CN213521600U - Brushless stator winding graduation and hanging wire integrated spindle - Google Patents

Abstract

The utility model discloses a brushless stator wire winding graduation and hanging wire integrated main shaft, it includes: mounting a plate; the hollow pipeline penetrates through the mounting plate and is fixedly mounted on the mounting plate; the ejector rod is slidably mounted in the hollow pipeline, and a first through groove is formed in the top end of the ejector rod; the upper shaft sleeve is fixedly arranged at the upper end of the hollow pipeline; the wire hooking plate is provided with a clamping hook at the end part, the first through groove is matched with the wire hooking plate, and the wire hooking plate is slidably installed in the first through groove; the top piece is fixedly arranged at the top of the upper shaft sleeve; a locking disk mounted on the top piece; the driving device is fixedly arranged at the bottom of the mounting plate and is connected with the ejector rod; realize the fixed stator of joint and rotate the stator, prevent to skid simultaneously to and practice thrift the upper portion space, and then make things convenient for the wiring, collude the line, improve work efficiency.

Description

Brushless stator winding graduation and hanging wire integrated spindle

Technical Field

The utility model relates to motor spooling equipment technical field especially involves a brushless stator wire winding graduation and hanging wire integrated main shaft.

Background

The basic structure of the motor can be divided into two parts: firstly, a fixed part: the stator (comprising a laminated stator, a stator winding, an insulation structure, a base, a junction box and the like); II, a rotating part: the rotor (including cast aluminum rotor, squirrel cage guide bar, rotating shaft, bearing, front and back end covers, etc.). The stator winding and cage bars are the key components of the motor to perform electromagnetic energy conversion, which must adhere to three basic principles: firstly, a magnetic field is necessarily generated after the winding is electrified; the winding conductor and the magnetic field generate relative cutting movement, and electromotive force is necessarily generated in the winding; and (III) if current passes through the winding and is in the magnetic field, the conductor is inevitably subjected to the action of the magnetic field force. Basic operation principle of three-phase asynchronous motor: after the stator passes through three-phase alternating current, a magnetic field rotating at a synchronous speed is generated in the air gap, the magnetic field induces current in the rotor conducting bars after cutting the rotor conducting bars, and the electrified rotor conducting bars are positioned in the magnetic field rotating in the air gap, so that electric power is generated again, and the rotor rotates towards the same direction of the rotating magnetic field of the stator. Because the current in the rotor conducting bar is unique to the air gap magnetic field generated by the stator winding because of the cutting of the rotor conducting bar, the rotating speed of the rotor can only be lower than the synchronous rotating speed of the air gap rotating magnetic field, and the synchronization can never be achieved (otherwise, the rotor conducting bar rotates synchronously with the air gap magnetic field, the rotor conducting bar can not cut the magnetic field, the current can not be induced, the electrodynamic force can not be generated, and the rotor can not rotate), so the asynchronous motor is named.

The clamping part occupation space of the existing motor winding clamping device is too large, the designed winding wire hooking and leading device is too complex and the efficiency is not high, the wire hooking device designed in the first half is inconvenient in the actual use process, the clamping of the mechanical clamping arm on the part is influenced, waiting is needed when partial procedures are carried out, more parts need to be bypassed at the installation position, and the use and production cost are high.

Accordingly, there is a need for a brushless stator winding indexing and stringing integrated spindle that solves one or more of the above problems.

SUMMERY OF THE UTILITY MODEL

For solving one or more problems that exist among the prior art, the utility model provides a brushless stator wire winding graduation and hanging wire integrated main shaft. The utility model discloses a solve the technical scheme that above-mentioned problem adopted and be: the utility model provides a brushless stator winding graduation and hanging wire integrated main shaft which characterized in that includes: mounting a plate;

the hollow pipeline penetrates through the mounting plate and is fixedly mounted on the mounting plate;

the ejector rod is slidably mounted in the hollow pipeline, a first through groove is formed in the top end of the ejector rod, and a connecting hole is formed in the side wall of the first through groove;

the upper shaft sleeve is fixedly installed at the upper end of the hollow pipeline, and a first matching through groove is formed in the top end of the upper shaft sleeve;

the wire hooking plate is provided with a chute matched with the connecting hole, a clamping hook is arranged at the end part of the wire hooking plate, the first through groove is matched with the wire hooking plate, the chute is matched with the connecting hole, and the wire hooking plate is slidably installed in the first matching through groove;

the lower end of the top piece is provided with a second matching through groove matched with the line hooking plate, and the top piece is fixedly installed at the top of the upper shaft sleeve;

the locking disc is arranged on the top piece, and when the top piece moves upwards, the locking disc is tightly sleeved on the stator on the outer side surface of the locking disc;

the driving device is fixedly installed at the bottom of the mounting plate and connected with the ejector rod, and the ejector rod is driven by the driving device to move up and down.

Further, still include: the pressing plate is provided with a matching notch matched with the clamping hook, the pressing plate is fixedly installed at the top end of the upper shaft sleeve or at the lower end of the top piece, and the pressing plate is limited in the leftward and rightward movement of the wire hooking plate.

Further, still include: the upper end parts of the sliding rods are fixedly arranged at the bottom of the mounting plate, and the lower end parts of the sliding rods are fixedly connected with the driving device; the circumferential rotating device is slidably mounted on the sliding rod and connected with the driving device, the lower end part of the ejector rod is fixedly mounted in the circumferential rotating device, and the driving device drives the circumferential rotating device to move up and down.

Further, still include: the rotating device is fixedly installed on the installation plate, a driven wheel is fixedly connected to the hollow pipeline, and the driven wheel is connected with a driving wheel of the rotating device through a belt.

Further, still include: the tensioning wheel is installed on the mounting plate and used for adjusting the tightness of the driving wheel and the connecting belt of the driven wheel.

Further, still include: the connecting shaft sleeve is fixedly arranged at the upper end part of the hollow pipeline and fixedly connected with the upper shaft sleeve.

Furthermore, the ejector rod is provided with a step, the step is connected with the connecting shaft sleeve in a clamping mode, and the connecting shaft sleeve is limited by the ejector rod.

Further, the connecting shaft sleeve is fixedly arranged at the upper end of the hollow pipeline by using a first locking piece and a second locking piece.

Further, the driving device is a linear motor.

The utility model discloses the beneficial effect who gains is: the utility model realizes the locking and winding of the stator and the rotation of the stator in the locking process by connecting the mounting plate, the hollow pipeline, the ejector rod, the upper shaft sleeve, the line hooking plate, the ejector piece, the locking disc, the driving device and other components together through an ingenious structure, and the line hooking plate for winding is arranged at the lower side of the locking disc in a matching way, so that the wiring and the winding of the winding device are more convenient, and the upper space is saved; when the locking disc does not lock the stator, the ejector rod enables the line hooking plate to be pressed on the pressing plate through the chute, the line is pressed tightly, when the locking disc locks the stator, the line hooking plate is loosened to hook the line, and therefore working efficiency is improved. The utility model discloses a practical value has greatly improved above.

Drawings

Fig. 1 is a perspective view of a brushless stator winding indexing and hanging integrated spindle according to the present invention;

fig. 2 is a schematic view of a brushless stator winding indexing and hanging integrated spindle according to the present invention;

fig. 3 is a top view of the brushless stator winding indexing and hanging integrated spindle according to the present invention;

fig. 4 is a partial exploded view of the brushless stator winding indexing and hanging integrated spindle according to the present invention;

fig. 5 is a side view of the brushless stator winding indexing and hanging integrated spindle of the present invention;

fig. 6 is a sectional view of the brushless stator winding graduation and hanging wire integrated spindle of the present invention in the direction of a-a.

[ reference numerals ]

101. mounting plate

110. stator

201 sliding rod

301. drive device

401 circumferential rotation device

501. ejector pin

502. step

503. first through groove

504. connecting hole

510. line drawing board

511. chute

512. trip

520. pressing plate

521 DEG A mating notch

601. rotating device

602. driving wheel

603. slave wheel

610. tensioning wheel

701. hollow pipeline

702. connecting sleeve

703. first locking member

704. second locking member

710. upper shaft sleeve

711. first fitting through groove

720. top piece

721. second matching through groove

801. locking disk.

Detailed Description

In order to make the above objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the invention.

As shown in fig. 1-6, the utility model discloses a brushless stator winding graduation and hanging wire integrated main shaft, it includes: a mounting plate 101;

a hollow pipeline 701, wherein the hollow pipeline 701 penetrates through the mounting plate 101 and is fixedly mounted on the mounting plate 101;

the top rod 501 is slidably mounted in the hollow pipeline 701, a first through groove 503 is formed in the top end of the top rod 501, and a connecting hole 504 is formed in the side wall of the first through groove 503;

the upper shaft sleeve 710 is fixedly installed at the upper end of the hollow pipeline 701, and a first matching through groove 711 is formed in the top end of the upper shaft sleeve 710;

the wiring board 510 is provided with an inclined groove 511 matched with the connecting hole 504, a clamping hook 512 is arranged at the end of the wiring board 510, the first through groove 503 is matched with the wiring board 510, the inclined groove 511 is matched with the connecting hole 504, and the wiring board 510 is slidably mounted in the first matching through groove 711;

the lower end of the top piece 720 is provided with a second matching through groove 721 matched with the wiring board 510, and the top piece 720 is fixedly arranged at the top of the upper shaft sleeve 710;

the locking disc 801 is installed on the top piece 720, and when the top piece 720 moves upwards, the locking disc 801 is tightly sleeved on the stator 110 on the outer side surface of the locking disc 801;

the driving device 301 is fixedly installed at the bottom of the installation plate 101, the driving device 301 is connected with the ejector rod 501, and the driving device 301 drives the ejector rod 501 to move up and down.

It should be noted that the locking plate 801 and the driving device 301 are conventional technical means, and specific reference may be made to patent numbers: 201821889528.9. the top rod 501 penetrates through the inclined groove 511 of the line hooking plate 510 through a connecting rod and is connected with the line hooking plate 510, so that when the top rod 501 moves downwards, the clamping hook 512 on the line hooking plate 510 moves inwards to press a line, and otherwise, the line is hooked.

Specifically, as shown in fig. 4, the method further includes: the pressing plate 520 is provided with a matching notch 521 matched with the hook 512, the pressing plate 520 is fixedly installed at the top end of the upper shaft sleeve 710 or at the lower end of the top part 720, the pressing plate 520 is limited in the left-right movement of the hook plate 510, and therefore the hook plate 510 is prevented from being separated from the pressing plate 520 due to the fact that the distance between the hook 512 and the pressing plate 520 is too large. The wire hooking plate 510 is matched for wire hooking and pressing, and a rubber buffer layer can be arranged on the pressing plate 520.

Specifically, as shown in fig. 2 and 6, the method further includes: at least two sliding rods 201 are arranged, the upper end parts of the sliding rods 201 are fixedly arranged at the bottom of the mounting plate 101, and the lower end parts of the sliding rods 201 are fixedly connected with the driving device 301; the circumferential rotating device 401 is slidably mounted on the sliding rod 201 and connected with the driving device 301, the lower end part of the top rod 501 is fixedly mounted in the circumferential rotating device 401, and the driving device 301 drives the circumferential rotating device 401 to move up and down.

Specifically, as shown in fig. 2 and 3, the method further includes: the rotating device 601 is fixedly installed on the installation plate 101, a driven wheel 603 is fixedly connected to the hollow pipeline 701, and the driven wheel 603 is connected with a driving wheel 602 of the rotating device 601 through a belt. And further comprising: and a tension pulley 610, wherein the tension pulley 610 is mounted on the mounting plate 101, and the tension pulley 610 is used for adjusting the tightness of the connecting belt of the driving pulley 602 and the driven pulley 603.

Specifically, as shown in fig. 4 and 6, the method further includes: the connecting shaft sleeve 702 is fixedly installed at the upper end of the hollow pipeline 701, and the upper shaft sleeve 710 is fixedly connected with the connecting shaft sleeve 702. The ejector rod 501 is provided with a step 502, the step 502 is connected with the connecting shaft sleeve 702 in a clamping mode, and the connecting shaft sleeve 702 limits the ejector rod 501. The hollow pipe 701 is matched, so that the rotating device 601 drives the top part 720 to rotate through the hollow pipe 701, the connecting sleeve 702 and the upper sleeve 710. Generally, the connecting sleeve 702 is fixedly mounted on the upper end of the hollow pipe 701 by using a first locking member 703 and a second locking member 704, wherein the first locking member 703 and the second locking member 704 are common fixing means.

It should be noted that the driving device 301 is generally a linear motor or a cylinder driving device, and the rotating device 601 is generally a motor.

The utility model discloses a use-way is: the driving device 301 drives the circumferential rotating device 401 to move upwards, so that the top rod 501 fixed in the circumferential rotating device 401 in a rotating mode moves upwards, the inclined groove 511 drives the hook 512 of the hook plate 510 to move outwards in the upwards moving process of the top rod 501, the releasing action is convenient for hooking, meanwhile, the top rod 501 drives the upper shaft sleeve 710 and the top piece 720 to move upwards, and the top piece 720 moves upwards to jack the locking disc 801 so that the locking disc 801 can fix the stator 110; the rotating device 601 is fixedly connected with the hollow pipeline 701, generally implemented by using a key, so that the hollow pipeline 701 rotates, the hollow pipeline 701 drives the connecting shaft sleeve 702, the upper shaft sleeve 710, the top part 720 and the locking disc 801 to rotate, and further the stator 110 rotates by a certain angle in a locked state for adjustment.

To sum up, the utility model realizes the locking and winding of the stator and the rotation of the stator in the locking process by connecting the mounting plate 101, the hollow pipeline 701, the ejector rod 501, the upper shaft sleeve 710, the wire hooking plate 510, the top piece 720, the locking disc 801, the driving device 301 and other components together through an ingenious structure, and the wire hooking plate for winding is arranged at the lower side of the locking disc in a matching way, so that the wiring and winding of the winding device are more convenient, and the upper space is saved; when the locking disc does not lock the stator, the ejector rod enables the line hooking plate to be pressed on the pressing plate through the chute, the line is pressed tightly, when the locking disc locks the stator, the line hooking plate is loosened to hook the line, and therefore working efficiency is improved. The utility model discloses a practical value has greatly improved above.

The above-described embodiments merely represent one or more embodiments of the present invention, which are described in detail and concrete, but are not to be construed as limiting the present invention. It should be noted that, for those skilled in the art, without departing from the concept of the present invention, several variations and modifications can be made, which all fall within the protection scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (9)

1. The utility model provides a brushless stator winding graduation and hanging wire integrated main shaft which characterized in that includes: mounting a plate;

the hollow pipeline penetrates through the mounting plate and is fixedly mounted on the mounting plate;

the ejector rod is slidably mounted in the hollow pipeline, a first through groove is formed in the top end of the ejector rod, and a connecting hole is formed in the side wall of the first through groove;

the upper shaft sleeve is fixedly installed at the upper end of the hollow pipeline, and a first matching through groove is formed in the top end of the upper shaft sleeve;

the wire hooking plate is provided with a chute matched with the connecting hole, a clamping hook is arranged at the end part of the wire hooking plate, the first through groove is matched with the wire hooking plate, the chute is matched with the connecting hole, and the wire hooking plate is slidably installed in the first matching through groove;

the lower end of the top piece is provided with a second matching through groove matched with the line hooking plate, and the top piece is fixedly installed at the top of the upper shaft sleeve;

the locking disc is arranged on the top piece, and when the top piece moves upwards, the locking disc is tightly sleeved on the stator on the outer side surface of the locking disc;

the driving device is fixedly installed at the bottom of the mounting plate and connected with the ejector rod, and the ejector rod is driven by the driving device to move up and down.

2. The brushless stator winding indexing and hanging integrated spindle of claim 1, further comprising: the pressing plate is provided with a matching notch matched with the clamping hook, the pressing plate is fixedly installed at the top end of the upper shaft sleeve or the lower end of the top piece, and the pressing plate is limited in the leftward and rightward movement of the wire hooking plate.

3. The brushless stator winding indexing and hanging integrated spindle of claim 1, further comprising: the upper end parts of the sliding rods are fixedly arranged at the bottom of the mounting plate, and the lower end parts of the sliding rods are fixedly connected with the driving device; the circumferential rotating device is slidably mounted on the sliding rod and connected with the driving device, the lower end part of the ejector rod is fixedly mounted in the circumferential rotating device, and the driving device drives the circumferential rotating device to move up and down.

4. The brushless stator winding indexing and hanging integrated spindle of claim 1, further comprising: the rotating device is fixedly installed on the installation plate, a driven wheel is fixedly connected to the hollow pipeline, and the driven wheel is connected with a driving wheel of the rotating device through a belt.

5. The brushless stator winding indexing and hanging integrated spindle of claim 4, further comprising: the tensioning wheel is installed on the mounting plate and used for adjusting the tightness of the driving wheel and the connecting belt of the driven wheel.

6. The brushless stator winding indexing and hanging integrated spindle of claim 1, further comprising: the connecting shaft sleeve is fixedly arranged at the upper end part of the hollow pipeline and fixedly connected with the upper shaft sleeve.

7. The brushless stator winding, indexing and wire hanging integrated spindle according to claim 6, wherein the ejector rod is provided with a step, the step is clamped with the connecting shaft sleeve, and the connecting shaft sleeve limits the ejector rod.

8. The brushless stator winding, indexing and winding integrated spindle of claim 6, wherein the connecting sleeve is fixedly mounted to the hollow conduit end portion using a first locking member and a second locking member.

9. The brushless stator winding, indexing and winding integrated spindle of claim 1, wherein the driving mechanism is a linear motor.

Images