is fixedly connected with a limiting block 102, the limiting block 102 is hinged with the coil 103, the size of the limiting block 102 is matched with the distance from the coil 103 to a point, and the limiting block 102 limits the position of the coil 103; a coil 103 is arranged on one side of the limiting block 102, a groove matched with the metal wire 104 in size is formed in the outer side of the coil 103, and the coil 103 fixes the metal wire 104 which is initially in a bending state;

the outer side of the coil 103 is provided with a metal wire 104, and the metal wire 104 is processed and then wound on the stator 308 to form a winding coil 103; a limiting block 105 is arranged on the outer side of one end, close to the coil 103, of the metal wire 104, a through hole is formed in the limiting block 105, the size of the through hole is matched with that of the metal wire 104, the limiting block 105 limits the initial position of the metal wire 104, and the metal wire moves under the driving of a first wedge 106 to slightly clean the outer surface of the metal wire 104;

one side of the limiting block 105 is fixedly connected with a first wedge block 106, the top of the first wedge block 106 is hinged with a roller, the size of the roller is matched with that of the rotating block 112, the first wedge block 106 limits the position of the limiting block 105, and meanwhile, the first wedge block 106 starts to move under the driving of the rotating block 112, so that the position of the limiting block 105 is driven to change;

The outer side of one end, away from the limiting block 105, of the first wedge block 106 is sleeved with a supporting piece 107, the number of the supporting pieces 107 is two, the two supporting pieces 107 are hinged with the first wedge block 106 and the second wedge block 108 respectively, a through hole is formed in the top end of the supporting piece 107, the size of the through hole is matched with that of the first wedge block 106 and the second wedge block 108, the size of the supporting piece 107 is matched with the distance between the first wedge block 106 and the bottom plate 101, the second wedge block 108 is arranged in the other supporting piece 107, the size of the first wedge block 108 is the same as that of the first wedge block 106, the first wedge block 106 and the second wedge block 108 are axially symmetrically distributed by taking the limiting block 102 as a symmetry axis, and the supporting pieces 107 limit the positions of the first wedge block 106 and the second wedge block 108 and are also supporting points for movement of the first wedge block 106 and the second wedge block 108;

a steering wheel 109 is arranged on the inner side of the top end of the metal wire 104, a groove matched with the metal wire 104 in size is formed in the outer side of the steering wheel 109, the steering wheel 109 changes the direction of the metal wire 104, the position of the metal wire 104 is limited, and the steering wheel is matched with the clamping block 110 to straighten the metal wire 104; a clamping block 110 is arranged on the outer side of one end, away from the coil 103, of the metal wire 104, a clamp is arranged inside the clamping block 110, a through hole matched with the metal wire 104 in size is formed in the clamping block 110, the clamping block 110 is driven by a wedge block II 108 to move towards the topmost end from the bottommost end and towards the bottommost end from the topmost end ceaselessly, the metal wire 104 can be clamped when the clamping block 110 moves towards the bottommost end from the topmost end, otherwise, the metal wire 104 can be loosened and cyclically reciprocated, the metal wire 104 is pulled out of the coil 103, and meanwhile, the metal wire 104 in a bending state is straightened by being matched with other structures;

The top of the bottom plate 101 is provided with a laser measuring instrument 111, and the laser measuring instrument 111 measures the line diameter of the straightened metal wire 104; the top of the wedge block II 108 is provided with a rotating block 112, the rotating block 112 is composed of two cylinders with the same size, the two cylinders are respectively positioned right above the wedge block I106 and the wedge block II 108, the size of the rotating block 112 is matched with that of the wedge block I106 and the wedge block II 108, and the rotating block 112 starts to rotate under the drive of a rotating gear 113, so that the positions of the wedge block I106 and the wedge block II 108 are changed; one side of the rotating block 112 is fixedly connected with a rotating gear 113, the rotating gear 113 is meshed with the transmission gear 202, and the rotating gear 113 rotates to drive the rotating block 112 and the transmission gear 202 to rotate.

Example two

Referring to fig. 5 to 8, a device for calculating the winding wire diameter of a brushless motor includes a side plate 201, where the side plate 201 defines the positions of a rotating gear 113 and a transmission gear 202; a transmission gear 202 is arranged on one side of the side plate 201, two sides of the transmission gear 202 are respectively meshed with the rotating gear 113 and the driven gear 203, and the transmission gear 202 is driven by the rotating gear 113 to start rotating, so that the driven gear 203 is driven to start moving;

the top of the transmission gear 202 is engaged with a driven gear 203, the outer side of the driven gear 203 is engaged with the transmission gear 202, one side of the driven gear 203 close to the side plate 201 is hinged with a connecting rod 204, the driven gear 203 is driven by the transmission gear 202 to start moving, so as to drive one of the rotating parts 206 fixedly connected with the driven gear 203 to start rotating, and then the connecting rod 204 drives the driven part 205 to start rotating; a connecting rod 204 is arranged on one side of the driven gear 203 close to the side plate 201, two ends of the connecting rod 204 are respectively hinged with the driven gear 203 and the driven part 205, the size of the connecting rod 204 is matched with the distance between the driven gear 203 and the driven part 205, the connecting rod 204 is connected with the driven gear 203 and the driven part 205, and the connecting rod starts to move under the driving of the driven gear 203, so that the driven part 205 is driven to start to rotate;

One end of the connecting rod 204, which is far away from the driven gear 203, is hinged with a driven part 205, one side of the driven part 205, which is close to the side plate 201, is hinged with the connecting rod 204, and the driven part 205 starts to rotate under the action of the connecting rod 204, so as to drive another rotating part 206 fixedly connected with the connecting rod to start to move; the side, away from the connecting rod 204, of the driven part 205 is provided with two rotating parts 206, the two rotating parts 206 are connected to the driven part 205 and the driven gear 203 respectively, the size of the rotating part 206 is matched with that of the chain 207, and the two rotating parts 206 start to rotate under the driving of the driven gear 203 and the driven part 205, so as to drive the chain 207 to move;

a chain 207 is arranged on the outer side of the rotating part 206, the size of the chain 207 is matched with that of the two rotating parts 206, and the chain 207 is driven by the rotating part 206 to start to move, so that a clamping block 208 fixedly connected with the chain is driven to move; a fixture block 208 is arranged on one side of the chain 207, which is far away from the driven piece 205, the size of the fixture block 208 is matched with a groove formed in the outer surface of the roller 209, the fixture block 208 is driven by the chain 207 to start moving, and when the movement is started according to the movement track of the chain 207, the roller 209 is driven to start rotating;

a roller 209 is arranged on one side of the clamping block 208, which is opposite to the driven part 205, a through hole with the size matched with the metal wire 104 is arranged in the roller 209, a groove with the size matched with the clamping block 208 is arranged on the outer surface of the roller 209, the size of the bottom of the roller 209 is matched with the groove arranged on the top of the positioning block 211, the roller 209 starts to move under the driving of the clamping block 208, so that a coil spring 210 at the bottom of the roller 209 is in an extending state, when the roller 209 is not acted by the clamping block 208, the coil spring 210 retracts, the roller 209 is restored to the initial position, and meanwhile, the roller 209 in the rotating state can clean the outer surface of the metal wire 104 inside;

The bottom of the roller 209 is provided with a coil spring 210, the coil spring 210 is positioned in a groove formed in the top of the positioning block 211, the size of the coil spring 210 is matched with that of the grooves formed in the bottom of the roller 209 and the top of the positioning block 211, the coil spring 210 starts to extend outwards under the driving of the roller 209, and when the roller 209 is not acted by the clamping block 208, the coil spring 210 starts to retract, so that the roller 209 returns to the initial position; the outer side of the coil spring 210 is provided with a positioning block 211, the top of the positioning block 211 is provided with a groove, the size of the groove is matched with that of the roller 209 and the coil spring 210, and the positioning block 211 limits the positions of the coil spring 210 and the roller 209.

EXAMPLE III

Referring to fig. 9 to 10, a device for calculating the winding wire diameter of a brushless motor includes a fixing member 301, a groove having a size matching that of a rotating wheel 302 is formed at the top of the fixing member 301, and the fixing member 301 defines the position of the rotating wheel 302; the inner side of the top of the fixing member 301 is provided with a rotating wheel 302, the size of the rotating wheel 302 is matched with a groove formed in the top end of the fixing member 301, the rotating wheel 302 limits the positions of the telescopic member 303 and the embedded member 304, and meanwhile, the position of the embedded member 304 can be adjusted by rotating the rotating wheel 302, so that an operator can conveniently place insulating paper on the embedded member 304;

one side of the rotating wheel 302 is fixedly connected with a telescopic part 303, the size of the telescopic part 303 is matched with the distance between the rotating wheel 302 and the embedded part 304, the telescopic part 303 drives the embedded part 304 to move, and the telescopic part 303 extends outwards to enable the embedded part 304 to move towards the direction of the stator 308; the other side of the telescopic member 303 is fixedly connected with an embedded member 304, the size of the embedded member 304 is matched with a through hole formed in the stator 308, cut insulating paper can be placed on the outer surface of the embedded member 304 and can move towards the stator 308 under the driving of the telescopic member 303, and therefore the insulating paper attached to the outer surface of the embedded member 304 is placed in the stator 308;

The top of the bottom plate 101 is fixedly connected with two opposite support rods 305, and the support rods 305 define the position of the telescopic rod 306 and provide support for the telescopic rod 306; two opposite telescopic rods 306 are arranged on the opposite surfaces of the two opposite support rods 305, the size of each telescopic rod 306 is matched with the distance between each support rod 305 and the corresponding extrusion part 307, and the telescopic rods 306 move oppositely to drive the extrusion parts 307 to start to move;

two opposite extrusion parts 307 are arranged on opposite sides of the two opposite telescopic rods 306, the size of each extrusion part 307 is matched with that of the stator 308, and the extrusion parts 307 fix the position of the stator 308; stators 308 are provided on opposite sides of the two opposing pressing members 307, the stators 308 cooperating with the inserts 304 to feed the cut insulating paper placed on the surface of the inserts 304 into the stators 308; a stop 309 is arranged on one side of the stator 308, the size of the stop 309 is slightly larger than that of the insert 304 and smaller than that of a through hole formed in the stator 308, and when the insert 304 is driven by the telescopic member 303 to pass through one side of the stator 308 and pass out of the other side, the insulating paper is prevented from being brought out of the stator 308 by the insert 304.

Example four

Referring to fig. 1 to 10, a device for calculating the winding wire diameter of a brushless motor includes a bottom plate 101, where the bottom plate 101 defines positions of structures such as a side plate 201, a defining block 102, and a supporting member 107; the top of the bottom plate 101 is fixedly connected with a limiting block 102, the limiting block 102 is hinged with the coil 103, the size of the limiting block 102 is matched with the distance from the coil 103 to a point, and the limiting block 102 limits the position of the coil 103; a coil 103 is arranged on one side of the limiting block 102, a groove matched with the metal wire 104 in size is formed in the outer side of the coil 103, and the metal wire 104 in an initial bending state is fixed by the coil 103;

The outer side of the coil 103 is provided with a metal wire 104, and the metal wire 104 is processed and then wound on the stator 308 to form a winding coil 103; a limiting block 105 is arranged on the outer side of one end, close to the coil 103, of the metal wire 104, a through hole is formed in the limiting block 105, the size of the through hole is matched with that of the metal wire 104, the limiting block 105 limits the initial position of the metal wire 104, and meanwhile, the limiting block is driven by the first wedge 106 to move, so that the outer surface of the metal wire 104 is slightly cleaned;

one side of the limiting block 105 is fixedly connected with a first wedge 106, the top of the first wedge 106 is hinged with a roller, the size of the roller is matched with that of the rotating block 112, the first wedge 106 limits the position of the limiting block 105, and meanwhile, the first wedge 106 starts to move under the driving of the rotating block 112, so that the position of the limiting block 105 is driven to change;

A steering wheel 109 is arranged on the inner side of the top end of the metal wire 104, a groove matched with the metal wire 104 in size is formed in the outer side of the steering wheel 109, the steering wheel 109 changes the direction of the metal wire 104, the position of the metal wire 104 is limited, and the steering wheel is matched with the clamping block 110 to straighten the metal wire 104; a clamping block 110 is arranged on the outer side of one end, away from the coil 103, of the metal wire 104, a clamp is arranged inside the clamping block 110, a through hole matched with the metal wire 104 in size is formed in the clamping block 110, the clamping block 110 is driven by a second wedge 108 to continuously move from the bottommost end to the topmost end and from the topmost end to the bottommost end, when the clamping block 110 moves from the topmost end to the bottommost end, the metal wire 104 can be clamped, otherwise, the metal wire 104 is loosened and cyclically reciprocated, the metal wire 104 is pulled out of the coil 103, and meanwhile, the metal wire 104 in a bent state is straightened by being matched with other structures;

The device comprises a side plate 201, wherein the side plate 201 defines the positions of structures such as a rotating gear 113, a transmission gear 202 and the like; a transmission gear 202 is arranged on one side of the side plate 201, two sides of the transmission gear 202 are respectively meshed with the rotating gear 113 and the driven gear 203, and the transmission gear 202 starts to rotate under the driving of the rotating gear 113, so that the driven gear 203 is driven to start to move;

one end of the connecting rod 204, which is far away from the driven gear 203, is hinged with a driven part 205, one side of the driven part 205, which is close to the sideboard 201, is hinged with the connecting rod 204, and the driven part 205 starts to rotate under the action of the connecting rod 204, so as to drive another rotating part 206 fixedly connected with the driven part to start to move; the driven part 205 is provided with two rotating parts 206 on one side away from the connecting rod 204, the two rotating parts 206 are respectively connected with the driven part 205 and the driven gear 203, the size of the rotating part 206 is matched with that of the chain 207, and the two rotating parts 206 start to rotate under the drive of the driven gear 203 and the driven part 205, so as to drive the chain 207 to move;

a roller 209 is arranged on one side of the clamping block 208, which is opposite to the driven piece 205, a through hole with the size matched with the metal wire 104 is arranged in the roller 209, a groove with the size matched with the clamping block 208 is arranged on the outer surface of the roller 209, the size of the bottom of the roller 209 is matched with the size of the groove arranged at the top of the positioning block 211, the roller 209 starts to move under the driving of the clamping block 208, so that a coil spring 210 at the bottom of the roller 209 is in an extension state, when the roller 209 is not acted by the clamping block 208, the coil spring 210 retracts, the roller 209 is enabled to recover to the initial position, and meanwhile, the roller 209 in the rotation state can clean the outer surface of the metal wire 104 inside;

The device comprises a fixing piece 301, wherein the top of the fixing piece 301 is provided with a groove matched with a rotating wheel 302 in size, and the fixing piece 301 limits the position of the rotating wheel 302; the rotating wheel 302 is arranged on the inner side of the top of the fixing piece 301, the size of the rotating wheel 302 is matched with a groove formed in the top end of the fixing piece 301, the rotating wheel 302 limits the positions of the telescopic piece 303 and the embedded piece 304, and meanwhile, the position of the embedded piece 304 can be adjusted by rotating the rotating wheel 302, so that an operator can conveniently place insulating paper on the embedded piece 304;

two opposite supporting rods 305 are fixedly connected to the top of the bottom plate 101, and the supporting rods 305 define the position of a telescopic rod 306 and provide support for the telescopic rod 306; two opposite telescopic rods 306 are arranged on the opposite surfaces of the two opposite support rods 305, the size of each telescopic rod 306 is matched with the distance between each support rod 305 and the corresponding extrusion part 307, and the telescopic rods 306 move oppositely to drive the corresponding extrusion part 307 to move;

Two opposite extrusion parts 307 are arranged on opposite sides of the two opposite telescopic rods 306, the size of each extrusion part 307 is matched with that of the stator 308, and the stator 308 is fixed by the extrusion parts 307; stators 308 are arranged on the opposite sides of the two opposite extrusion members 307, the stators 308 are matched with the embedded member 304, and the insulation paper which is arranged on the surface of the embedded member 304 and is cut is fed into the stators 308; one side of the stator 308 is provided with a stop 309, the size of the stop 309 is slightly larger than that of the insert 304 and smaller than that of a through hole formed in the stator 308, and when the insert 304 is driven by the telescopic member 303 to pass through one side of the stator 308 and pass out from the other side, the insulating paper is prevented from being brought out of the stator 308 by the insert 304.

The working process and principle are as follows: referring to fig. 1 to 10, an operator puts one end of a metal wire 104 wound on a coil 103 into a clamping block 110 through a through hole formed in a limiting block 105, a roller 209 and a positioning block 211, and a groove formed in an outer surface of a steering wheel 109, and then starts the motor to rotate a rotating gear 113, because the rotating gear 113 is fixedly connected with the rotating block 112, the rotating block 112 is located right above a wedge block 106 and a wedge block 108, the size of the rotating block 112 is matched with that of the wedge block 106 and the wedge block 108, the wedge block 106 and the wedge block 108 are respectively hinged with a supporting piece 107, when the rotating block 112 rotates, the wedge block 106 and the wedge block 108 periodically move with a hinge point with the supporting piece 107 as a fulcrum under the driving of the rotating block 112, and because of the angle setting of the wedge block 106 and the wedge block 108, when wedge block one 106 is at the top end, wedge block two 108 is at the bottom end, and since clamp block 110 is fixedly connected with wedge block two 108, clamp block 110 moves along with wedge block two 108, when the second wedge 108 is driven by the rotating block 112 to move downward from the highest position, the clamping block 110 will also move from the topmost position to the bottommost position, during this movement, the clamping block 110 will clamp the wire 104, which is inside, thereby pulling out the wire 104 wound on the coil 103, when the second wedge 108 and the clamping block 110 start to move from the bottommost end to the topmost end under the driving of the rotating block 112, at the moment, the clamping block 110 loosens the metal wire 104, the metal wire 104 wound outside the coil 103 is pulled out and matched with the steering wheel 109, the metal wire 104 in the bending state is straightened, the straightened metal wire 104 extends out of the bottom of the clamping block 110, and the wire diameter of the metal wire 104 is measured by the laser measuring instrument 111;

An operator starts the motor to rotate the rotating gear 113, the rotating gear 113 is meshed with the transmission gear 202, the transmission gear 202 is meshed with the driven gear 203, the rotating gear 113 rotates to drive the transmission gear 202 and the driven gear 203 to rotate, so that one rotating part 206 fixedly connected with the driven gear 203 is driven to rotate, the driven gear 203 is connected with the driven part 205 through the connecting rod 204 at one side of the driven gear 203 close to the side plate 201, two ends of the connecting rod 204 are hinged with the driven gear 203 and the driven part 205, the driven part 205 is fixedly connected with the other rotating part 206 at the side far from the side plate 201, so that the driven gear 203 is driven by the connecting rod 204 to synchronously rotate the driven part 205, so that the other rotating part 206 fixedly connected with the driven part 205 is driven to move, and a clamping block 208 is fixedly connected to one side of the chain 207 close to the roller 209 because the size of the chain 207 is matched with the two rotating parts 206, the size of the block 208 matches with the groove on the outer surface of the roller 209, so the chain 207 will start to move under the drive of the two rotating blocks 112, to drive the block 208 to move, so that the fixture block 208 makes periodic motion according to the motion track of the chain 207, at this time, the fixture block 208 moves and simultaneously moves along the groove formed on the outer surface of the roller 209, thereby driving the roller 209 to rotate, and at this time, the coil spring 210 connected to the bottom of the roller 209 is in an extended state, after the roller 209 rotates for a circle under the driving of the fixture block 208, the fixture block 208 does not contact with the groove on the outer surface of the roller 209, the roller 209 in this state is rotated in the reverse direction by the retracted coil spring 210, the initial movement is restored, when the fixture block 208 moves to the initial position under the driving of the chain 207, the fixture block is connected with the roller 209 again, and is circularly reciprocated, and then is matched with the clamping block 110 to clean dust passing through the outer surface of the metal wire 104 in the roller 209;

The cut insulating paper is placed on the embedded part 304 by an operator, at the moment, the telescopic part 303 is started, the embedded part 304 moves towards the direction of the stator 308, the size of the extrusion part 307 is matched with that of the stator 308, the extrusion part 307 clamps the stator 308 under the action of the telescopic rod 306, because the size of the embedded part 304 is matched with that of the through hole formed in the stator 308, when the embedded part 304 passes through one side of the stator 308 under the driving of the telescopic part 303, the insulating paper placed on the outer surface of the embedded part 304 enters the interior of the stator 308, at the moment, the side of the stator 308 far away from the embedded part 304 is provided with the stop 309, the size of the through hole formed in the interior of the stop 309 is slightly larger than that of the embedded part 304, so that when the embedded part 304 passes through the stator 308 through the interior of the stator 308, the insulating paper on the outer surface of the embedded part 304 is left in the interior of the stator 308 under the action of the stop 309, thereby achieving the purpose of conveniently inserting the insulating paper into the stator 308.

To sum up, in the device for calculating the winding wire diameter of the brushless motor, an operator starts the motor to rotate the rotary gear 113 by passing one end of the metal wire 104 wound on the coil 103 through the inside of the limiting block 105, through the through holes formed in the roller 209 and the positioning block 211, through the groove formed in the outer surface of the steering wheel 109, and finally placing the metal wire into the clamping block 110, at this time, the operator starts the motor to rotate the rotary gear 113, because the rotary gear 113 is fixedly connected with the rotary block 112, the rotary block 112 is located right above the first wedge 106 and the second wedge 108, the size of the rotary block 112 is matched with that of the first wedge 106 and the second wedge 108, the first wedge 106 and the second wedge 108 are respectively hinged with the supporting member 107, when the rotary block 112 rotates, the first wedge 106 and the second wedge 108 will make periodic motion by taking the hinged point with the supporting member 107 as a fulcrum under the driving of the rotary block 112, and because the angle of the first wedge 106 and the second wedge 108 is set, when the first wedge 106 is at the top end, the second wedge 108 is at the bottom end, because the clamping block 110 is fixedly connected with the second wedge 108, the clamping block 110 moves along with the second wedge 108, when the second wedge 108 starts to move downwards from the top under the drive of the rotating block 112, the clamping block 110 also moves from the top end to the bottom end, in the moving process, the clamping block 110 clamps the metal wire 104 in the inner part, so that the metal wire 104 wound on the coil 103 is pulled out, when the second wedge 108 and the clamping block 110 start to move from the bottom end to the top end under the drive of the rotating block 112, the clamping block 110 loosens the metal wire 104 in the inner part, the metal wire 104 wound outside the coil 103 is pulled out and matched with the steering wheel 109, the metal wire 104 in a bending state is pulled straight, the straight metal wire 104 extends from the bottom of the clamping block 110, and the wire diameter of the metal wire 104 is measured by the laser measuring instrument 111, thereby achieving the purpose of straightening the metal wire 104 in the bending state and measuring the wire diameter of the metal wire 104.

An operator starts the motor to rotate the rotating gear 113, the rotating gear 113 is meshed with the transmission gear 202, the transmission gear 202 is meshed with the driven gear 203, the rotating gear 113 rotates to drive the transmission gear 202 and the driven gear 203 to rotate, so that one rotating part 206 fixedly connected with the driven gear 203 is driven to rotate, the driven gear 203 is connected with the driven part 205 through the connecting rod 204 at one side of the driven gear 203 close to the side plate 201, two ends of the connecting rod 204 are hinged with the driven gear 203 and the driven part 205, the driven part 205 is fixedly connected with the other rotating part 206 at the side far from the side plate 201, so that the driven gear 203 is driven by the connecting rod 204 to synchronously rotate the driven part 205, so that the other rotating part 206 fixedly connected with the driven part 205 is driven to move, and a clamping block 208 is fixedly connected to one side of the chain 207 close to the roller 209 because the size of the chain 207 is matched with the two rotating parts 206, the size of the fixture block 208 is matched with the groove formed on the outer surface of the roller 209, so that the chain 207 starts to move under the driving of the two rotating blocks 112 to drive the fixture block 208 to move, so that the fixture block 208 makes periodic motion according to the motion track of the chain 207, at the moment, the fixture block 208 moves along the groove formed on the outer surface of the roller 209 to drive the roller 209 to start to rotate, at the moment, the coil spring 210 connected with the bottom of the roller 209 is in an extending state, after the roller 209 rotates for a circle under the driving of the fixture block 208, at the moment, the fixture block 208 does not contact with the groove formed on the outer surface of the roller 209, the roller 209 in the state is driven by the retracted coil spring 210 to reversely rotate to recover the initial motion, when the fixture block 208 moves to the initial position under the driving of the chain 207, the fixture block 208 is connected with the roller 209 again to circularly reciprocate, and then, under the matching with the clamping block 110, the dust passing through the outer surface of the metal wire 104 inside of the roller 209 is cleaned, thereby achieving the purpose of cleaning impurities present on the outer surface of the metal wire 104 due to long-term standing.

An operator puts the cut insulating paper on the embedded part 304, at the moment, the telescopic part 303 is started to enable the embedded part 304 to move towards the direction of the stator 308, because the size of the extrusion part 307 is matched with that of the stator 308, the extrusion part 307 can clamp the stator 308 under the action of the telescopic rod 306, because the size of the embedded part 304 is matched with that of a through hole formed in the stator 308, when the embedded part 304 passes through one side of the stator 308 under the driving of the telescopic part 303, the insulating paper placed on the outer surface of the embedded part 304 enters the stator 308 along with the through hole, because the side of the stator 308 far away from the embedded part 304 is provided with the stop 309, the size of the through hole formed in the stop 309 is slightly larger than that of the embedded part 304, when the embedded part 304 passes through the stator 308 through the interior of the stator 308, the insulating paper on the outer surface of the embedded part 304 is left in the stator 308 under the action of the stop 309, thereby achieving the purpose of conveniently inserting the insulating paper into the stator 308.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in the process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A device for calculating the wire diameter of a brushless motor winding is characterized in that: the device comprises a bottom plate (101) and a side plate (201), wherein a limiting block (102) is fixedly connected to the top of the bottom plate (101), a coil (103) is arranged on one side of the limiting block (102), a metal wire (104) is arranged on the outer side of the coil (103), a limiting block (105) is arranged on the outer side of one end, close to the coil (103), of the metal wire (104), a wedge block I (106) is fixedly connected to one side of the limiting block (105), a supporting piece (107) is sleeved on the outer side of one end, far away from the limiting block (105), of the wedge block I (106), a wedge block II (108) is arranged inside the supporting piece (107), a steering wheel (109) is arranged on the inner side of the top end of the metal wire (104), a clamping block (110) is arranged on the outer side of one end, far away from the coil (103), of the metal wire (104), and a laser measuring instrument (111) is arranged on the top of the bottom plate (101), the top of the second wedge block (108) is provided with a rotating block (112), one side of the rotating block (112) is fixedly connected with a rotating gear (113), one side of the side plate (201) is provided with a transmission gear (202), the top of the transmission gear (202) is meshed with a driven gear (203), one side, close to the side plate (201), of the driven gear (203) is provided with a connecting rod (204), one end, far away from the driven gear (203), of the connecting rod (204) is hinged to a driven member (205), and one side, far away from the connecting rod (204), of the driven member (205) is provided with a rotating member (206).

2. The apparatus for calculating winding wire diameter of brushless motor according to claim 1, wherein: the outer side of the rotating part (206) is provided with a chain (207), one side, away from the driven part (205), of the chain (207) is provided with a clamping block (208), and one side, back to the driven part (205), of the clamping block (208) is provided with a roller (209).

3. The apparatus for calculating winding wire diameter of brushless motor according to claim 2, wherein: the bottom of the roller (209) is provided with a coil spring (210), and the outer side of the coil spring (210) is provided with a positioning block (211).

4. The apparatus for calculating winding wire diameter of brushless motor according to claim 1, wherein: still include mounting (301), the inboard at mounting (301) top is provided with runner (302), one side fixedly connected with extensible member (303) of runner (302).

5. The apparatus for calculating winding wire diameter of brushless motor according to claim 4, wherein: the other side of the telescopic piece (303) is fixedly connected with an embedded piece (304).

6. The apparatus for calculating winding wire diameter of brushless motor according to claim 1, wherein: the top of bottom plate (101) fixedly connected with two opposite branch (305), two opposite two the opposite face of branch (305) is provided with two relative telescopic links (306).

7. The apparatus for calculating winding wire diameter of brushless motor according to claim 6, wherein: two opposite extrusion parts (307) are arranged on the opposite sides of the two opposite telescopic rods (306).

8. The apparatus for calculating winding wire diameter of brushless motor according to claim 7, wherein: stators (308) are provided on opposite sides of two of the pressing members (307) facing each other.

9. The apparatus for calculating winding wire diameter of brushless motor according to claim 8, wherein: a stop block (309) is arranged on one side of the stator (308).