CN214417033U - Directional conveyor of socket upper cover - Google Patents

Abstract

The application relates to the field of assembly part conveying technology, in particular to a socket upper cover directional conveying device. The socket cover conveying device comprises a conveying belt which is used for conveying a socket upper cover and is obliquely arranged, a feeding station and a screening station are sequentially arranged on the conveying belt along the conveying direction of the conveying belt, a feeding baffle is arranged at the lower end of the conveying belt, and the feeding baffle is positioned at the feeding station on the conveying belt; the screening station comprises a poke rod shaft arranged on the conveying belt, a poke sheet which is rotationally connected with the poke rod shaft and can penetrate through the first gap or the second gap, a sensing piece which is connected with the poke sheet in a matching way, and an air pipe controlled by the sensing piece, wherein a first interval for the bottom plate of the socket upper cover to penetrate through is formed between the poke sheet and the conveying belt; when the bottom plate of the upper socket cover is abutted to the shifting sheet, the bottom plate of the upper socket cover drives the shifting sheet to rotate around the circumferential direction of the shifting rod shaft, and then the induction piece is triggered to control the air pipe to work so as to blow the upper socket cover away from the conveying belt. This application has the effect of the waste of reducing the manpower.

Description

Directional conveyor of socket upper cover

Technical Field

The application relates to the field of assembly part conveying technology, in particular to a socket upper cover directional conveying device.

Background

The socket, also called a power socket and a switch socket, mainly comprises a socket upper cover and a socket lower cover, wherein in actual production, the socket upper cover and the socket lower cover are usually produced separately, and then the socket upper cover and the socket lower cover are assembled.

Referring to fig. 1, a schematic structural diagram of an upper cover of a socket in the related art mainly includes a bottom plate 1 and four connecting pins 2 uniformly spaced from and disposed on two sides of the bottom plate 1, specifically, two connecting pins 2 are disposed on two sides of the bottom plate 1 on which the connecting pins 2 are disposed respectively, a first gap 3 is formed between the two connecting pins 2 disposed on the same side, a second gap 4 is formed between the two connecting pins 2 disposed on different sides, and generally, the connecting pins 2 and the bottom plate 1 are formed in an integrated manner.

In view of the above-mentioned related art, the inventor believes that, in actual production, workers often stack injection-molded upper socket covers at will, so that before the upper socket cover is assembled on a production line, the upper socket cover needs to be manually adjusted to a state that the connecting pins are below the upper base plate, and there is a defect that the assembly operation of the upper socket cover is complicated.

SUMMERY OF THE UTILITY MODEL

In order to adjust the socket upper cover to the state that the connecting pins are under the upper base plate, the application provides a socket upper cover directional conveying device.

The application provides a directional conveyor of socket upper cover adopts following technical scheme:

a socket upper cover directional conveying device comprises a conveying belt which is used for conveying socket upper covers and is obliquely arranged, wherein a feeding station, a screening station and a discharging station are sequentially arranged on the conveying belt along the conveying direction of the conveying belt, a feeding baffle is arranged at the lower end of the conveying belt, and the feeding baffle is positioned at the feeding station on the conveying belt; the screening station comprises a poke rod shaft arranged on the conveying belt, a poke sheet which is rotationally connected with the poke rod shaft and can penetrate through a first gap or a second gap, an induction piece which is connected with the poke sheet in a matched mode, and an air pipe controlled by the induction piece, wherein a first interval for a bottom plate of the socket upper cover to penetrate through is formed between the poke sheet and the conveying belt; when the bottom plate of the upper socket cover is abutted to the shifting sheet, the bottom plate of the upper socket cover drives the shifting sheet to rotate around the circumferential direction of the shifting rod shaft, and then the induction piece is triggered to control the air pipe to work so as to blow the upper socket cover away from the conveying belt.

Through adopting above-mentioned technical scheme, when the connecting leg of socket upper cover and conveyer butt, and during the bottom plate of socket upper cover and plectrum butt, the bottom plate drives the plectrum and winds the rotation of plectrum axle circumference, and then triggers the response piece and blows off conveyer with socket upper cover with control trachea work. And when the bottom plate of socket upper cover and conveyer butt, the first interval that the bottom plate of socket upper cover formed from between plectrum and the conveyer passes through, and the screening station standby. And then can realize that the screening station is automatic to be screened the socket upper cover, when reducing the degree of difficulty to the assembly operation of socket upper cover, still improved the efficiency of screening. In addition, with conveyer to the one side downward sloping that is close to reinforced baffle gradually for the socket upper cover slides to conveyer is close to one side of reinforced baffle under the effect of gravity, and then makes the socket upper cover get into the screening station, and the baffle plays the effect that the restriction socket upper cover removed, reduces the possibility that the socket upper cover breaks away from the conveyer belt.

Optionally, the feeding mechanism is used for being connected with a feeding station on the conveying belt, the feeding mechanism comprises a storage bin and a lifting belt, a discharging end of the lifting belt is connected with a discharging station of the conveying belt, and the other end of the lifting belt extends into the storage bin; be provided with a plurality of location strips that set up perpendicular with promotion belt direction of transfer on the conveyer belt of promotion belt, the promotion belt is arranged in carrying the socket upper cover in the feed bin to reinforced station.

Through adopting above-mentioned technical scheme, promote the belt and shift the socket upper cover to reinforced station by the feed bin, owing to be provided with on the promotion belt a plurality ofly and promote the perpendicular location strip that sets up of belt direction of transfer for the location strip can restrict the removal of socket upper cover, improves the efficiency that promotes the subassembly and shift the socket upper cover.

Optionally, the socket cover further comprises a guide station arranged on the conveying belt and located between the screening station and the feeding station, the guide station comprises a guide plate arranged above the conveying belt, the guide plate gradually approaches to the side provided with the feeding baffle along the conveying direction of the conveying belt, and a channel for the socket cover to pass through is formed between the guide plate and the feeding baffle; when the bottom plate of the socket upper cover is abutted against the guide plate, the conveying belt drives the socket upper cover to slide towards the direction close to the feeding baffle plate.

Through adopting above-mentioned technical scheme, shift the in-process of screening station by reinforced station with the socket upper cover at the promotion belt, the bottom plate of socket upper cover at first with the deflector butt, because the deflector is close to the baffle gradually along conveyer's direction of transfer, make the deflector give the power of a direction of socket upper cover steadily and smoothly, under the synergism of gravity and guiding force, order about the socket upper cover and slide and get into the screening station to the direction that is close to the baffle, reduce the possibility that the deflector blockked the socket upper cover, improve the screening rate of accuracy of screening station to the socket upper cover.

Optionally, the deflector includes the mounting panel and sets up the row brush in the mounting panel near one side of conveyer, the row brush is used for the bottom plate butt with the socket upper cover.

Through adopting above-mentioned technical scheme, shift the in-process of screening station with the socket upper cover by reinforced station at the promotion belt, be provided with row brush in one side that the mounting panel is close to conveyer for the bottom plate of socket upper cover carries out soft butt with row brush, reduces the damage of direction station to the socket upper cover.

Optionally, the screening station further comprises a backflow channel arranged on the conveying belt, one end of the backflow channel is communicated with the bin, and one end of the backflow channel, which is far away from the bin, is opposite to one side, which is far away from the air pipe, of the conveying belt; the backflow channel is used for enabling the socket upper cover blown off the conveying belt through the air pipe to flow back into the storage bin.

Through adopting above-mentioned technical scheme, when the socket upper cover breaks away from conveyer under tracheal drive, return channel collects and shifts to the feed bin again the socket upper cover that breaks away from conveyer for can circulate reciprocal to the screening of socket upper cover, improve the screening efficiency to the socket upper cover.

Optionally, the conveying belt is further provided with an adjusting station, and the adjusting station is located between the screening station and the discharging station; the adjusting station comprises an adjusting piece arranged above the conveying belt, and a second space for the bottom plate of the socket upper cover to pass through is formed between the adjusting piece and the conveying belt; the conveying belt is provided with an adjusting baffle which is positioned at an adjusting station of the conveying belt, the adjusting part, the adjusting baffle and the feeding baffle are arranged on the same side of the conveying belt, the adjusting part is provided with a guide surface, and the guide surface gradually approaches to the other side of the conveying belt along the conveying direction of the conveying belt; when the connecting pins of the upper socket cover abut against the guide surface, the transmission belt drives the upper socket cover to rotate around the abutting points of the connecting pins and the guide surface in the circumferential direction.

Through adopting above-mentioned technical scheme, conveyer conveys the socket upper cover to the adjustment station by the screening station, because the adjusting part, adjustment baffle and reinforced baffle set up in conveyer's same one side, and the spigot surface is close to conveyer's opposite side gradually along conveyer's direction of transfer, make when the connection foot of socket upper cover and spigot surface butt, conveyer drive socket upper cover is around the butt point circumrotation of connecting foot and spigot surface, adjust the socket upper cover through the adjustment station is automatic, when reducing the waste of manpower, the efficiency of screening has still been improved.

Optionally, the adjusting station comprises an adjusting rod arranged above the conveying belt and a plurality of supporting plates for fixing the adjusting rod, and the supporting plates are arranged on one side of the conveying belt, where the adjusting baffle is arranged; the adjusting rod is provided with a plurality of positioning columns at even intervals along the length direction of the adjusting rod, and the positioning columns are in threaded connection with the supporting plate.

Through adopting above-mentioned technical scheme, because the adjusting lever is provided with a plurality of reference columns along its length direction even interval, and one side that conveyer was provided with adjustment baffle is provided with the backup pad of fixed adjusting lever, and backup pad and reference column threaded connection for the reference column can be adjusted the position of adjusting lever, makes the adjustment station can filter the socket upper cover of different models, improves the functional of screening station screening.

Optionally, the automatic feeding device further comprises a discharging mechanism arranged at one end of the conveying belt far away from the feeding station, wherein the discharging mechanism comprises a discharging plate and a plurality of limiting strips, an overturning channel for the bottom plate of the upper socket cover to penetrate and slide is formed between the discharging plate and the limiting strips, the feeding end of the overturning channel is connected with the discharging end of the conveying belt, and the bottom plate of the upper socket cover slides between the discharging plate and the limiting strips in a limiting manner; under the synergistic action of the discharging plate and the limiting strips, the upper cover of the socket is twisted from the state that the connecting pins are arranged below the upper base plate to the state that the connecting pins are arranged above the base plate.

By adopting the technical scheme, the discharging mechanism is arranged on one side, away from the lifting belt, of the conveying belt and comprises the discharging plate and the limiting strips, the overturning channel for the bottom plate of the upper socket cover to penetrate and slide is formed between the discharging plate and the limiting strips, under the synergistic action of the discharging plate and the limiting strips, the upper socket cover is twisted from the state that the connecting pins are arranged below the upper bottom plate to the state that the connecting pins are arranged above the bottom plate, the state of the upper socket cover is automatically adjusted through the synergistic action of the discharging plate and the limiting strips, and the screening efficiency is improved while the waste of manpower is reduced; in addition, the bottom plate of the upper socket cover slides between the discharge plate and the limiting strip in a limiting manner, the limiting strip and the discharge plate limit the upper socket cover to move, and the possibility that the upper socket cover is separated from a discharge station is reduced.

Optionally, the discharging mechanism further comprises a discharging rail which is arranged at one end of the discharging plate far away from the conveying belt and connected with the discharging plate, a discharging channel is arranged on the discharging rail, and one end of the discharging channel close to the conveying plate is communicated with one end of the overturning channel far away from the discharging station; the lower end face of the discharging rail is provided with a direct vibration machine used for driving the socket upper cover to slide through the discharging rail.

By adopting the technical scheme, the discharging rail is arranged at one end, away from the conveying belt, of the discharging plate and is connected with the discharging plate, and the direct vibration machine is arranged on the lower end face of the discharging rail, so that the direct vibration machine can continuously vibrate the discharging plate, the socket upper cover can be quickly twisted from a state that the connecting pins are arranged on the upper bottom plate to a state that the connecting pins are arranged on the upper bottom plate, and the discharging efficiency is improved; but also can drive the socket upper cover to slide rapidly through the discharging rail.

Optionally, the side wall of the storage bin is provided with a material taking door.

Through adopting above-mentioned technical scheme, when having the clout in the feed bin, can take out the convenient operation through getting the socket upper cover of bin gate in to the silo.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the connecting pin of the upper socket cover abuts against the conveyor belt and the bottom plate of the upper socket cover abuts against the shifting sheet, the bottom plate drives the shifting sheet to rotate circumferentially around the shifting rod shaft, and then the induction piece is triggered to control the air pipe to work so as to blow the upper socket cover off the conveyor belt. And when the bottom plate of socket upper cover and conveyer butt, the first interval that the bottom plate of socket upper cover formed from between plectrum and the conveyer passes through, and the screening station standby. And then can realize that the screening station is automatic to be screened the socket upper cover, when reducing the degree of difficulty to the assembly operation of socket upper cover, still improved the efficiency of screening. In addition, the conveying belt is gradually inclined downwards to one side close to the feeding baffle plate, so that the socket upper cover slides to one side, close to the feeding baffle plate, of the conveying belt under the action of gravity, the socket upper cover is further promoted to enter a screening station, the baffle plate plays a role in limiting the movement of the socket upper cover, and the possibility that the socket upper cover is separated from the conveying belt is reduced;

2. conveyer conveys the socket upper cover to the adjustment station by the screening station, because the adjusting part, adjustment baffle and reinforced baffle set up in conveyer's same one side, and the spigot surface is close to conveyer's opposite side gradually along conveyer's direction of transfer, make when the connection foot of socket upper cover and spigot surface butt, conveyer drive socket upper cover is around the butt point circumferencial rotation of connecting foot and spigot surface, adjust the socket upper cover through the adjustment station is automatic, when reducing the waste of manpower, the efficiency of screening has still been improved.

Drawings

Fig. 1 is a schematic structural view of a socket upper cover of the related art.

Fig. 2 is a schematic structural diagram of the socket cover screening by the socket cover directional conveying apparatus according to embodiment 1 of the present application.

Fig. 3 is a schematic view of the socket cover of fig. 2 in a loading station on a conveyor belt.

Fig. 4 is a schematic view of the socket cover of fig. 2 in a guide station on a conveyor belt.

Fig. 5 is a schematic view of the state of the socket cover shown in fig. 4 in a guide station on a conveyor belt, in which the socket cover of the dotted line is not guided by the guide station.

Fig. 6 is a schematic view of the socket cover in the first state of fig. 2 in a material sieving station on a conveyor belt.

Fig. 7 is a schematic view of the socket cover in the second state of fig. 2 in a material sieving station on a conveyor belt.

Fig. 8 is a schematic view of the socket cover in the third state of fig. 2 in a material sieving station on a conveyor belt.

Fig. 9 is a schematic view of the upper cover of the socket in a first state of screening by the screening station shown in fig. 2.

Fig. 10 is a schematic view of the socket cover in the third state shown in fig. 2 in the alignment station on the conveyor belt.

Fig. 11 is a schematic view of the socket cover in the second state shown in fig. 2 in the alignment station on the conveyor belt.

Fig. 12 is a schematic view of the upper cover of the alignment position adjustment socket shown in fig. 2.

Fig. 13 is a front view of the socket cover in the second state in the alignment station on the conveyor belt.

Fig. 14 is a front view of the socket cover in the third state in the alignment station on the conveyor belt.

Fig. 15 is a schematic view of the socket cover of fig. 2 in an outfeed station on a conveyor belt.

Fig. 16 is a schematic structural view of a socket cover in a second state of embodiment 2 of the present application in a setting station on a conveyor belt.

Fig. 17 is a front view of the socket cover in the second state of embodiment 2 of the present application in the adjustment station on the conveyor belt.

Fig. 18 is a schematic structural view of the socket upper cover in the third state of embodiment 2 of the present application in the adjustment station on the conveyor belt.

Fig. 19 is a front view of the socket cover in the third state in the alignment station on the conveyor belt.

Description of reference numerals: 1. a base plate; 2. a connecting pin; 3. a first gap; 4. a second gap; 5. a frame; 6. a feeding mechanism; 7. a screening mechanism; 8. a discharging mechanism; 9. a conveyor belt; 10. a feeding station; 11. a guide station; 12. a screening station; 13. adjusting the station; 14. a discharge station; 15. a feeding baffle plate; 16. a storage bin; 17. lifting the belt; 18. a material taking door; 19. a connecting plate; 20. a positioning bar; 21. caulking grooves; 22. a guide plate support block; 23. a guide plate; 24. arranging brushes; 25. a channel; 26. a supporting strip; 27. a lever shaft; 28. a shifting sheet; 29. a sensing member; 30. an air tube; 31. a detection hole; 32. a first pitch; 33. a return channel; 34. an adjustment member; 35. a second pitch; 36. adjusting a baffle; 37. a guide surface; 38. an adjusting lever; 39. a support plate; 40. a positioning column; 41. positioning a groove; 42. a discharge plate; 43. a limiting strip; 44. a discharge rail; 45. a direct vibration machine; 46. a discharge channel; 47. a floor tunnel; 48. a connection pin passage; 49. turning over the channel; 50. an adjustment plate; 51. positioning a plate; 52. mounting a plate; 53. a direct vibration machine support frame; 54. a first limit nut; 55. and a second limit nut.

Detailed Description

The present application is described in further detail below with reference to figures 1-19.

The embodiment of the application discloses directional conveyor of socket upper cover.

Example 1

Referring to fig. 2, the socket cover directional conveying device includes a frame 5, a feeding mechanism 6 disposed on the frame 5 and used for conveying the socket cover, a screening mechanism 7, and a discharging mechanism 8. Feed mechanism 6 is arranged in promoting the socket upper cover to screening mechanism 7, and screening mechanism 7 is used for screening the socket upper cover to the appointed state and sends out socket upper cover directional conveyor through discharge mechanism 8.

Screening mechanism 7 includes conveyor belt 9, and conveyor belt 9 is last and has set gradually feeding station 10, direction station 11, screening station 12, adjustment station 13 and ejection of compact station 14 along its direction of transfer, and conveyor belt 9 inclines to one side along its extending direction, and the lower one side of conveyor belt 9 is provided with the reinforced baffle 15 that the restriction socket upper cover breaks away from conveyor belt 9. When the socket cover enters the loading station 10, the socket cover can slide to the lower side of the conveyor belt 9 under the action of gravity and pass through the loading baffle 15 to be limited on the conveyor belt 9.

When the screening mechanism screens the socket upper cover, the screening mechanism can be divided into a first flow and a second flow according to the path of the socket upper cover. In the first process, the upper cover of the socket is driven by the conveying belt 9 to pass through a guide station 11, a screening station 12 and an adjusting station 13 from a feeding station 10 to a discharging station 14 in sequence; in the second process, the conveyor belt 9 drives the socket upper cover to pass through the guide station 11, the screening station 12 and return to the feeding station 10 again through the screening station 12 in sequence from the feeding station 10.

Referring to fig. 2 and 3, the feed mechanism 6 includes a magazine 16 and a lifting belt 17, the lifting belt 17 being used to transport the socket lids in the magazine 16 into the loading station 10. The side wall of the bin 16 is hinged with a material taking door 18, and when the socket upper cover directional conveying device stops working, if excessive excess materials exist in the bin 16, the socket upper cover in the bin 16 can be taken out through the material taking door 18.

The discharge end of the lifting belt 17 is connected with the feeding station 10 on the conveying belt 9, specifically, a connecting plate 19 is hinged to the joint of the lifting belt 17 and the conveying belt 9, and the connecting plate 19 is used for filling the gap between the discharge end of the lifting belt 17 and the conveying belt 9, so that the socket upper cover can smoothly enter the conveying belt 9 through the guide of the connecting plate 19. Be provided with a plurality of location strips 20 that set up perpendicularly with lifting belt 17 direction of transfer on the lifting belt 17, it is concrete, the quantity of location strip 20 sets up according to lifting belt 17's length, and usually, location strip 20 and lifting belt 17 integrated into one piece can also be through welded fastening.

Referring to fig. 1, in the present embodiment, a caulking groove 21 is formed between each positioning strip 20 and the adjacent positioning strip 20, and when the positioning strip 20 is inserted into the first gap 3 or the second gap 4, the positioning strip 20 drives the socket cover and the conveyor belt of the lifting belt 17 to move synchronously, so that the lifting belt 17 transfers the socket cover from the bin 16 to the feeding station 10 on the conveyor belt 9.

When the bottom plate 1 of the socket upper cover is inserted into the embedded groove 21, the groove wall of the embedded groove 21 drives the socket upper cover and the conveyor belt of the lifting belt 17 to move synchronously, and further the lifting belt 17 drives the socket upper cover to be transferred from the bin 16 to the feeding station 10 on the conveyor belt 9.

Referring to fig. 2 and 4, the guide station 11 includes a guide plate 23 disposed above the conveyor belt 9, a guide plate support block 22 fixed to the conveyor belt 9 is disposed on one side of the guide plate 23 away from the charging baffle 15, the guide plate 23 includes a mounting plate 52 having one end fixed to the guide plate support block 22 and a row brush 24 disposed on one side of the mounting plate 52 close to the conveyor belt 9 and used for abutting against the bottom plate 1 of the socket upper cover, the guide plate 23 is gradually close to the side provided with the charging baffle 15 along the conveying direction of the conveyor belt 9, and a channel 25 for the socket upper cover to pass through is formed between the guide plate 23 and the charging baffle 15.

Referring to fig. 5, when the bottom plate 1 of the upper cover of the socket abuts against the row brush 24, the conveyor belt 9 drives the upper cover of the socket to slide in a direction close to the feeding baffle 15 and enter the screening station 12 through the passage 25.

In addition, the guide station 11 can also only comprise a guide plate 23, and when the bottom plate 1 of the socket upper cover abuts against the guide plate 23, the conveyor belt 9 drives the socket upper cover to slide towards the direction close to the feeding baffle 15 and enter the screening station 12 through the channel 25.

Referring to fig. 2 and 6, the screening station 12 comprises a supporting bar 26 fixed on one side of the conveyor belt 9 far from the feeding baffle 15 through bolts, a poke rod 27 arranged at one end of the supporting bar 26 far from the conveyor belt 9, a poke plate 28 arranged at one end of the poke rod 27 far from the supporting bar 26, a sensing piece 29 connected with the poke plate 28 in a matching way, and an air pipe 30 controlled by the sensing piece 29.

Specifically, the air tube 30 is erected on the supporting bar 26, the sensing member 29 is disposed at one end of the lever shaft 27 far away from the supporting bar 26, the shifting piece 28 is disposed between the sensing member 29 and the supporting bar 26, and the lever shaft 27 penetrates through the shifting piece 28 and is rotatably connected with the shifting piece 28. The sensing member 29 is a light sensor, that is, a detection hole 31 for detecting the state of the pick 28 is formed in one side of the sensing member 29 close to the pick 28, and under the condition that the screening station 12 does not work, the pick 28 blocks the detection hole 31, so that the detection hole 31 does not sense light.

Referring to fig. 1, the socket cover can be divided into a first state, a second state and a third state according to the positional relationship among the bottom plate 1 of the socket cover, the connection pins 2 of the socket cover and the conveyor belt 9.

Referring to fig. 1 and 6, in a first state, the connecting leg 2 of the socket upper cover abuts against the conveyor belt 9, when the socket upper cover is transferred to the position of the screening station 12 under the action of the conveyor belt 9, and the bottom plate 1 of the socket upper cover abuts against the poking piece 28, the bottom plate 1 drives the poking piece 28 to rotate circumferentially around the poking rod shaft 27, so as to trigger the sensing piece 29, and further, the air pipe 30 is driven through the triggering of the sensing piece 29 to blow the socket upper cover away from the conveyor belt 9. The sensing member 29 may be a general photoelectric trigger such as a proximity switch.

Referring to fig. 1 and 7, in the second state, the bottom plate 1 of the socket upper cover abuts against the conveyor belt of the conveyor belt 9, a first gap 32 through which the bottom plate 1 of the socket upper cover passes is formed between the pick 28 and the conveyor belt 9, and the pick 28 passes through the first gap 3 between the connection pins 2 integrally formed on the same side of the socket upper cover.

Referring to fig. 1 and 8, in the third state, the bottom plate 1 of the jack upper cover abuts against the conveyor belt 9, the bottom plate 1 of the jack upper cover passes through the first gap 32 formed between the paddle 28 and the conveyor belt 9, and the paddle 28 passes through the second gap 4 integrally formed between the connection pins 2 on different sides of the jack upper cover.

Referring to fig. 8 and 9, the screening station 12 further includes a backflow passage 33 disposed on the conveyor belt 9, the backflow passage 33 is used for backflow of the socket upper cover blown off from the conveyor belt 9 through the air pipe 30 into the bin 16, one end of the backflow passage 33 is communicated with the bin 16, and one end of the backflow passage 33 far away from the bin 16 is opposite to one side of the conveyor belt 9 far away from the air pipe 30. When in the first state, the sensing part 29 is triggered, and then the air pipe 30 is driven to blow the socket upper cover away from the conveyor belt 9, and when the socket upper cover is separated from the conveyor belt 9 under the driving of the air pipe 30, the backflow channel 33 collects the socket upper cover separated from the conveyor belt 9 and transfers the socket upper cover into the bin 16 again, so that the screening of the socket upper cover can be repeated circularly.

Referring to fig. 2 and 10, the adjusting station 13 includes an adjusting member 34 disposed above the conveyor belt of the conveyor belt 9, and a second gap 35 is formed between the adjusting member 34 and the conveyor belt 9 for the bottom plate 1 of the socket cover to pass through. The conveyor belt 9 is provided with an adjusting baffle 36, the adjusting baffle 36 is positioned at the adjusting station 13 of the conveyor belt 9, and the adjusting member 34, the adjusting baffle 36 and the feeding baffle 15 are arranged on the same side of the conveyor belt 9. The adjuster 34 is provided with a guide surface 37, and the guide surface 37 gradually approaches the other side of the conveyor belt 9 in the conveying direction of the conveyor belt 9. When the connection pins 2 of the receptacle cover abut against the guide surfaces 37, the conveyor belt 9 drives the receptacle cover to rotate circumferentially about the abutting points of the connection pins 2 and the guide surfaces 37.

Referring to fig. 11, the adjusting member 34 includes an adjusting rod 38, a plurality of positioning posts 40 evenly spaced along the length direction of the adjusting rod 38, and a plurality of supporting plates 38 for the positioning posts 40 to penetrate through. For example, two support plates 39 are provided and spaced apart from each other in the longitudinal direction of the conveyor belt 9, and two positioning posts 40 are provided and spaced apart from each other in the longitudinal direction of the adjustment rod 38 and correspond to the two support plates 39 one by one. One side of the supporting plate 39 close to the adjusting rod 38 is provided with a positioning groove 41 in a penetrating manner, the positioning column 40 penetrates through the positioning groove 41 and is in threaded connection with a first limit nut 54 at one end of the positioning column 40 far away from the adjusting rod 38, and one side of the first limit nut 54 close to the adjusting rod 38 is abutted against one side of the supporting plate 38 far away from the adjusting rod 38. In addition, a second limit nut 55 is further disposed on the positioning column 40 disposed at an end of the adjusting rod 38 far from the feeding baffle 15, the supporting plate 39 far from the feeding baffle 15 is located between the first limit nut 54 and the second limit nut 55, and a side of the second limit nut 55 far from the adjusting rod 38 abuts against a side of the supporting plate 38 close to the adjusting rod 38.

Referring to fig. 12 and 13, in the second state, the socket upper cover enters the adjusting station 13 under the transmission of the conveyor belt 9, at this time, the socket upper cover passes through the second distance 35, and the bottom plate 1 of the socket upper cover is always abutted to the adjusting baffle 36, so that the socket upper cover is always in the second state in the process of passing through the adjusting station 13.

Referring to fig. 12 and 14, in the third state, the socket cover is conveyed by the conveyor belt 9 to enter the adjusting station 13, at this time, the connecting pins 2 of the socket cover abut against the guide surfaces 37 on the adjusting rods 38, and the socket cover is driven by the conveyor belt 9 to rotate circumferentially around the abutting points of the connecting pins 2 and the guide surfaces 37 on the adjusting rods 38, so that the socket cover is rotated from the third state to the second state.

Referring to fig. 2 and 15, the discharging mechanism 8 includes a discharging plate 42, a plurality of limiting strips 43, a discharging rail 44, a linear vibrator 45 and a linear vibrator support 53, and the discharging plate 42 and the limiting strips 43 are disposed at one end of the conveying belt 9 far away from the feeding station 10.

Referring to fig. 1, a turning channel 49 for the bottom plate 1 of the upper socket cover to penetrate and slide is formed between the discharging plate 42 and the limiting strip 43, the feeding end of the turning channel 49 is connected with the discharging station 14, and when the upper socket cover is located in the turning channel 49, the bottom plate 1 of the upper socket cover slides between the discharging plate 42 and the limiting strip 43 in a limiting manner, so that the upper socket cover is limited to move. Under the cooperation of the discharging plate 42 and the limiting strip 43, the upper cover of the socket is twisted from the state that the connecting pins 2 are under the upper base plate 1 to the state that the base plate 1 is under the upper connecting pins 2. Specifically, in the feed end of the reversing channel 49, the stopper bar 43 is located above the discharge plate 42, and as the reversing channel 49 extends, the stopper bar 43 gradually twists toward the lower side of the discharge plate 42, and in the discharge end of the reversing channel 49, the stopper bar 43 is located below the discharge plate 42.

Referring to fig. 2 and 15, the discharging rail 44 is provided with a discharging channel 46, specifically, the discharging channel 46 includes a bottom plate channel 47 for limiting sliding of the bottom plate 1 of the upper cover of the socket and a connecting pin channel 48 for limiting sliding of the connecting pin 2 of the upper cover of the socket, the bottom plate channel 47 is communicated with the connecting pin channel 48, and one end of the discharging channel 46 close to the discharging plate 42 is communicated with one end of the turning channel 49 far away from the discharging station 14; the lower end face of the discharging rail 44 is provided with a direct vibration machine 45 for driving the socket upper cover to slide through the discharging rail 44, and the direct vibration machine 45 is fixed on a direct vibration machine support frame 53 through bolts. The discharge plate 42 is continuously vibrated by the vertical vibration machine 45, so that the socket upper cover can be twisted from a state where the connection pins 2 are located below the upper base plate 1 to a state where the base plate 1 is located below the upper connection pins 2.

The implementation principle of the embodiment 1 is as follows:

when the socket upper covers need to be screened, the socket upper covers are firstly placed in the bin 16, the socket upper covers in the bin 16 are screened all the time under the action of the lifting belt 17, when the positioning bars 20 are plugged in the second gaps 4 or when the bottom plates 1 of the socket upper covers are plugged in the caulking grooves 21, the positioning bars 20 can limit the radial movement of the socket upper covers, and the lifting belt 17 enables the socket upper covers to be transferred from the bin 16 to the feeding stations 10 on the conveying belt 9 through the connecting plates 19.

Subsequently, the socket cover is transferred to the guide station 11 by the transfer of the transfer belt 9, and when the bottom plate 1 of the socket cover abuts against the row brush 24, the transfer belt 9 drives the socket cover to slide in a direction close to the charging shutter 15 and enter the sorting station 12 through the passage 25.

When the socket upper cover enters the screening station 12, the socket upper cover can be divided into a first state, a second state and a third state according to the position relation of the bottom plate 1 of the socket upper cover, the connecting pins 2 of the socket upper cover, the conveying belt 9 and the baffle.

The socket cover can be divided into a first state, a second state and a third state according to the positional relationship among the bottom plate 1 of the socket cover, the connection pins 2 of the socket cover and the conveyor belt 9.

In the first state, the connecting leg 2 of the socket upper cover abuts against the conveyor belt 9, when the socket upper cover is transferred to the position of the screening station 12 under the action of the conveyor belt 9, and when the bottom plate 1 of the socket upper cover abuts against the shifting piece 28, the bottom plate 1 drives the shifting piece 28 to rotate circumferentially around the shifting rod shaft 27, so as to trigger the sensing piece 29, and further, the air pipe 30 is driven through the triggering of the sensing piece 29 to blow the socket upper cover away from the conveyor belt 9. The sensing member 29 may be a general photoelectric trigger such as a proximity switch.

In the second state, the bottom plate 1 of the socket upper cover abuts against the conveyor belt of the conveyor belt 9, a first gap 32 for the bottom plate 1 of the socket upper cover to pass through is formed between the poking piece 28 and the conveyor belt 9, and the poking piece 28 passes through the first gap 3 between the connecting pins 2 integrally formed on the same side of the socket upper cover.

In the third state, the bottom plate 1 of the jack upper cover abuts against the conveyor belt 9, the bottom plate 1 of the jack upper cover passes through the first gap 32 formed between the pusher 28 and the conveyor belt 9, and the pusher 28 passes through the second gap 4 formed between the connecting pins 2 integrally formed on different sides of the jack upper cover.

When the socket upper cover in the second state enters the adjusting station 13, the socket upper cover passes through the second interval 35, and the bottom plate 1 of the socket upper cover is always abutted to the adjusting baffle 36, so that the socket upper cover is always in the second state and enters the discharging station 14 in the process of passing through the adjusting station 13.

In the third state, the socket upper cover enters the adjusting station 13 under the transmission of the transmission belt 9, at this time, the connecting pin 2 of the socket upper cover abuts against the guide surface 37 on the adjusting rod 38, and under the driving of the transmission belt 9, the socket upper cover rotates around the abutting point of the connecting pin 2 and the guide surface 37 on the adjusting rod 38, so that the socket upper cover is rotated from the third state to the second state and enters the discharging station 14.

When the socket upper cover enters the discharging station 14, the socket upper cover can be twisted from a state that the connecting pins 2 are under the upper bottom plate 1 to a state that the bottom plate 1 is under the upper connecting pins 2 under the continuous vibration action of the vertical vibration machine 45 on the discharging plate 42 and the continuous limiting action of the limiting strip 43 on the socket upper cover.

Example 2

Referring to fig. 16 and 17, the present embodiment is different from embodiment 1 in that the adjusting member 34 includes an adjusting plate 50 and a positioning plate 51 for fixing the adjusting plate 50, the positioning plate 51, the adjusting plate 50 and the adjusting baffle 36 are disposed on the same side of the conveyor belt 9, a guide surface 37 is disposed on one side of the adjusting plate 50 away from the adjusting baffle 36, the guide surface 37 gradually approaches to the other side of the conveyor belt 9 along the conveying direction of the conveyor belt 9, and a second space 35 for the bottom plate 1 of the socket upper cover to pass through is formed between the adjusting plate 50 and the conveyor belt 9.

In the second state, the socket upper cover enters the adjusting station 13 under the transmission of the conveyor belt 9, at this time, the bottom plate 1 of the socket upper cover passes through the second interval 35, and the bottom plate 1 of the socket upper cover is always abutted to the baffle plate, so that the socket upper cover is always in the second state in the process of passing through the adjusting station 13.

Referring to fig. 18 and 19, in the third state, the socket cover is conveyed by the conveyor belt 9 and enters the adjustment station 13, at this time, the connection pins 2 of the socket cover abut against the guide surfaces 37 of the adjustment plate 50, and the socket cover is rotated in the circumferential direction around the abutting points of the connection pins 2 and the guide surfaces 37 by the drive of the conveyor belt 9, so that the socket cover is rotated from the third state to the second state.

The implementation principle of the embodiment 2 is as follows:

when the socket upper cover in the second state enters the adjusting station 13, the socket upper cover passes through the second interval 35, and the bottom plate 1 of the socket upper cover is always abutted to the baffle plate, so that the socket upper cover is always in the second state and enters the discharging station 14 in the process of passing through the adjusting station 13.

When the upper socket cover in the third state enters the adjusting station 13, the connecting pins 2 of the upper socket cover abut against the guide surfaces 37 of the adjusting plate 50, and the upper socket cover rotates around the abutting points of the connecting pins 2 and the guide surfaces 37 under the driving of the conveying belt 9, so that the upper socket cover is rotated from the third state to the second state and enters the discharging station 14.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a directional conveyor of socket upper cover which characterized in that: the socket cover conveying device comprises a conveying belt (9) which is used for conveying a socket upper cover and is obliquely arranged, a feeding station (10), a screening station (12) and a discharging station (14) are sequentially arranged on the conveying belt (9) along the conveying direction of the conveying belt, a feeding baffle (15) is arranged at the lower end of the conveying belt (9), and the feeding baffle (15) is positioned at the feeding station (10) on the conveying belt (9); the screening station (12) comprises a poke rod shaft (27) arranged on the conveying belt (9), a poke sheet (28) which is rotatably connected with the poke rod shaft (27) and can penetrate through the first gap (3) or the second gap (4), a sensing piece (29) which is connected with the poke sheet (28) in a matching mode, and an air pipe (30) controlled by the sensing piece (29), wherein a first interval (32) for the bottom plate (1) of the socket upper cover to penetrate through is formed between the poke sheet (28) and the conveying belt (9); when the bottom plate (1) of the upper socket cover abuts against the shifting sheet (28), the bottom plate (1) of the upper socket cover drives the shifting sheet (28) to rotate around the circumferential direction of the shifting rod shaft (27), and then the sensing piece (29) is triggered to control the air pipe (30) to work so as to blow the upper socket cover off the conveying belt (9).

2. The device of claim 1, wherein: the automatic feeding device is characterized by further comprising a feeding mechanism (6) connected with a feeding station (10) on the conveying belt (9), wherein the feeding mechanism (6) comprises a storage bin (16) and a lifting belt (17), the discharging end of the lifting belt (17) is connected with a discharging station (14) of the conveying belt (9), and the other end of the lifting belt extends towards the interior of the storage bin (16); be provided with a plurality of location strips (20) that set up perpendicularly with lifting belt (17) direction of transfer on lifting belt (17)'s the conveyer belt, lifting belt (17) are arranged in carrying the socket upper cover in feed bin (16) to reinforced station (10).

3. The device as claimed in claim 2, wherein: the automatic feeding device is characterized by further comprising a guide station (11) which is arranged on the conveying belt (9) and located between the screening station (12) and the feeding station (10), wherein the guide station (11) comprises a guide plate (23) which is arranged above the conveying belt (9), the guide plate (23) is gradually close to one side provided with the feeding baffle (15) along the conveying direction of the conveying belt (9), and a channel (25) for the socket upper cover to pass through is formed between the guide plate (23) and the feeding baffle (15); when the bottom plate (1) of the upper socket cover abuts against the guide plate (23), the conveying belt (9) drives the upper socket cover to slide towards the direction close to the feeding baffle (15).

4. A socket cover directional conveying device according to claim 3, wherein: the guide plate (23) comprises a mounting plate (52) and a row brush (24) arranged on one side, close to the conveying belt (9), of the mounting plate (52), and the row brush (24) is used for being abutted to the bottom plate (1) of the socket upper cover.

5. The device of claim 1, wherein: the screening station (12) further comprises a backflow channel (33) arranged on the conveying belt (9), one end of the backflow channel (33) is communicated with the storage bin (16), and one end, far away from the storage bin (16), of the backflow channel (33) is opposite to one side, far away from the air pipe (30), of the conveying belt (9); the backflow channel (33) is used for backflow of the socket upper cover blown off the conveyor belt (9) through the air pipe (30) into the storage bin (16).

6. The device of claim 1, wherein: the conveying belt (9) is also provided with an adjusting station (13), and the adjusting station (13) is positioned between the screening station (12) and the discharging station (14); the adjusting station (13) comprises an adjusting piece (34) arranged above the conveying belt (9), and a second interval (35) for the bottom plate (1) of the socket upper cover to pass through is formed between the adjusting piece (34) and the conveying belt (9); the conveying belt (9) is provided with an adjusting baffle (36), the adjusting baffle (36) is positioned at an adjusting station (13) of the conveying belt (9), the adjusting part (34), the adjusting baffle (36) and the feeding baffle (15) are arranged on the same side of the conveying belt (9), the adjusting part (34) is provided with a guide surface (37), and the guide surface (37) is gradually close to the other side of the conveying belt (9) along the conveying direction of the conveying belt (9); when the connecting pins (2) of the upper socket cover abut against the guide surface (37), the transmission belt (9) drives the upper socket cover to rotate around the abutting points of the connecting pins (2) and the guide surface (37) in the circumferential direction.

7. The device of claim 6, wherein: the adjusting station (13) comprises an adjusting rod (38) arranged above the conveying belt (9) and a plurality of supporting plates (39) used for fixing the adjusting rod (38), and the supporting plates (39) are arranged on one side, provided with the adjusting baffle (36), of the conveying belt (9); the adjusting rod (38) is provided with a plurality of positioning columns (40) at intervals along the length direction, and the positioning columns (40) are in threaded connection with the supporting plate (39).

8. The device as claimed in claim 2, wherein: the automatic feeding device is characterized by further comprising a discharging mechanism (8) arranged at one end, far away from the feeding station (10), of the conveying belt (9), wherein the discharging mechanism (8) comprises a discharging plate (42) and a plurality of limiting strips (43), an overturning channel (49) for the bottom plate (1) of the upper socket cover to penetrate and slide is formed between the discharging plate (42) and the limiting strips (43), the feeding end of the overturning channel (49) is connected with the discharging end of the conveying belt (9), and the bottom plate (1) of the upper socket cover slides between the discharging plate (42) and the limiting strips (43) in a limiting mode; under the synergistic action of the discharging plate (42) and the limiting strip (43), the upper cover of the socket is twisted from the state that the connecting pins (2) are under the upper bottom plate (1) to the state that the connecting pins (2) are under the upper bottom plate (1).

9. The device of claim 8, wherein: the discharging mechanism (8) further comprises a discharging rail (44) which is arranged at one end, far away from the conveying belt (9), of the discharging plate (42) and connected with the discharging plate (42), a discharging channel (46) is arranged on the discharging rail (44), and one end, close to the conveying plate, of the discharging channel (46) is communicated with one end, far away from the discharging station (14), of the overturning channel (49); and a straight vibrating machine (45) for driving the socket upper cover to slide through the discharging rail (44) is arranged on the lower end face of the discharging rail (44).

10. The device as claimed in claim 2, wherein: the side wall of the storage bin (16) is provided with a material taking door (18).

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