CN220683996U - Swivel nut conveying device and swivel nut feeding equipment - Google Patents

Abstract

The utility model is suitable for the technical field of production and manufacturing, and provides a screw sleeve conveying device and screw sleeve feeding equipment. The device comprises a bracket, a linear motor, a moving part, a fixed seat, a cover plate and a feeding part; the bracket is fixed with the fixed seat; the linear motor is fixed on the fixed seat, and an output shaft of the linear motor is fixed with the moving part; the moving part is provided with a first notch; the fixed seat is provided with a first groove, the moving part is arranged in the first groove, and the linear motor drives the moving part to horizontally move along the length direction of the first groove; the fixing seat is provided with a second groove along the vertical direction of the first groove; the side surface of the first groove is provided with a blowing hole opposite to the second groove, and the blowing hole is used for introducing air flow to enable the screw sleeve to enter the feeding part from the first notch of the moving part; the cover plate is fixed on the connecting part of the first groove and the second groove of the fixing seat. The screw sleeve feeding device is simple in structure, and can feed the screw sleeve to the lower part of the material taking mechanism, so that the material taking mechanism is convenient to take materials.

Description

Swivel nut conveying device and swivel nut feeding equipment

Technical Field

The utility model belongs to the technical field of production and manufacturing, and particularly relates to a screw sleeve conveying device and screw sleeve feeding equipment.

Background

The steel wire thread sleeve is a novel internal thread fastener, is suitable for threaded connection, is screwed into and fastened in a threaded hole of one of the connected pieces to form a standard internal thread, and is screwed into the threaded hole again to fix the two connected pieces. The steel wire thread sleeve is also called a thread sleeve, and is called a sleeve for short. The spring-shaped internal and external thread concentric body is formed by precisely processing a cold-rolled diamond stainless steel wire with high strength, high precision and smooth surface, and is mainly used for reinforcing and protecting internal threads made of low-strength materials.

The existing steel wire thread insert conveying device adjusts the steel wire thread insert to be in a required vertical state in the conveying process, and the taking mechanism is convenient to take.

At present, the material taking mechanism is required to move to the steel wire thread insert conveying device to take materials, so that the material taking mechanism is inconvenient to take materials.

Disclosure of Invention

The embodiment of the utility model aims to provide a screw sleeve conveying device and screw sleeve feeding equipment, and aims to solve the problem that a material taking mechanism is inconvenient to take materials because the material taking mechanism is required to move to the steel wire screw sleeve conveying device to take materials.

The embodiment of the utility model is realized in such a way that the screw sleeve conveying device comprises a bracket, a linear motor, a moving part, a fixed seat, a cover plate and a feeding part;

the bracket is fixed with the fixed seat;

the linear motor is fixed on the fixed seat, and an output shaft of the linear motor is fixed with the moving piece;

the moving part is provided with a first notch which is matched with the size of the screw sleeve;

the fixed seat is provided with a first groove which is matched with the moving part, the moving part is arranged in the first groove, and the linear motor drives the moving part to horizontally move along the length direction of the first groove;

the fixed seat is provided with a second groove which is matched with the feeding piece along the vertical direction of the first groove and is used for fixing one end of the feeding piece to the fixed seat;

the side surface of the first groove of the fixed seat is provided with a blowing hole opposite to the second groove, and the blowing hole is used for introducing air flow to enable the screw sleeve to enter the feeding piece from the first notch of the moving piece when the first notch of the moving piece moves to be opposite to the second groove;

the cover plate is fixed on the joint of the first groove and the second groove of the fixing seat and used for preventing the screw sleeve from flying out from the upper part of the fixing seat in the process that the air blowing hole is used for introducing air flow.

Preferably, a second notch which is adapted to the first notch of the moving member is formed in the side surface of the first groove of the fixing seat, and is used as a feeding port of the screw sleeve conveying device, and the screw sleeve enters the second notch of the moving member through the second notch of the fixing seat.

Preferably, the opening at the connection position of the second groove and the first groove of the fixing seat is adapted to the first notch, a height difference exists between the concave surface of the opening and the bottom surface of the second groove, the height difference is the thickness of the channel wall of the feeding member, and the height difference is used for enabling the inner wall of the channel wall of the feeding member, the concave surface of the opening of the second groove and the concave surface of the first notch of the moving member to be in the same horizontal plane.

Preferably, the feeding member has a hollow passage therein adapted to the first gap for allowing the insert to enter the hollow passage from the first gap of the moving member during the air flow passing through the air blowing hole.

Another object of the embodiment of the utility model is a screw sleeve feeding device, which comprises a frame, a feeding device, a vibration transmission device and a screw sleeve conveying device, wherein the feeding device, the vibration transmission device and the screw sleeve conveying device are arranged on the frame;

the feeding device comprises a bin and a feeding part, wherein the bin is used for temporarily storing the screw sleeve, and the feeding part is used for transferring the screw sleeve from the bin to the vibration transmission device;

the vibration transmission device comprises a screw sleeve transmission groove and a vibration device for driving the screw sleeve transmission groove to vibrate, and the feeding end of the screw sleeve transmission groove is positioned right below the feeding position of the feeding device;

the feed inlet of the screw sleeve conveying device is positioned right below the discharge end of the vibration transmission device.

Preferably, the feed bin is arranged as an arc-shaped groove, the feed bin is obliquely arranged, the upper end of the feed bin is fixed with the mounting plate, and the lower end of the feed bin is positioned at the material taking position of the feeding piece.

Preferably, the feeding piece is disc-shaped, a plurality of arc-shaped feeding plates are arranged on the inner side of the feeding piece, and a first gear is arranged on the outer annular surface of the feeding piece;

the feeding part is fixed on the frame through a rotating shaft; a driving motor is arranged on a bottom plate of the frame, a second gear is arranged on an output shaft of the driving motor, and the first gear is meshed with the second gear.

Preferably, the screw sleeve transmission groove is provided with a transmission groove along the length direction, and the width of the transmission groove is matched with the outer diameter of the screw sleeve;

a discharge hole is formed in one side, close to the feeding end, of the transmission groove, and is used for discharging a non-upright screw sleeve in the transmission groove, and the discharge hole is positioned right above the storage bin;

an interception plate is arranged between the feeding end and the discharging port of the transmission groove and used for discharging overlapped screw sleeves in the transmission groove.

Preferably, the vibration device comprises a vibration motor, the vibration motor is fixed relative to the frame, a vibration platform is arranged at the top of the vibration motor, and the screw sleeve transmission groove is formed in the vibration platform.

Preferably, the screw sleeve feeding device further comprises a baffle plate, wherein the baffle plate is located right above the conveying groove of the screw sleeve conveying groove and close to the discharge end of the screw sleeve conveying groove, and the baffle plate is used for preventing the screw sleeve located in the conveying groove from overturning.

The screw sleeve conveying device provided by the embodiment of the utility model has the beneficial effects that:

after the screw sleeve enters the first notch of the moving part, the linear motor drives the moving part to horizontally move along the length direction of the first groove of the fixed seat, and when the first notch of the moving part moves to a position opposite to the second groove of the fixed seat, the air blowing hole is used for introducing air flow to enable the screw sleeve to enter the feeding part fixed in the second groove of the fixed seat from the first notch of the moving part. The screw sleeve feeding device is simple in structure, and can feed the screw sleeve to the lower part of the material taking mechanism, so that the material taking mechanism is convenient to take materials.

Drawings

Fig. 1 is a perspective view of a screw sleeve conveying device according to an embodiment of the present utility model;

FIG. 2 is a partial block diagram of FIG. 1;

FIG. 3 is a partial block diagram of FIG. 1;

FIG. 4 is an enlarged view of the feed member of FIG. 1;

fig. 5 is a perspective structural view 1 of a screw sleeve feeding device according to an embodiment of the present utility model;

fig. 6 is a perspective view of fig. 2 showing a removed part of a shell of a screw sleeve feeding device according to an embodiment of the present utility model;

fig. 7 is a rear view of a screw sleeve feeding device according to an embodiment of the present utility model.

In the accompanying drawings: 100. a screw sleeve conveying device; 110. a bracket; 120. a linear motor; 130. a moving member; 131. a first notch; 140. a fixing seat; 141. a first groove; 142. a second groove; 1421. an opening; 143. a blow hole; 144. a second notch; 150. a cover plate; 160. a feeding member; 161. a hollow passage; 200. a vibration transmission device; 210. a screw sleeve transmission groove; 211. a transmission groove; 212. a discharge port; 213. an interception plate; 220. a vibration device; 221. a vibration motor; 222. a vibration platform; 300. a feeding device; 310. a storage bin; 320. a feeding member; 321. a loading plate; 322. a first gear; 400. a frame; 410. a mounting plate; 420. a rotating shaft; 430. a bottom plate; 440. a connecting plate; 450. a support plate; 500. a driving motor; 510. a second gear; 600. and a baffle.

Detailed Description

The present utility model 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 utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Specific implementations of the utility model are described in detail below in connection with specific embodiments.

1-3, a structure diagram of a screw sleeve conveying device 100 according to an embodiment of the present utility model includes a bracket 110, a linear motor 120, a moving member 130, a fixing base 140, a cover plate 150 and a feeding member 160;

the bracket 110 is fixed with the fixing base 140;

the linear motor 120 is fixed on the fixed seat 140, and an output shaft of the linear motor 120 is fixed with the moving member 130;

the moving member 130 is provided with a first gap 131 corresponding to the size of the screw sleeve;

the fixed seat 140 is provided with a first groove 141 adapted to the moving member 130, the moving member 130 is disposed in the first groove 141, and the linear motor 120 drives the moving member 130 to move horizontally along the length direction of the first groove 141;

the fixing base 140 is provided with a second groove 142 adapted to the feeding member 160 along the vertical direction of the first groove 141, for fixing one end of the feeding member 160 to the fixing base 140;

the side surface of the first groove 141 of the fixed seat 140 is provided with a blowing hole 143 opposite to the second groove 142, and the blowing hole is used for introducing air flow to enable the screw sleeve to enter the feeding piece 160 from the first gap 131 of the moving piece 130 when the first gap 131 of the moving piece 130 moves to be opposite to the second groove 142;

the cover plate 150 is fixed on the connection between the first groove 141 and the second groove 142 of the fixing base 140, and is used for preventing the screw sleeve from flying out from above the fixing base 140 during the process of introducing the air flow into the air blowing hole 143.

In the embodiment of the present utility model, the linear motor 120 is used to drive the moving member 130 to move horizontally along the direction of the first groove 141, which can also be achieved by using a conventional servo motor and ball screw pair driving system.

In the embodiment of the present utility model, a groove is formed on the side of the moving member 130, which is close to the output shaft of the linear motor 120, and the output shaft is embedded in the groove to fix the output shaft and the moving member 130.

In the embodiment of the present utility model, the length and width of the first notch 131 should not be smaller than the outer diameter of the screw sleeve, and the height of the first notch 131 should not be lower than the height of the screw sleeve.

In the embodiment of the present utility model, the depth of the first groove 141 is identical to the height of the moving member 130 in order to maintain the upward face of the fixed seat 140 and the upward face of the moving member 130 at the same level. The groove width of the first groove 141 is slightly larger than the width of the moving member 130 in order to reduce friction, and the moving member 130 can be more smooth when moving. The length of the first groove 141 is identical to the length of the fixed seat 140, so that the length of the groove is longer than the length of the moving member 130 to ensure that the first notch 131 of the moving member 130 can reach a position opposite to the second groove 142 of the fixed seat 140.

In the embodiment of the present utility model, the connection between the second groove 142 and the first groove 141 is communicated, and the groove length of the second groove 142 extends from the connection between the second groove 142 and the first groove 141 to the side surface of the fixing base 140; the width of the second groove 142 is consistent with the width of the feeding member 160, so that the feeding member 160 can be embedded into the fixing base 140.

In the embodiment of the present utility model, the air hole 143 may be continuously connected to the moving member 130, and when the first notch 131 moves to the position opposite to the second groove 142, the air hole 143 is connected to the air hole.

In an embodiment of the present utility model, after the screw sleeve enters the first gap 131 of the moving member 130, the linear motor 120 drives the moving member 130 to move horizontally along the length direction of the first groove 141 of the fixed seat 140, and when the first gap 131 of the moving member 130 moves to a position opposite to the second groove 142 of the fixed seat 140, the air blowing hole 143 is blown with air flow to make the screw sleeve enter the feeding member 160 fixed in the second groove 142 of the fixed seat 140 from the first gap 131 of the moving member 130. The screw sleeve feeding device is simple in structure, and can feed the screw sleeve to the lower part of the material taking mechanism, so that the material taking mechanism is convenient to take materials.

As shown in fig. 1-3, as a preferred embodiment of the present utility model, a second notch 144 corresponding to the first notch 131 of the moving member 130 is formed on a side surface of the first groove 141 of the fixed seat 140, and is used as a feed port of the screw sleeve conveying device 100, so that the screw sleeve passes through the second notch 144 of the fixed seat 140 and enters the first notch 131 of the moving member 130.

In the embodiment of the present utility model, the length and height of the second notch 144 are consistent with those of the first notch 131, and the width of the second notch 144 is consistent with the thickness of the side surface where the second notch 144 is located.

In the embodiment of the present utility model, the position of the second notch 144 is attached to the position before the first notch 131 is not moved, so that the screw sleeve can enter the first notch 131 of the moving member 130 through the second notch 144 of the fixed seat 140.

As shown in fig. 1-3, as another preferred embodiment of the present utility model, the opening 1421 at the end of the second groove 142 connected to the first groove 141 of the fixed base 140 is adapted to the first notch 131, and the concave surface of the opening 1421 and the bottom surface of the second groove 142 have a height difference, which is the thickness of the channel wall of the feeding member 160, so that the inner wall of the channel wall of the feeding member 160, the concave surface of the opening 1421 of the second groove 142 and the concave surface of the first notch 131 of the moving member 130 are at the same level.

In the embodiment of the present utility model, the length and height of the opening 1421 at the end of the second groove 142 connected to the first groove 141 are identical to those of the first notch 131.

In the embodiment of the utility model, there is a thickness difference between two sides of the opening 1421 and two sides corresponding to the second groove 142, where the thickness difference is the thickness of the channel wall of the feeding member 160.

As shown in fig. 4, as another preferred embodiment of the present utility model, the feeding member 160 has a hollow channel 161 corresponding to the first gap 131 therein, and the hollow channel 161 is used for inserting a screw sleeve from the first gap 131 of the moving member 130 into the air flow passing through the air blowing hole 143.

In the embodiment of the present utility model, the feeding member 160 is a curved rectangular member having a hollow passage 161 formed therein.

As shown in fig. 5, the embodiment of the utility model further provides a screw sleeve feeding device, which comprises a frame 400, a feeding device 300, a vibration transmission device 200 and a screw sleeve conveying device 100, wherein the feeding device 300, the vibration transmission device 200 and the screw sleeve conveying device 100 are arranged on the frame 400;

the feeding device 300 comprises a bin 310 and a feeding piece 320, wherein the bin 310 is used for temporarily storing the screw sleeve, and the feeding piece 320 is used for transferring the screw sleeve from the bin 310 to the vibration transmission device 200;

the vibration transmission device 200 comprises a screw sleeve transmission groove 210 and a vibration device 220 for driving the screw sleeve transmission groove 210 to vibrate, wherein the feeding end of the screw sleeve transmission groove 210 is positioned right below the feeding position of the feeding device 300;

the feed inlet of the screw sleeve conveying device 100 is positioned right below the discharge end of the vibration transmission device 200.

In an embodiment of the present utility model, the rack 400 includes a base 430, and each device is mounted on the base 430.

In the embodiment of the present utility model, a connection plate 440 is disposed on the frame 400, the connection plate 440 is provided with a circular hole, one side of the circular hole is fixed with the bin 310, and the other side of the circular hole is opposite to the feeding member 320.

In the embodiment of the present utility model, the feed port of the screw sleeve delivery device 100 is close to the discharge end of the vibration transmission device 200 but is not in contact with the discharge end of the vibration transmission device 200.

In one embodiment of the present utility model, a screw sleeve is temporarily stored in the magazine 310, the screw sleeve in the magazine 310 is transferred to the screw sleeve transferring groove 210 through the feeding member 320, the vibration device 220 vibrates the screw sleeve transferring groove 210, so that the screw sleeve positioned in the screw sleeve transferring groove 210 is transferred forward to the second notch 144 of the feed inlet of the screw sleeve transferring device 100, after the screw sleeve enters the first notch 131 from the second notch 144, the linear motor 120 drives the moving member 130 to horizontally move along the length direction of the first groove 141 of the fixed seat 140, and when the first notch 131 of the moving member 130 moves to a position opposite to the second groove 142 of the fixed seat 140, the air blowing hole 143 is introduced with air flow to enable the screw sleeve to enter the feeding member 160 fixed in the second groove 142 of the fixed seat 140 from the first notch 131 of the moving member 130. The screw sleeve feeding device is simple in structure, and can feed the screw sleeve to the lower part of the material taking mechanism, so that the material taking mechanism is convenient to take materials.

As shown in fig. 5, as a preferred embodiment of the present utility model, the bin 310 is provided as an arc-shaped groove, the bin 310 is inclined, the upper end is fixed to the mounting plate 410, and the lower end is located at the material taking position of the loading member 320.

In the embodiment of the utility model, the inner wall of the stock bin 310 is smooth, and due to the arc-shaped structure and the inclined arrangement, the screw sleeve slides in the inclined stock bin 310 to fall to the lower end, and the lower end of the stock bin 310 is connected with the material taking position of the feeding member 320.

In an embodiment of the present utility model, mounting plate 410 is secured to bottom plate 430.

As shown in fig. 5-7, as a preferred embodiment of the present utility model, the feeding member 320 is configured as a disc, a plurality of arc-shaped feeding plates 321 are disposed on the inner side of the feeding member 320, and a first gear 322 is disposed on the outer annular surface of the feeding member 320;

the feeding member 320 is fixed on the frame 400 through a rotating shaft 420; a driving motor 500 is disposed on the bottom plate 430 of the frame 400, a second gear 510 is disposed on an output shaft of the driving motor 500, and the first gear 322 is meshed with the second gear 510.

In the embodiment of the present utility model, the feeding machine is fixed on the support plate 450 through the rotating shaft 420, the support plate 450 is fixed with the frame 400, and the feeding member 320 and the rotating shaft 420 are relatively fixed, that is, the feeding member 320 rotates along with the rotating shaft 420, and the rotating shaft 420 is rotationally connected with the support plate 450.

In the embodiment of the present utility model, there are two driving motors 500 respectively disposed at the left and right sides of the first gear 322 to engage the two second gears 510 with the first gear 322.

In the embodiment of the utility model, the second gear 510 on the driving motor 500 rotates to drive the first gear 322 to rotate, the rotation of the first gear 322 means that the feeding member 320 rotates, so that the arc-shaped feeding plate 321 at the inner side of the feeding member 320 supports the screw sleeve at the material taking position of the feeding member 320 to transmit in the rotating direction, when the arc-shaped concave surface of the arc-shaped feeding plate 321 faces downwards, the screw sleeve positioned on the concave surface of the arc-shaped feeding plate 321 drops downwards, and falls on the feeding end of the screw sleeve transmission groove 210 extending into the inner side of the feeding member 320 and close to the center of the feeding member 320.

In the embodiment of the present utility model, changing the rotation speed of the driving motor 500 may change the rotation speed of the first gear, thereby changing the feeding speed.

As shown in fig. 5, as a preferred embodiment of the present utility model, the screw sleeve transferring groove 210 is provided with a transferring groove 211 in a length direction, and the width of the transferring groove 211 is adapted to the outer diameter of the screw sleeve;

a discharge hole 212 is formed in one side, close to the feeding end, of the conveying groove 211, the discharge hole 212 is used for discharging a non-upright screw sleeve in the conveying groove 211, and the discharge hole 212 is positioned right above the stock bin 310;

an interception plate 213 is disposed between the feeding end of the transmission groove 211 and the discharge port 212, and is used for discharging the overlapped screw sleeves in the transmission groove 211.

In the embodiment of the utility model, one side of the feeding end of the transmission groove 211 is provided with a feeding slope, so that the screw sleeve can fall into the input groove conveniently, and the range of aggregate is enlarged.

In the embodiment of the present utility model, the discharge port 212 is removed by removing a portion of the side wall of the transmission groove 211, so that when the non-upright screw sleeve is conveyed to the position of the discharge port 212, the non-upright screw sleeve falls into the feeding bin 310 under the action of vibration, and the upright screw sleeve screen continuously moves towards the discharge end along the transmission groove 211 through the discharge port 212.

In the embodiment of the present utility model, the height of the interception plate 213 from the concave surface of the transmission groove 211 is slightly higher than the height of the screw sleeve, and when the screw sleeves are overlapped, the overlapped screw sleeves are intercepted in the moving process so that the screw sleeves fall into the feeding bin 310.

As shown in fig. 6, as a preferred embodiment of the present utility model, the vibration device 220 includes a vibration motor 221, the vibration motor 221 is fixed to the frame 400, a vibration platform 222 is disposed on top of the vibration motor 221, and the screw sleeve transmission groove 210 is disposed on the vibration platform 222.

In the embodiment of the present utility model, the connection between the vibration platform 222 and the screw sleeve transmission groove 210 is set in a form of a chute, so that the position of the screw sleeve transmission groove 210 relative to the chute can be adjusted and then fixed, and the fixing manner can be realized by matching a screw with a kidney-shaped hole, which belongs to a common connection manner, and the embodiment is not repeated. By adjusting the position of the screw sleeve transfer slot 210 relative to the vibration platform 222, the amplitude of vibration at both ends of the screw sleeve transfer slot 210 can be varied. Further, the conveying speed can also be adjusted by changing the vibration frequency of the vibration motor 221.

As shown in fig. 5 to 6, as a preferred embodiment of the present utility model, the screw sleeve feeding apparatus further includes a baffle 600, the baffle 600 being located right above the transmission groove 211 of the screw sleeve transmission groove 210, near the discharge end of the screw sleeve transmission groove 210, the baffle 600 being used to prevent the screw sleeve located in the transmission groove 211 from tipping over.

In the embodiment of the present utility model, the baffle 600 is located right above the transmission groove 211, and the distance between the baffle 600 and the concave surface of the transmission groove 211 is slightly larger than the height of the conveyed screw sleeve, and when the screw sleeve is toppled over, the top of the screw sleeve touches the baffle 600, so that the screw sleeve can be conveyed forwards from the transmission groove 211 but cannot be tipped over.

In an embodiment of the present utility model, the baffles extend from the discharge opening 212 of the sleeve transport groove 210 to the discharge end. By the arrangement of the baffle 600, the screw is always in an upright state during the transfer of the screw transfer groove 210.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. The screw sleeve conveying device is characterized by comprising a bracket, a linear motor, a moving part, a fixed seat, a cover plate and a feeding part;

the bracket is fixed with the fixed seat;

the linear motor is fixed on the fixed seat, and an output shaft of the linear motor is fixed with the moving piece;

the moving part is provided with a first notch which is matched with the size of the screw sleeve;

the fixed seat is provided with a first groove which is matched with the moving part, the moving part is arranged in the first groove, and the linear motor drives the moving part to horizontally move along the length direction of the first groove;

the fixed seat is provided with a second groove which is matched with the feeding piece along the vertical direction of the first groove and is used for fixing one end of the feeding piece to the fixed seat;

the side surface of the first groove of the fixed seat is provided with a blowing hole opposite to the second groove, and the blowing hole is used for introducing air flow to enable the screw sleeve to enter the feeding piece from the first notch of the moving piece when the first notch of the moving piece moves to be opposite to the second groove;

the cover plate is fixed on the joint of the first groove and the second groove of the fixing seat and used for preventing the screw sleeve from flying out from the upper part of the fixing seat in the process that the air blowing hole is used for introducing air flow.

2. The screw sleeve conveying device according to claim 1, wherein a second notch which is matched with the first notch of the moving piece is formed in the side face of the first groove of the fixing seat and is used as a feeding port of the screw sleeve conveying device, and the screw sleeve enters the first notch of the moving piece through the second notch of the fixing seat.

3. The screw sleeve conveying device according to claim 1, wherein an opening at one end of the second groove of the fixing seat connected with the first groove is matched with the first notch, a height difference exists between a concave surface of the opening and a bottom surface of the second groove, the height difference is the thickness of a channel wall of the feeding member, and the inner wall of the channel wall of the feeding member, the concave surface of the opening of the second groove and the concave surface of the first notch of the moving member are located on the same horizontal plane.

4. The screw sleeve conveying device according to claim 1, wherein the interior of the feeding member is provided with a hollow channel which is matched with the first notch, and the screw sleeve is used for entering the hollow channel from the first notch of the moving member in the process that the air blowing hole is used for introducing air flow.

5. A screw sleeve feeding device, which is characterized by comprising a frame, a feeding device, a vibration transmission device and a screw sleeve conveying device, wherein the feeding device, the vibration transmission device and the screw sleeve conveying device are arranged on the frame;

the feeding device comprises a bin and a feeding part, wherein the bin is used for temporarily storing the screw sleeve, and the feeding part is used for transferring the screw sleeve from the bin to the vibration transmission device;

the vibration transmission device comprises a screw sleeve transmission groove and a vibration device for driving the screw sleeve transmission groove to vibrate, and the feeding end of the screw sleeve transmission groove is positioned right below the feeding position of the feeding device;

the feed inlet of the screw sleeve conveying device is positioned right below the discharge end of the vibration transmission device.

6. The screw sleeve feeding device according to claim 5, wherein the stock bin is provided as an arc-shaped groove, the stock bin is obliquely arranged, the upper end of the stock bin is fixed with the mounting plate, and the lower end of the stock bin is positioned at the material taking position of the feeding piece.

7. The screw sleeve feeding device according to claim 5, wherein the feeding piece is disc-shaped, a plurality of arc-shaped feeding plates are arranged on the inner side of the feeding piece, and a first gear is arranged on the outer annular surface of the feeding piece;

the feeding part is fixed on the frame through a rotating shaft; a driving motor is arranged on a bottom plate of the frame, a second gear is arranged on an output shaft of the driving motor, and the first gear is meshed with the second gear.

8. The insert feeding apparatus according to claim 5, wherein the insert transfer groove is provided with a transfer groove in a length direction, a width of the transfer groove being adapted to an outer diameter of the insert;

a discharge hole is formed in one side, close to the feeding end, of the transmission groove, and is used for discharging a non-upright screw sleeve in the transmission groove, and the discharge hole is positioned right above the storage bin;

an interception plate is arranged between the feeding end and the discharging port of the transmission groove and used for discharging overlapped screw sleeves in the transmission groove.

9. The screw sleeve feeding device according to claim 5, wherein the vibration device comprises a vibration motor, the vibration motor is relatively fixed with the frame, a vibration platform is arranged at the top of the vibration motor, and the screw sleeve transmission groove is formed in the vibration platform.

10. The insert loading apparatus of claim 5, further comprising a baffle positioned directly above the transfer groove of the insert transfer groove, proximate the discharge end of the insert transfer groove, the baffle configured to prevent an insert positioned in the transfer groove from tipping.