CN211018582U - Beating mechanism of motor iron core pressure riveting device - Google Patents

Abstract

The utility model provides a motor core presses beating mechanism of riveting device belongs to mechanical technical field. It has solved the current not good problem of squeeze quality of squeeze riveter. This mechanism of beating of motor core pressure riveting device includes the ejector pin, support and telescopic cylinder are four, telescopic cylinder is four including the cylinder body and be piston rod four of vertical setting, the cylinder body is fixed on the support, the lower extreme and the ejector pin of piston rod four link firmly, the vertical sleeve that is fixed with on the cylinder body, the upper end of piston rod four stretches out the cylinder body and is located the sleeve, it is provided with the balancing weight and makes the balancing weight have the spring two of downward motion trend to slide in the sleeve, directly over the balancing weight is in piston rod four, have on the sleeve along the radial connecting hole that runs through of this sleeve, be equipped with the supporting shoe in the connecting hole, the sleeve external fixation has the driving piece three that makes the supporting shoe can follow the radial reciprocal translation of sleeve, and under driving piece three effects. The utility model discloses the suppression is of high quality.

Description

Beating mechanism of motor iron core pressure riveting device

Technical Field

The utility model belongs to the technical field of machinery, a device, especially a mechanism is beaten of device is riveted to motor core pressure is related to a motor core pressure.

Background

The motor stator core or the rotor core is formed by stacking sheet-shaped silicon steel sheets, and in order to ensure that the silicon steel sheets are tightly matched and are not loose, a plurality of rivets are required to be further penetrated after the silicon steel sheets are pressed into a block.

The equipment of present suppression rivet is like the automatic squeeze riveter of two stations of a motor stator core that chinese patent storehouse disclosed [ application number: 201510912410.8, including the workstation, workstation top fixedly connected with goes up the mould mounting panel, still includes the rotary table board, and rotary table board center below is connected with rotary mechanism, and the rotary table board both ends are pressing portion and material returned portion respectively, and pressing portion is located and goes up the mould mounting panel under, and pressing portion below corresponds the material cylinder that presses, and material returned portion below is connected with the material cylinder that returns.

In the riveting press, the rivet is pressed in only by pressing the rivet through the cylinder, and the pressing precision and the quality are poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims at having the above-mentioned problem to current technique, provided a motor core presses beating mechanism of riveting device, the technical problem of solution is how to improve the quality of impressing.

The purpose of the utility model can be realized by the following technical proposal: the utility model provides a motor core presses beating mechanism of riveting device, including ejector pin, support and telescopic cylinder four, telescopic cylinder four includes the cylinder body and is piston rod four of vertical setting, and the cylinder body is fixed on the support, and the lower extreme and the ejector pin of piston rod four link firmly, its characterized in that, the vertical sleeve that is fixed with on the cylinder body, the upper end of piston rod four stretches out the cylinder body and is located the sleeve, the sleeve in slide and be provided with the balancing weight and make the balancing weight have the spring two of downward motion trend, the balancing weight is directly over piston rod four, has on the sleeve along the radial connecting hole that runs through of this sleeve, is equipped with the supporting shoe in the connecting hole, the sleeve external fixation have make the supporting shoe can follow the radial driving piece three of reciprocal translation of sleeve, and under driving piece three effects, the supporting.

In the initial state, the supporting block supports against the balancing weight to keep the second spring in a compressed state; when the piston rod IV moves downwards, the supporting block is far away from the balancing weight under the action of the driving piece III, and at the moment, the balancing weight moves downwards rapidly under the action of the spring II and strikes the piston rod IV to increase a striking force on the piston rod IV, so that the piston rod IV moves downwards more powerfully to stably press the rivet into the iron core; after the rivet is pressed in, the piston rod moves upwards to drive the balancing weight to move upwards for resetting.

In the hammering mechanism of the motor iron core pressure riveting device, at least two connecting holes are uniformly distributed along the circumferential direction of the sleeve, and the supporting block, the driving piece III and the connecting holes are identical in number and are in one-to-one correspondence in position so as to better support the balancing weight.

In the beating mechanism of the motor core pressure riveting device, the side wall of one end, close to the inner cavity of the sleeve, of the supporting block is a third conical surface, the diameter of the third conical surface is gradually increased from the inside of the sleeve to the outside of the sleeve, a fourth conical surface matched with the third conical surface is arranged on the side wall of the lower end of the balancing weight, the fourth conical surface extends to the bottom wall of the balancing weight, and the fourth conical surface can be abutted against the third conical surface. When the supporting block continuously extends into the sleeve under the action of the driving part III, the balancing weight can overcome the elasticity of the spring II to rise under the matching of the conical surface III and the conical surface IV, so that the balancing weight obtains higher descending speed and acts on the piston rod IV to further improve the quality and the stability of the pressure rivet.

In the hammering mechanism of the motor iron core pressure riveting device, the diameter of the piston rod four is smaller than the inner diameter of the sleeve, and a plurality of silencing holes are formed in the side wall of the lower end of the sleeve in a penetrating mode. The silencing hole is used for discharging noise generated by knocking the counterweight block on the piston rod IV.

In the hammering mechanism of the motor core pressure riveting device, the top wall of the balancing weight is provided with a blind hole arranged in the vertical direction, the second spring is vertically arranged in the blind hole, and the lower end and the upper end of the second spring are respectively abutted against the bottom wall of the blind hole and the inner wall of the sleeve.

In the hammering mechanism of the motor core pressure riveting device, the driving piece III is a telescopic cylinder V, and a piston rod of the telescopic cylinder V is fixedly connected with the supporting block.

As another scheme, in the hammering mechanism of the motor iron core pressure riveting device, the driving member three is a telescopic oil cylinder, and a piston rod of the telescopic oil cylinder is fixedly connected with the supporting block.

Compared with the prior art, this device is riveted to motor core pressure's beating mechanism has following advantage:

1. and a counterweight block driven by a second spring is arranged above a fourth piston rod of the telescopic cylinder, and when the fourth piston rod moves downwards, the counterweight block can rapidly move downwards under the action of the second spring and beat on the fourth piston rod so as to increase a beating force on the fourth piston rod, so that the fourth piston rod moves downwards more powerfully to stably press the rivet into the iron core, and the processing quality is further improved.

2. Under the matching of the third conical surface and the fourth conical surface, the counterweight block can overcome the elastic force of the second spring to rise, so that the counterweight block obtains higher descending speed and acts on the fourth piston rod, and the quality and the stability of the pressure rivet are further improved.

Drawings

Fig. 1 is a schematic perspective view of the motor core press-riveting device.

Fig. 2 is a schematic perspective view of the conveying mechanism with the cam divider removed.

Fig. 3 is a schematic sectional structure diagram of the conveying mechanism.

Fig. 4 is a schematic view of a connection structure of the positioning die and the top case.

Fig. 5 is a perspective view of the press-fitting mechanism.

Fig. 6 is a schematic sectional view of the press-fitting structure.

Fig. 7 is an enlarged schematic view of a structure at a in fig. 6.

Fig. 8 is a schematic view of the position structure of the clamping block and the pushing block.

Fig. 9 is a schematic view of a connection structure of the rolling member and the guide shoe.

Fig. 10 is a schematic cross-sectional view of the hammering mechanism with the ejector pin removed.

Fig. 11 is an enlarged schematic view of B in fig. 10.

In the figure, 1, iron core; 2. a frame; 3. a first motor; 4. a turntable; 4a, riveting and pressing stations; 4b, ejecting the material; 4c, a material placing station; 5. positioning the mold; 5a, a supporting surface; 5b, a linkage rod; 5c, an annular shoulder; 6. jacking and sleeving; 6a, a baffle ring; 6a1, annular face; 7. a connecting ring; 8. a holder; 9. a roller; 10. a second motor; 11. a weight plate; 11a, a yielding hole; 12. a connecting rod; 13. a first driving part; 13a, a telescopic cylinder I; 13b, pressing a sleeve; 14. a support; 15. a clamping block; 16. a single-acting cylinder I; 17. a top rod; 17a and a first conical surface; 18. a trough; 19. a linear vibrator; 20. a stopper; 20a, a blocking part; 21. a push block; 21a, a wedge face; 22. a telescopic cylinder III; 23. an elastic block; 24. a telescopic cylinder IV; 24a and a piston rod IV; 25. a sleeve; 25a, sound deadening holes; 26. a balancing weight; 26a and a conical surface four; 27. a second spring; 28. a support block; 28a and a conical surface III; 29. a driving member III; 30. a guide block; 30a, a bevel; 31. a through hole; 31a and a taper hole II; 32. a connecting frame; 33. a second single-acting cylinder; 34. a rolling member; 35. a rotating shaft; 36. a first spring; 37. riveting; 38. a strip-shaped hole; 38a, an opening; 38b and a first taper hole.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

Example one

As shown in fig. 1, the motor core press-riveting apparatus is generally composed of a conveying mechanism for conveying the core 1 and a press-fitting mechanism for press-fitting the rivet 37 into the core 1.

Wherein the content of the first and second substances,

the conveying mechanism comprises a driving mechanism, a frame 2, a first motor 3 fixedly arranged on the frame 2 and a turntable 4 horizontally arranged on the frame 2 and driven by the first motor 3 to rotate. Riveting station 4a, liftout station 4b and blowing station 4c are equipped with the equipartition in proper order on carousel 4, and wherein, riveting station 4a one side is equipped with the mechanism of impressing that is used for impressing rivet 37 into iron core 1, all is equipped with on riveting station 4a, liftout station 4b and the blowing station 4c with carousel 4 rotation connection's positioning die 5. In the embodiment, the first motor 3 is connected with the rotary plate 4 through a cam divider, so that the rotary plate 4 rotates at an angle of 120 degrees.

As shown in fig. 3 and 4, the positioning die 5 is provided with a supporting surface 5a for horizontally supporting the iron core 1, the supporting surface 5a is provided with linkage rods 5b which are vertically arranged and have shapes and sizes matched with the wire slots of the iron core 1, at least two linkage rods 5b are uniformly distributed along the circumferential direction of the iron core 1, and the linkage rods 5b can be slidably arranged in the wire slots of the iron core 1. The linkage rod 5b plays a linkage role, so that the iron core 1 rotates along with the positioning die 5. In the present embodiment, the number of the linkage rods 5b is preferably 3. Each positioning die 5 is sleeved with a top sleeve 6, and the top sleeve 6 is provided with an annular surface 6a1 opposite to the bottom wall of the iron core 1.

In the present embodiment, the connection mode of the turntable 4 and the positioning die 5 is specifically as follows: all be equipped with go-between 7 between every positioning die 5 and carousel 4, and go-between 7 with correspond 6 coaxial arrangements of top cover, go-between 7 links firmly with carousel 4, and positioning die 5 rotates through bearing and go-between 7 to be connected. Further, an annular cavity is formed between the positioning die 5 and the connecting ring 7, the annular cavity is located between the bearing and the top sleeve 6, an annular retainer 8 is arranged in the annular cavity, a plurality of rolling grooves are uniformly distributed along the circumferential direction of the retainer 8 on the retainer 8, rollers 9 are arranged in the rolling grooves, and two sides of each roller 9 are respectively pressed on the positioning die 5 and the connecting ring 7 so as to ensure the rotating stability of the positioning die 5.

As shown in fig. 2, a second motor 10 for driving the positioning die 5 to rotate along the circumferential direction of the iron core 1 is fixed on the lower side of the turntable 4, and the second motor 10 and the positioning die 5 have the same number and are in one-to-one correspondence in position. Preferably, the second motor 10 is connected with the positioning die 5 through a coupler.

The driving mechanism can drive the ejection sleeve 6 positioned at the ejection station 4b to move up and down, and the iron core 1 can be ejected when the ejection sleeve 6 moves up. Specifically, as shown in fig. 2 and 3, the driving mechanism includes a weight plate 11 horizontally disposed on the lower side of the turntable 4 and a limit structure for limiting the downward movement position of the top sleeve 6. The weight plates 11 and the top sleeves 6 are the same in number and correspond to each other in position. A connecting rod 12 is vertically arranged between the counterweight plate 11 and the top sleeve 6, and the lower end of the connecting rod 12 is fixedly connected with the counterweight plate 11. The upper end of the connecting rod 12 penetrates through the rotary table 4 and is fixedly connected with the top sleeve 6, and at least two connecting rods 12 distributed along the circumferential direction of the top sleeve 6 are arranged on the same top sleeve 6. Preferably, the number of the connecting rods 12 on the same top sleeve 6 is 4. The frame 2 is also provided with a driving part one 13, and each balance weight plate 11 can rotate to the driving part one 13 and is jacked up by the driving part one 13 under the driving of the turntable 4. The limiting structure comprises a blocking ring 6a integrally formed on the inner wall of the top sleeve 6 and an annular convex shoulder 5c integrally formed on the outer wall of the positioning die 5, the annular convex shoulder 5c, the blocking ring 6a and the iron core 1 are coaxially arranged, the annular convex shoulder 5c is located between the blocking ring 6a and the rotary table 4, and the bottom wall of the blocking ring 6a abuts against the top wall of the annular convex shoulder 5c to limit the top sleeve 6 to move downwards. The top wall of the baffle ring 6a is the annular surface 6a 1.

Further, the second motor 10 is vertically arranged, and a main shaft of the second motor 10 and the top sleeve 6 are coaxially arranged. The counterweight plate 11 is provided with a abdication hole 11a for the lower end of the second motor 10 to pass through, so that the distance among the counterweight plate 11, the rotary table 4 and the motor can be reduced, and the whole structure becomes compact. The first driving part 13 comprises a first telescopic cylinder 13a and a pressing sleeve 13b fixedly connected with a piston rod of the first telescopic cylinder 13a, the inner diameter of the pressing sleeve 13b is larger than the size of the lower end of the second motor 10, and under the action of the first telescopic cylinder 13a, the top wall of the pressing sleeve 13b can be pressed on the bottom wall of the counterweight plate 11. Naturally, the first driving member 13 may also be an electric push rod, and a main shaft of the electric push rod may abut against the bottom wall of the counterweight plate 11.

The working process of the conveying mechanism is as follows: in the emptying station 4c, the iron core 1 is horizontally placed on the supporting surface 5a, and the linkage rod 5b is inserted into the wire slot of the iron core 1; the first motor 3 drives the rotary table 4 to rotate so that the positioning die 5 at the discharging station 4c is shifted to the riveting station 4a, when one rivet 37 is pressed, the second motor 10 drives the positioning die 5 to rotate and drives the iron core 1 to rotate for a certain angle through the linkage rod 5b and then stops, then one rivet 37 is pressed into the iron core 1, and the process is circularly carried out so that a plurality of rivets 37 are pressed into one iron core 1; after the riveting is finished, the rotary table 4 rotates to enable the iron core 1 subjected to riveting to be transferred to the material ejecting station 4b, the first telescopic cylinder 13a drives the pressing sleeve 13b to eject the counterweight plate 11 to move upwards, and the annular surface 6a1 is in contact with the bottom wall of the iron core 1 under the matching of the connecting rod 12 and the ejecting sleeve 6 to eject the iron core 1; after the iron core 1 is taken down, the first telescopic cylinder 13a drives the pressing sleeve 13b to reset, and the top sleeve 6 resets under the action of the counterweight plate 11 and self gravity. The three stations of the riveting station 4a, the ejection station 4b and the discharge station 4c are operated in sequence and circularly, so that the riveting process is continuously carried out.

As shown in fig. 1, 5, 6, 7 and 8, a press-in mechanism is arranged at one side of the riveting station 4a, and the press-in mechanism comprises a bracket 14, a hammering mechanism, two clamping blocks 15 arranged in parallel and a single-acting cylinder 16 for respectively driving the two clamping blocks 15 to approach each other, and in the embodiment, the two clamping blocks 15 approach each other until being pressed together, and naturally, the two clamping blocks 15 do not press together. Two clamp splice 15 form when being close to and are the vertical direction through-going bar hole 38, this side opening 38a of riveting station 4a is kept away from to bar hole 38, bar hole 38 upper end is the downward taper hole 38b that diminishes in aperture, be equipped with on the support 14 can send into the feeding mechanism of bar hole 38 with rivet 37 pole portion through above-mentioned opening 38a, and rivet 37 head moves down under the action of gravity and presses on the hole wall of taper hole 38b, above-mentioned beat the mechanism and include vertical ejector pin 17 of locating directly over taper hole 38b and be used for driving piece two that ejector pin 17 reciprocated.

As shown in fig. 6 and 7, the feeding mechanism includes a strip-shaped trough 18 disposed on one side of the opening 38a, the trough 18 is disposed horizontally, the notch of the trough 18 faces upward, and the trough 18 is mounted on the bracket 14 through the linear vibrator 19. The trough 18 is slidably engaged with the rivet 37, and the inlet and the outlet are respectively provided at two ends of the trough 18, and the outlet is disposed opposite to the opening 38 a. When the rivet 37 is used, the rod part of the rivet 37 is positioned in the trough 18, the head part of the rivet 37 is pressed against the edge of the notch of the trough 18, and the rivet 37 moves from the inlet to the outlet under the action of the linear vibrator 19. A stopper 20 capable of restricting the outward discharge of the rivet 37 is fixed to the outlet, and the stopper 20 is made of an elastic material. The elastic material may be plastic, rubber or silicone. In the present embodiment, the stopper 20 is preferably made of a plastic material. The single-acting cylinder I16 is connected with the material groove 18 through the base, the material groove 18 is further provided with a material pushing mechanism which can enable the rivet 37 at the outlet to overcome the elasticity of the stop block 20 to be discharged and to be sent into the strip-shaped hole 38 through the opening 38a, and the material pushing mechanism is located between the material groove 18 and the clamping block 15.

In this embodiment, as shown in fig. 7 and 8, the pushing mechanism includes two pushing blocks 21 respectively disposed at two sides of the outlet, and a third telescopic cylinder 22 respectively driving the two pushing blocks 21 to approach or separate from each other. Wherein, the third telescopic cylinder 22 is fixed on the trough 18 through a base; the two push blocks 21 are distributed along the horizontal direction, and the distribution direction of the two push blocks 21 is vertical to the length extension direction of the trough 18; the two push blocks 21 are respectively provided with a wedge-shaped surface 21a matched with the rod part of the rivet 37, and when the two push blocks 21 are close to each other, the wedge-shaped surfaces 21a can be contacted with the side wall of the rod part of the rivet 37. Further optimized, one of the pushing blocks 21 is provided with two wedge-shaped surfaces 21 a; the other pushing block 21 has a wedge surface 21a, and the wedge surface 21a is located at the middle position of the two wedge surfaces 21a on the same pushing block 21 to push out the rivet 37 more stably.

As shown in fig. 6 and 7, the stopper 20 includes a stopper 20a in a block shape and vertically arranged, and the head of the rivet 37 can abut against the stopper 20 a; the trough 18 is also fixed with an elastic block 23 right below the stop part 20a, and the elastic block 23 is made of elastic material. The elastic material may be plastic, rubber or silicone. In the present embodiment, the elastic block 23 is preferably made of a plastic material. Two elastic blocks 23 are arranged in parallel along the width direction of the trough 18, and the two elastic blocks 23 can be abutted against the rod part of the rivet 37. The stop 20 and the elastic block 23 are respectively arranged to block the head of the rivet 37 and the rod of the rivet 37, so that the rivet 37 is kept in a vertical state, and the pushing process is ensured to be stably carried out.

As shown in fig. 10 and 11, the second driving member includes a fourth telescopic cylinder 24, and the fourth telescopic cylinder 24 includes a cylinder body and a vertically arranged piston rod four 24 a. Wherein, the cylinder body is fixed on the bracket 14; a sleeve 25 is vertically fixed on the cylinder body, and the upper end of the piston rod four 24a extends out of the cylinder body and is positioned in the sleeve 25. A weight 26 is slidably disposed in the sleeve 25 so that the weight 26 can slide up and down. In this embodiment, the side wall of the weight 26 and the inner side wall of the sleeve 25 are circumferential surfaces matching with each other and the two are attached together, so as to ensure the stability of the sliding of the weight 26. A second spring 27 which enables the counterweight block 26 to have a downward movement trend is further arranged between the counterweight block 26 and the sleeve 25, the counterweight block 26 is positioned right above the piston rod four 24a, a connecting hole which penetrates through the sleeve 25 along the radial direction is formed in the sleeve 25, a supporting block 28 is arranged in the connecting hole, a third driving part 29 which enables the supporting block 28 to translate along the sleeve 25 in a reciprocating manner along the radial direction is fixed outside the sleeve 25, and under the action of the third driving part 29, the supporting block 28 can extend into the sleeve 25 and support the counterweight block 26.

The second spring 27 is arranged as follows: set up the blind hole that sets up along vertical direction on the balancing weight 26 roof, in the blind hole was vertically located to spring two 27, and spring two 27 lower extreme and upper end offset with blind hole diapire and sleeve 25 inner wall respectively.

Further, at least two connecting holes are uniformly distributed along the circumferential direction of the sleeve 25, and the supporting blocks 28, the driving pieces three 29 and the connecting holes are the same in number and are in one-to-one correspondence in position. In this embodiment, the number of the connection holes is preferably 2, that is, the number of the support block 28, the driving member three 29 and the connection holes is 2.

Furthermore, as shown in fig. 11, the side wall of the supporting block 28 near the end of the inner cavity of the sleeve 25 is a tapered surface three 28a, and the diameter of the tapered surface three 28a gradually increases from the inside of the sleeve 25 to the outside of the sleeve 25. The side wall of the lower end of the balancing weight 26 is provided with a conical surface four 26a matched with the conical surface three 28a, the conical surface four 26a extends to the bottom wall of the balancing weight 26, and the conical surface four 26a can be pressed against the conical surface three 28 a. When the supporting block 28 continuously extends into the sleeve 25 under the action of the driving member iii 29, the weight 26 can be lifted up against the elastic force of the spring ii 27 under the cooperation of the conical surface iii 28a and the conical surface iv 26a, so that the weight 26 can obtain a larger descending speed and act on the piston rod iv 24a, thereby further improving the quality and stability of the pressure rivet 37. In this embodiment, it is preferable that the driving member three 29 is a telescopic cylinder five, and a piston rod of the telescopic cylinder five is fixedly connected to the supporting block 28. Naturally, the technical scheme that the driving part III 29 is a telescopic oil cylinder, and a piston rod of the telescopic oil cylinder is fixedly connected with the supporting block 28 is adopted.

As shown in fig. 5 and 10, the diameter of the piston rod assembly 24a is smaller than the inner diameter of the sleeve 25, and a plurality of noise-reducing holes 25a are formed through the sidewall of the lower end of the sleeve 25 for discharging noise generated when the weight 26 strikes the piston rod assembly 24 a.

Further, as shown in fig. 5 and 6, two guide blocks 30 are disposed under the clamping block 15, and a power mechanism is disposed on the bracket 14 for enabling the two guide blocks 30 to approach each other, and when the two guide blocks 30 approach each other, a through hole 31 is formed to vertically penetrate through the through hole and directly face the strip-shaped hole 38. As shown in fig. 6 and 7, the middle of the through hole 31 is a second taper hole 31a with a diameter gradually decreasing downwards, the diameters of the upper end and the lower end of the through hole 31 are respectively the same as the maximum diameter and the minimum diameter of the second taper hole 31a, and the shape and the size of the lower end of the through hole 31 are matched with the rod part of the rivet 37. The side wall of the lower end of the ejector rod 17 is provided with a first conical surface 17a matched with the second conical hole 31a, and the first conical surface 17a can be contacted with the hole wall of the second conical hole 31a and enables the two guide blocks 30 to be far away from each other by overcoming the action of a power mechanism.

As shown in fig. 5 and 9, the specific structure of the power mechanism is as follows: the two guide blocks 30 are distributed along the width direction of the trough 18, the power mechanism comprises a connecting frame 32, a single-acting cylinder II 33 and rolling pieces 34, wherein the connecting frame 32 and the guide blocks 30 are distributed along the length direction of the trough 18, one end, close to the connecting frame 32, of each guide block 30 is rotatably connected with the support 14 through a same rotating shaft 35, two rolling pieces 34 are arranged on one side of each guide block 30 respectively, the two guide blocks 30 are located between the two rolling pieces 34 respectively, the two rolling pieces 34 are rotatably connected with the connecting frame 32, the axes of the rolling pieces 34 are vertically arranged, the outer side walls of the rolling pieces 34 are circumferential surfaces, inclined surfaces 30a in contact with the circumferential surfaces are arranged on the guide blocks 30, the single-acting cylinder II 33 is used for driving the connecting frame 32 to translate towards the guide blocks 30, and the circumferential surfaces can press the inclined surfaces 30a to roll to enable the two guide blocks 30 to rotate around the rotating shafts 35 and to be close to each other.

In this embodiment, the rolling elements 34 are bearings, the inner ring of the bearing is rotatably connected to the bracket 14 by a first pin, and the outer side wall of the outer ring of the bearing is the circumferential surface. Naturally, the rolling member 34 may also be a roller in a cylindrical shape, and the roller is rotatably connected to the bracket 14 through the second pin.

To explain further, as shown in fig. 6, a first spring 36 is provided between the guide shoes 30 to drive the guide shoes 30 to rotate around the rotation shaft 35 and to move away from each other. When the rivet pressing device is used specifically, the two guide blocks 30 are close to each other under the action of the single-acting air cylinder II 33 and overcome the elastic force of the spring I36, and the spring I36 is adopted, so that the through hole 31 can be more easily opened by the ejector rod 17, the rivet pressing 37 can normally work, the two guide blocks 30 can be automatically opened under the action of no stress, and the through hole 31 is convenient to clean. In the present embodiment, the first spring 36 is installed as follows: the inner sides of the two guide blocks 30 are provided with mounting holes which are blind holes, two ends of the first spring 36 are respectively positioned in the two mounting holes, and two ends of the first spring 36 are respectively pressed against the bottom walls of the two mounting holes.

The working process of the press-in mechanism is as follows: the rivet 37 is input from the inlet, at the moment, the rod part of the rivet 37 is positioned in the trough 18, the head part of the rivet 37 is pressed against the edge of the notch of the trough 18, moves towards the outlet direction under the action of the linear vibrator 19 and is blocked by the stop block 20 and the elastic block 23; then the telescopic cylinder III 22 pushes the two push blocks 21 to approach each other, so that the wedge-shaped surface 21a is contacted with the side wall of the rod part of the rivet 37, the rivet 37 overcomes the elasticity of the stop block 20 and the elastic block 23 to be discharged and is sent into the strip-shaped hole 38 through the opening 38a, at the moment, the rivet 37 moves downwards under the action of gravity, so that the head of the rivet is pressed against the hole wall of the first taper hole 38b for limiting, and the stop block 20 and the elastic block 23 reset under the action of the elasticity to block the next rivet 37 to be discharged; then, the four telescopic cylinders 24 work to enable the four piston rods 24a to move downwards, the supporting blocks 28 are far away from the counterweight blocks 26 under the action of the five telescopic cylinders, and at the moment, the counterweight blocks 26 move downwards rapidly and are knocked on the four piston rods 24a under the action of the second springs 27, so that knocking force is increased on the four piston rods 24 a; the piston rod four 24a drives the ejector rod 17 to move downwards to press the head of the rivet 37 to enable the rivet 37 to move downwards quickly, the rivet 37 can be matched with the hole wall of the first conical hole 38b to open the strip-shaped hole 38 when moving downwards to ensure that the rivet 37 moves downwards smoothly, then the rivet 37 enters the through hole 31 formed by the two guide blocks 30, the lower end of the through hole 31 plays a role in guiding the rivet 37 to be pressed into the iron core 1, and the rivet 37 is pressed into the iron core 1 accurately, wherein when the ejector rod 17 moves downwards to enable the first conical surface 17a to be in contact with the second conical hole 31a, the two guide blocks 30 can be separated from each other to enable the through hole 31 to be opened to enable the head of the rivet 37 to move downwards smoothly, and one-time operation.

In the actual product, a vibration disc (not shown) is arranged on one side of the material groove 18 and is connected with the inlet of the material groove 18 through a material rail (not shown) to realize automatic feeding of the rivets 37.

Example two

The second embodiment is basically the same as the first embodiment in structure and principle, and the difference lies in: the driving mechanism comprises two telescopic cylinders and a connecting frame 32, wherein the two telescopic cylinders are arranged on the lower side of the turntable 4, the connecting frame 32 is in a concave shape, the number of the two telescopic cylinders and the number of the connecting frame 32 are the same as that of the top sleeve 6, the two piston rods of the telescopic cylinders are in one-to-one correspondence with the middle of the connecting frame 32, and the two ends of the connecting frame 32 penetrate through the turntable 4 and are fixedly connected with the corresponding top sleeve 6.

EXAMPLE III

The structure and principle of the third embodiment are basically the same as those of the first embodiment, and the differences are that: the limit structure comprises a top sleeve 6 bottom wall and a rotary table 4 top wall, and the top sleeve 6 bottom wall is pressed on the rotary table 4 top wall.

Example four

The structure and principle of the fourth embodiment are basically the same as those of the first embodiment, and the difference lies in that: the pushing mechanism is a pneumatic finger capable of clamping the rod part of the rivet 37.

EXAMPLE five

The structure and principle of the fifth embodiment are basically the same as those of the first embodiment, and the difference lies in: the power mechanism comprises two single-acting cylinders III distributed along the width direction of the trough 18, and the two single-acting cylinders III are fixedly connected with the two guide blocks 30 respectively.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (7)

1. A hammering mechanism of a motor iron core press riveting device comprises a mandril (17), a support (14) and a four telescopic cylinder (24), wherein the four telescopic cylinder (24) comprises a cylinder body and a four piston rod (24a) which is vertically arranged, the cylinder body is fixed on the support (14), the lower end of the four piston rod (24a) is fixedly connected with the mandril (17), the hammer is characterized in that a sleeve (25) is vertically fixed on the cylinder body, the upper end of the four piston rod (24a) extends out of the cylinder body and is positioned in the sleeve (25), a counterweight block (26) and a second spring (27) which enables the counterweight block (26) to have a downward movement trend are arranged in the sleeve (25) in a sliding manner, the counterweight block (26) is positioned right above the four piston rod (24a), a connecting hole which radially penetrates through the sleeve (25) is arranged on the sleeve (25), a supporting block (28) is arranged in the connecting hole, a third driving piece (29) which enables the supporting block (28) to, and under the action of the driving part III (29), the supporting block (28) can extend into the sleeve (25) and support the balancing weight (26).

2. The hammering mechanism of the motor iron core rivet pressing device according to claim 1, characterized in that at least two connecting holes are uniformly distributed along the circumference of the sleeve (25), and the supporting block (28), the driving piece three (29) and the connecting holes have the same number and are in one-to-one correspondence.

3. The hammering mechanism of the iron core rivet pressing device of the motor according to claim 2, characterized in that the side wall of one end of the supporting block (28) close to the inner cavity of the sleeve (25) is a conical surface three (28a), the diameter of the conical surface three (28a) is gradually increased from the inside of the sleeve (25) to the outside of the sleeve (25), the side wall of the lower end of the counterweight (26) is provided with a conical surface four (26a) matched with the conical surface three (28a), the conical surface four (26a) extends to the bottom wall of the counterweight (26), and the conical surface four (26a) can press against the conical surface three (28 a).

4. The hammering mechanism of the motor iron core rivet pressing device according to claim 1, 2 or 3, characterized in that the diameter of the piston rod four (24a) is smaller than the inner diameter of the sleeve (25), and a plurality of silencing holes (25a) are arranged on the side wall of the lower end of the sleeve (25) in a penetrating way.

5. The hammering mechanism of the iron core rivet pressing device for the motor according to claim 1, 2 or 3, characterized in that the top wall of the counterweight block (26) is provided with a blind hole arranged along the vertical direction, the second spring (27) is vertically arranged in the blind hole, and the lower end and the upper end of the second spring (27) respectively abut against the bottom wall of the blind hole and the inner wall of the sleeve (25).

6. The hammering mechanism of the iron core rivet pressing device of the motor according to claim 1, wherein the driving member three (29) is a telescopic cylinder five, and a piston rod of the telescopic cylinder five is fixedly connected with the supporting block (28).

7. The hammering mechanism of the iron core rivet pressing device for the motor according to claim 1, wherein the driving member III (29) is a telescopic cylinder, and a piston rod of the telescopic cylinder is fixedly connected with the supporting block (28).

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