CN215141708U - Rotating system REMS - Google Patents

Abstract

The utility model provides a rotating system REMS, include: the rotary support is provided with a moving part moving along the track, a rotary groove is formed in the middle end of the rotary support, one end of a positioning column is fixedly connected in the rotary groove, a turnover plate is arranged at the other end of the positioning column in a rotating fit mode, a rotary driving column is fixedly connected with the turnover plate, a guide column matched with the rotary driving column is fixedly connected with the track, and a positioning assembly matched with the turnover plate is fixedly connected with the rotary support. The rotating angle of the turnover plate is controlled through the matching of the positioning column and the turnover plate, and meanwhile, the turnover plate after rotating is positioned through the matching of the positioning assembly and the turnover plate, so that the floor area of the annular process line is reduced, and the manufacturing cost of the whole annular process line is reduced.

Description

Rotating system REMS

Technical Field

The utility model relates to a rotating system field, concretely relates to rotating system REMS.

Background

The conveying system runs through the whole process of a modern automobile coating production line and is an artery of the coating production line. At present, the conveying systems adopted in the mass continuous production mainly comprise: a suspension chain conveyor, a swing link conveyor, a RoDip conveyor, and a multi-function shuttle.

The self-propelled hoist conveyor is limited to a vehicle body coating line with the capacity below 20JPH, cavity air is easily generated on the roof of the vehicle, and particle defects are easily generated on the top of the vehicle and front and rear covers of the vehicle. The accumulation type suspension conveyor has small in-out groove angle, poor in exhaust effect, large groove body volume, long line body, large floor area and the majority of the existing pretreatment electrophoresis production lines use EMS, accumulation chain and swing rod chain systems.

In the prior art, an annular process line is often adopted in the REMS (rotary self-propelled trolley conveying system), a trolley can be separated from the conveying system after the surface of a soaking tank is coated, and when a conveyor returns along the annular process line, a large amount of space is wasted at two ends of the annular process line, so that the whole REMS (rotary self-propelled trolley conveying system) is large in occupied area and high in manufacturing cost.

SUMMERY OF THE UTILITY MODEL

In order to solve the above technical problem, the utility model provides a rotating system REMS that can effectively solve above-mentioned technical problem.

In order to achieve the above purpose, the technical scheme of the utility model is as follows: a rotary system REMS, comprising: the rotary support is provided with a moving part moving along the track, a rotary groove is formed in the middle end of the rotary support, one end of a positioning column is fixedly connected in the rotary groove, a turnover plate is arranged at the other end of the positioning column in a rotating fit mode, a rotary driving column is fixedly connected with the turnover plate, a guide column matched with the rotary driving column is fixedly connected with the track, and a positioning assembly matched with the turnover plate is fixedly connected with the rotary support.

Preferably, the positioning assembly comprises: the positioning frame is fixedly connected with the rotating support and provided with a descending table, the positioning frame is provided with an ascending table located right above the descending table, the descending table is matched with a locking column, and the turnover plate is provided with a locking groove matched with the locking column; locking post fixedly connected with one with the spacing platform of down platform complex, spacing platform with go upward between the platform the cover be equipped with a reset spring, the reset spring cover is located the lateral wall of locking post, the locking post extends to perpendicularly and goes upward platform upper surface cooperation and has a drive assembly, drive assembly drives the locking post goes upward.

Preferably, the number of the locking grooves is four, and the locking grooves are uniformly distributed around the center of the positioning column at equal angles.

Preferably, the drive assembly comprises: the driving rod, driving rod one end and the platform of going upward are articulated, and the middle-end and the locking post of driving rod are articulated, the other end of driving rod is equipped with a cam that drives the locking post and go upward, runing rest fixedly connected with one drives the rotatory first motor of cam.

Preferably, the moving part is fixedly connected with a moving wheel matched with the track.

Preferably, the roll-over plate is equipped with two rotating parts, rotates between two rotating parts and is equipped with a trip shaft, roll-over plate fixedly connected with second motor, the second motor passes through the hold-in range and drives the trip shaft is rotatory, a roll-over stand of trip shaft fixedly connected with.

The utility model has the advantages of as follows:

the rotating angle of the turnover plate is controlled through the matching of the positioning column and the turnover plate, and meanwhile, the turnover plate after rotating is positioned through the matching of the positioning assembly and the turnover plate, so that the floor area of the annular process line is reduced, and the manufacturing cost of the whole annular process line is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic diagram of an overall structure of a rotational system REMS according to an embodiment of the present invention;

fig. 2 is an enlarged view of a structure at a position a of the rotational system REMS according to an embodiment of the present invention.

The corresponding part names indicated by the numbers and letters in the drawings:

1. the rotary support 2, the moving part 3, the positioning column 4, the turnover plate 5, the rotary driving column 6, the guiding column 7, the positioning frame 8, the descending table 9, the ascending table 10, the locking column 11, the locking groove 12, the limiting table 13, the reset spring 14, the driving rod 15, the cam 16, the first motor 17, the moving wheel 18, the rotating part 19, the turnover shaft 20, the second motor 21 and the turnover frame.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

The present invention will be described in further detail with reference to examples and embodiments.

As shown in fig. 1, a rotational system REMS includes: the rotary support comprises a rotary support 1 and a track, wherein the rotary support 1 is provided with a moving part 2 moving along the track, the track is an annular track, the moving part 2 is fixedly connected with a moving wheel 17 matched with the track, and the moving wheel 17 reduces the friction force between the rotary support 1 and the track.

The middle end of the rotating support 1 is provided with a rotating groove, one end of a positioning column 3 is arranged in the rotating groove (the positioning column 3 is perpendicular to the rotating support 1), the other end of the positioning column 3 is matched with a turnover plate 4 in a rotating mode, and the turnover plate 4 is fixedly connected with a rotary driving column 5.

The track is fixedly connected with a guide post 6 matched with the rotary driving post 5, and the rotary driving post 5 is matched with the guide post 6 to control the rotation angle of the turnover plate 4 (the rotation angle of the turnover plate 4 is 90 degrees).

The rotating support 1 is fixedly connected with a positioning component matched with the turnover plate 4, and the turnover plate 4 is fixed relative to the rotating support 1 after rotating through the positioning component and the turnover plate 4.

The positioning assembly includes: the positioning frame 7 is fixedly connected with the rotating support 1, the positioning frame 7 is provided with a descending table 8, the positioning frame 7 is provided with an ascending table 9 right above the descending table 8, and the descending table 8 is matched with a locking column 10.

As shown in fig. 1 to 2, the turning plate 4 is provided with four locking grooves 11 matched with the locking columns 10, the locking grooves 11 are uniformly distributed around the center of the positioning column 3 at equal angles, and the locking columns 10 vertically penetrate through the lower platform 8 to be matched with the turning plate 4.

The locking column 10 is fixedly connected with a limiting table 12 matched with the descending table 8, the limiting table 12 controls the descending distance of the locking column 10, a return spring 13 is sleeved between the limiting table 12 and the ascending table 9, the outer side wall of the locking column 10 is sleeved with the return spring 13, and the return spring 13 is matched with the limiting table 12 to drive the locking column 10 to descend.

The locking column 10 vertically extends to the upper surface of the ascending table 9 and is matched with a driving assembly, and the driving assembly drives the locking column 10 to ascend.

The drive assembly includes: and one end of the driving rod 14 is hinged with the ascending table 9, the middle end of the driving rod 14 is hinged with the locking column 10, and the other end of the driving rod 14 is provided with a cam 15.

The rotating bracket 1 is fixedly connected with a first motor 16 for driving the cam 15 to rotate, the rotating center of the cam 15 is coaxial with the output shaft of the first motor 16, and the first motor 16 drives the cam 15 to rotate so as to drive the cam 15 to rotate.

The cam 15 drives the driving rod 14 to rotate counterclockwise around the hinge point of the ascending platform 9, so as to drive the locking column 10 to ascend and compress the return spring 13, and the locking column 10 is separated from the locking groove 11.

The turning plate 4 is provided with two rotating parts 18, a turning shaft 19 is rotatably arranged between the two rotating parts 18, the turning plate 4 is fixedly connected with a second motor 20, the second motor 20 drives the turning shaft 19 to rotate through a synchronous belt, and the turning shaft 19 is fixedly connected with a turning frame 21.

As shown in fig. 1 and 2, in operation, a trolley to be dipped is fixed by a roll-over stand 21, a rotating support 1 moves along a rail to drive the trolley to move to a dipping tank, a second motor 20 drives a roll-over shaft 19 to rotate the trolley to perform surface coating in the dipping tank, the coated trolley is conveyed along the rail by the rotating support 1, and when the rotating support 1 moves to two ends of an annular rail.

The driving motor drives the cam 15 to rotate, the cam 15 drives the driving rod 14 to rotate anticlockwise around a hinge point of the upward table 9, the driving rod 14 drives the locking column 10 to move upwards and compress the spring, the locking column 10 is separated from the locking groove 11, and the rotary driving column 5 is matched with the guide column 6 to drive the turnover plate 4 to rotate by 90 degrees.

In the rotating process of the turnover plate 4, the first motor 16 drives the cam 15 to rotate, the reset spring 13 drives the locking column 10 to move downwards to be in contact with the turnover plate 4, and the locking column 10 is automatically matched with the other locking groove 11 to realize locking after the turnover plate 4 rotates ninety degrees.

The rotating support 1 is conveyed continuously along the track, when the rotating support 1 drives the turnover plate 4 to move to the next guide column 6, the rotating driving column 5 is matched with the guide column 6, the positioning assembly is matched with the locking groove 11 again, locking is achieved after the turnover plate 4 rotates ninety degrees, and the rotating support 1 reciprocates along the track.

Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention.

Claims (6)

1. A rotary system REMS, comprising: the rotary support is provided with a moving part moving along the track, a rotary groove is formed in the middle end of the rotary support, one end of a positioning column is fixedly connected in the rotary groove, a turnover plate is arranged at the other end of the positioning column in a rotating fit mode, a rotary driving column is fixedly connected with the turnover plate, a guide column matched with the rotary driving column is fixedly connected with the track, and a positioning assembly matched with the turnover plate is fixedly connected with the rotary support.

2. The rotational system REMS of claim 1, wherein the positioning assembly comprises: the positioning frame is fixedly connected with the rotating support and provided with a descending table, the positioning frame is provided with an ascending table located right above the descending table, the descending table is matched with a locking column, and the turnover plate is provided with a locking groove matched with the locking column; locking post fixedly connected with one with the spacing platform of down platform complex, spacing platform with go upward between the platform the cover be equipped with a reset spring, the reset spring cover is located the lateral wall of locking post, the locking post extends to perpendicularly and goes upward platform upper surface cooperation and has a drive assembly, drive assembly drives the locking post goes upward.

3. The rotational system REMS as in claim 2, wherein said locking slots are four in number and equally angularly distributed about the center of the positioning post.

4. The rotational system REMS of claim 2, wherein the drive assembly comprises: the driving rod, driving rod one end and the platform of going upward are articulated, and the middle-end and the locking post of driving rod are articulated, the other end of driving rod is equipped with a cam that drives the locking post and go upward, runing rest fixedly connected with one drives the rotatory first motor of cam.

5. The rotational system REMS according to claim 1, wherein the moving part is fixedly connected with moving wheels cooperating with rails.

6. The REMS as claimed in claim 1, wherein the turning plate has two rotating portions, a turning shaft is rotatably disposed between the two rotating portions, the turning plate is fixedly connected with a second motor, the second motor drives the turning shaft to rotate through a synchronous belt, and the turning shaft is fixedly connected with a turning frame.

Images