CN213150593U - Synchronous transmission device for tantalum capacitor - Google Patents

Abstract

The utility model provides a synchronous transmission that tantalum electric capacity was used, it is including the base, the base wherein the both ends of one side are fixed with the end plate, the end plate top is fixed with the bearing board, the vertical rotation axis of installing in bearing board top, install synchronous pulley on the rotation axis, base top opposite side is horizontal mounting and has first guide pillar, movable mounting has first slide on the first guide pillar, base top between first guide pillar and the hold-in range is horizontal mounting and has the second guide pillar, movable mounting has the second slide on the second guide pillar, be located the synchronous belt of second guide pillar one side and be fixed with the second and carry the seat, install the second delivery board between second transport seat and the second slide top. The utility model discloses rational in infrastructure, transport speed is fast, work efficiency is high after adopting above-mentioned scheme.

Description

Synchronous transmission device for tantalum capacitor

Technical Field

The utility model belongs to the technical field of the electric capacity technique and specifically relates to indicate a synchronous drive device that tantalum electric capacity was used.

Background

When an existing electronic product is processed, the conveying belt is adopted for conveying, after one-time conveying is completed, after the electronic product is required to be processed for the time, the conveying belt reversely conveys the processed electronic product back, then the electronic product is discharged and a new electronic product to be processed is placed, and the conveying speed is low and the working efficiency is low by adopting the mode.

Disclosure of Invention

An object of the utility model is to overcome prior art's not enough, provide a synchronous drive device that tantalum electric capacity is used rational in infrastructure, conveying speed is fast, work efficiency is high.

In order to achieve the above object, the present invention provides a technical solution: a synchronous transmission device for tantalum capacitors comprises a base, end plates are fixed at two ends of one side of the base, a bearing plate is fixed at the top of the end plate, a rotating shaft is vertically installed at the top of the bearing plate, synchronous pulleys are installed on the rotating shaft, the two synchronous pulleys are connected through a synchronous belt, a rotating motor is installed at the bottom of one bearing plate, a transmission shaft of the rotating motor upwards penetrates through the bearing plate to be connected with the rotating shaft, a first guide pillar is horizontally installed at the other side of the top of the base, a first sliding seat is movably installed on the first guide pillar, a first conveying seat is fixed on the synchronous belt far away from one side of the first guide pillar, a lifting cylinder is installed at the top of the first conveying seat, a piston rod of the lifting cylinder is vertically upwards fixedly connected with the bottom of one end of the first conveying plate, the other end of the first conveying plate extends to the upper portion, the bottom of the guide post downwards penetrates through the first sliding seat to form a guide end, the top of the base between the first guide post and the synchronous belt is horizontally provided with a second guide post, the second guide post is movably provided with a second sliding seat, a second conveying seat is fixed on the synchronous belt on one side of the second guide post, and a second conveying plate is arranged between the second conveying seat and the top of the second sliding seat.

A first bearing shaft is fixed between the two end plates below the first conveying seat, a first shaft sleeve is fixed at the bottom of the first conveying seat, and the first shaft sleeve is movably sleeved on the first bearing shaft; a second bearing shaft is fixed between the two end plates below the second conveying seat, a second shaft sleeve is fixed at the bottom of the second conveying seat, and the second shaft sleeve is movably sleeved on the second bearing shaft.

The length directions of the first guide post and the second guide post are consistent with the conveying direction of the synchronous belt.

After the scheme is adopted, the first conveying plate is positioned at the input end in the initial state, the electronic product to be conveyed is placed on the first conveying plate through the prior process, the rotating motor rotates in the forward direction to drive the rotating shaft to rotate through the transmission shaft, the rotating shaft drives the synchronous belt to rotate through the synchronous belt pulley, the synchronous belt drives the first conveying plate provided with the electronic product to move towards the output end through the first conveying seat, the synchronous belt drives the second conveying plate to move towards the input end through the second conveying seat, before the two conveying plates are staggered, the piston rod of the lifting cylinder stretches out to drive the first conveying plate to ascend, so that the first conveying plate is positioned above the second conveying plate, the second conveying plate passes below the first conveying plate, the piston rod which passes through the lifting cylinder contracts to drive the first conveying plate to descend and reset, when the first conveying plate moves in place, the second conveying plate also moves in place simultaneously, the electronic product is placed on the second conveying plate through the previous process; after the first conveying plate is machined and the second conveying plate is placed, a rotating motor rotates reversely, a rotating shaft is driven to rotate through a transmission shaft, the rotating shaft drives a synchronous belt to rotate through a synchronous belt wheel, the synchronous belt drives the first conveying plate to move towards an input end through a first conveying seat, the synchronous belt drives the second conveying plate to move towards an output end through a second conveying seat, the two conveying plates are staggered, a piston rod of a lifting cylinder extends out to drive the first conveying plate to ascend, so that the first conveying plate is located above the second conveying plate, the second conveying plate penetrates through the lower portion of the first conveying plate, and the piston rod penetrating through the rear lifting cylinder contracts to drive the first conveying plate to descend and reset, so that reciprocating conveying is formed; the utility model discloses rational in infrastructure, transport speed is fast, work efficiency is high after adopting above-mentioned scheme.

Drawings

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

Detailed Description

The present invention will be further explained with reference to the drawings, and the preferred embodiment of the present invention is: referring to fig. 1, the synchronous transmission device for tantalum capacitors in this embodiment includes a base 1, end plates 2 are fixed at two ends of one side of the base 1, a support plate 3 is fixed on the top of the end plates 2, a rotating shaft 4 is vertically installed on the top of the support plate 3, a synchronous pulley 5 is installed on the rotating shaft 4, the two synchronous pulleys 5 are connected through a synchronous belt 6, a rotating motor 7 is installed at the bottom of one support plate 3, a transmission shaft of the rotating motor 7 upwards penetrates through the support plate 3 to be connected with the rotating shaft 4, a first guide pillar 8 is horizontally installed at the other side of the top of the base 1, a first sliding seat 13 is movably installed on the first guide pillar 8, a first conveying seat 9 is fixed on the synchronous belt 6 at the side far from the first guide pillar 8, a lifting cylinder 10 is installed at the top of the first conveying seat 9, a piston rod of the lifting cylinder 10 is vertically, the other end of the first conveying plate 11 extends to the upper portion of the first sliding seat 13 to form a suspended end, a guide pillar 12 is vertically fixed at the bottom of the suspended end, the bottom of the guide pillar 12 downwards penetrates through the first sliding seat 13 to form a guide end, the top of the base 1 between the first guide pillar 8 and the synchronous belt 6 is horizontally provided with a second guide pillar 14, the length direction of the second guide pillar 14 is consistent with the conveying direction of the synchronous belt 6, a second sliding seat 15 is movably arranged on the second guide pillar 14, a second conveying seat 16 is fixed on the synchronous belt 6 on one side of the second guide pillar 14, and a second conveying plate 17 is arranged between the second conveying seat 16 and the top of the second sliding seat 15. A first bearing shaft 18 is fixed between the two end plates 2 below the first conveying seat 9, a first shaft sleeve is fixed at the bottom of the first conveying seat 9, and the first shaft sleeve is movably sleeved on the first bearing shaft 18; a second bearing shaft 19 is fixed between the two end plates 2 below the second conveying seat 16, a second shaft sleeve is fixed at the bottom of the second conveying seat 16, and the second shaft sleeve is movably sleeved on the second bearing shaft 19.

After the scheme is adopted in the embodiment, the first conveying plate is positioned at the input end in the initial state, the electronic product to be conveyed is placed on the first conveying plate through the previous process, the rotating motor rotates forwards to drive the rotating shaft to rotate through the transmission shaft, the rotating shaft drives the synchronous belt to rotate through the synchronous belt pulley, the synchronous belt drives the first conveying plate provided with the electronic product to move towards the output end through the first conveying seat, meanwhile, the synchronous belt drives the second conveying plate to move towards the input end through the second conveying seat, before the two conveying plates are staggered, a piston rod of the lifting cylinder extends out to drive the first conveying plate to ascend, so that the first conveying plate is positioned above the second conveying plate, the second conveying plate penetrates through the lower part of the first conveying plate, the piston rod penetrating through the rear lifting cylinder contracts to drive the first conveying plate to descend and reset, when the first conveying plate moves in place, meanwhile, the second conveying plate is moved in place, and the electronic product is placed on the second conveying plate through the previous process; after the first conveying plate is machined and the second conveying plate is placed, a rotating motor rotates reversely, a rotating shaft is driven to rotate through a transmission shaft, the rotating shaft drives a synchronous belt to rotate through a synchronous belt wheel, the synchronous belt drives the first conveying plate to move towards an input end through a first conveying seat, the synchronous belt drives the second conveying plate to move towards an output end through a second conveying seat, the two conveying plates are staggered, a piston rod of a lifting cylinder extends out to drive the first conveying plate to ascend, so that the first conveying plate is located above the second conveying plate, the second conveying plate penetrates through the lower portion of the first conveying plate, and the piston rod penetrating through the rear lifting cylinder contracts to drive the first conveying plate to descend and reset, so that reciprocating conveying is formed; the embodiment is rational in infrastructure, conveying speed is fast, work efficiency is high after adopting above-mentioned scheme.

The above-mentioned embodiments are only preferred embodiments of the present invention, and the scope of the present invention is not limited thereto, so that all the changes made according to the shape and principle of the present invention should be covered within the protection scope of the present invention.

Claims (3)

1. The utility model provides a synchronous drive that tantalum electric capacity was used, it is including base (1), its characterized in that: the two ends of one side of a base (1) are fixed with end plates (2), the top of each end plate (2) is fixed with a bearing plate (3), the top of each bearing plate (3) is vertically provided with a rotating shaft (4), the rotating shaft (4) is provided with synchronous pulleys (5), the two synchronous pulleys (5) are connected through a synchronous belt (6), the bottom of one bearing plate (3) is provided with a rotating motor (7), a transmission shaft of the rotating motor (7) upwards penetrates through the bearing plate (3) to be connected with the rotating shaft (4), the other side of the top of the base (1) is horizontally provided with a first guide pillar (8), a first sliding seat (13) is movably arranged on the first guide pillar (8), a first conveying seat (9) is fixed on the synchronous belt (6) far away from one side of the first guide pillar (8), a lifting cylinder (10) is arranged at the top of the first conveying seat (9), a piston rod of the lifting cylinder (10) upwards vertically is fixedly connected, the other end of the first conveying plate (11) extends to a suspended end formed above the first sliding seat (13), a guide pillar (12) is vertically fixed at the bottom of the suspended end, the bottom of the guide pillar (12) downwards penetrates through the first sliding seat (13) to form a guide end, the top of the base (1) between the first guide pillar (8) and the synchronous belt (6) is horizontally provided with a second guide pillar (14), a second sliding seat (15) is movably arranged on the second guide pillar (14), a second conveying seat (16) is fixed on the synchronous belt (6) located on one side of the second guide pillar (14), and a second conveying plate (17) is arranged between the second conveying seat (16) and the top of the second sliding seat (15).

2. The synchronous drive device for tantalum capacitors as claimed in claim 1, wherein: a first bearing shaft (18) is fixed between the two end plates (2) below the first conveying seat (9), a first shaft sleeve is fixed at the bottom of the first conveying seat (9), and the first shaft sleeve is movably sleeved on the first bearing shaft (18); a second bearing shaft (19) is fixed between the two end plates (2) below the second conveying seat (16), a second shaft sleeve is fixed at the bottom of the second conveying seat (16), and the second shaft sleeve is movably sleeved on the second bearing shaft (19).

3. The synchronous drive device for tantalum capacitors as claimed in claim 1, wherein: the length directions of the first guide post (8) and the second guide post (14) are consistent with the conveying direction of the synchronous belt (6).

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