CN220765544U - Auxiliary plate transmission device - Google Patents

Abstract

An auxiliary plate transmission device comprises a net belt, two connecting chains respectively arranged at two sides of the net belt, and a rolling device group fixedly connected with the net belt and the connecting chains. The net belt is formed by twisting a plurality of twisted iron wires. The net belt comprises a plurality of kinking parts, two connecting parts respectively arranged at two sides of the net belt and a plurality of abutting parts contacted with the outside. The connecting chain comprises a connecting surface connected with the mesh belt and a supporting surface arranged on the top of the connecting chain. The connecting surface is connected with the connecting part. The rolling device group comprises a plurality of rolling devices, each rolling device comprises a group of support plate groups arranged at two ends of the rolling device, a rolling shaft clamped between the support plate groups, and a roller sleeved outside the rolling shaft. The roller can freely roll on a rolling shaft. This supplementary panel transmission has avoided the risk of area material bottom strain.

Description

Auxiliary plate transmission device

Technical Field

The utility model belongs to the technical field of transmission, and particularly relates to an auxiliary plate transmission device.

Background

The transmission device is a device which drives the finished product or the particulate article to continuously move along a given route through the bearing part and helps the finished product or the particulate article to reach a specified position. In industrial production, the transmission device is widely applied, and when materials are produced, the materials have high temperature and large mass, and the transmission device is needed to assist in movement. When transferring some small-sized appliances, the transmission device is also used, so that the labor and the cost are saved.

In the process of sintering the pipeline plate, when the belt material passes through the belt furnace, the belt material needs to be supported by the belt and can move in the same direction along with the belt ground transmission. However, the speed of the mesh belt and the speed of the belt are often asynchronous, so that the bottom of the belt is easily pulled by the mesh belt, and finally product defects are caused.

Disclosure of Invention

In view of the above, the present utility model provides an auxiliary plate driving device to solve the above problems.

An auxiliary plate transmission device comprises a net belt, two connecting chains respectively arranged at two sides of the net belt, and a rolling device group fixedly connected with the net belt and the connecting chains. The net belt comprises a plurality of kinking parts, two connecting parts arranged on two sides of the net belt and a plurality of abutting parts in contact with the outside. The connecting chain comprises a connecting surface connected with the mesh belt and a supporting surface arranged on the top of the connecting chain. The connecting surface is connected with the connecting part. The rolling device group comprises a plurality of rolling devices, each rolling device comprises a group of support plate groups arranged at two ends of the rolling device, a rolling shaft clamped between the two support plates, and a roller sleeved outside the rolling shaft.

Further, the net belt is formed by twisting a plurality of torsion iron wires.

Further, the support plate group includes an inner support plate connected to the mesh belt, and an outer support plate connected to the connecting chain.

Further, the rolling shaft comprises an inner side surface facing the mesh belt side and an outer side surface facing away from the mesh belt side.

Further, the inner support plate includes an inner abutment surface abutting against the torsion portion, and an inner clamping portion connected to the inner side surface.

Further, the outer support plate comprises an outer abutting surface abutting against the support surface and an outer clamping portion connected with the outer side surface.

Further, the drum includes a through hole.

Further, the diameter of the through hole is larger than the diameter of the rolling shaft.

Further, the through hole is not coaxial with the roll shaft.

Compared with the prior art, the auxiliary plate transmission device provided by the utility model has the advantages that the mesh belt is formed by twisting a plurality of torsion iron wires, so that the auxiliary plate transmission device has hardness, certain toughness and longer service life. Meanwhile, due to the connecting chains connected to the two sides of the mesh belt, the two sides can be kept consistent when the mesh belt moves, the abrasion of the auxiliary plate transmission device is reduced, and the stability of the whole structure is enhanced. Because a plurality of identical rolling devices are arranged, the rolling devices comprise a rolling shaft and a roller, the roller can support the belt material to change friction during belt material transmission from sliding friction to rolling friction, and the bottom of the belt material is not strained when the speeds of the net belt and the belt material are not synchronous. Because the diameter of the through hole of the roller is larger than that of the rolling shaft, and the through hole is not coaxial with the rolling shaft, the roller has a certain movable space, friction force between the roller and the rolling shaft is small, and the belt can be better attached to the supporting belt. When it is desired to stop the web advance at a cost saving, the web may still assist the web advance by the rolling of the drum.

Drawings

Fig. 1 is a schematic structural diagram of an auxiliary plate transmission device provided by the utility model.

Fig. 2 is an exploded view of a rolling device of the auxiliary plate driving device of fig. 1.

Fig. 3 is a schematic view of a partial enlarged structure of the auxiliary plate driving device at a of fig. 1.

Detailed Description

Specific embodiments of the present utility model are described in further detail below. It should be understood that the description herein of the embodiments of the utility model is not intended to limit the scope of the utility model.

Fig. 1 to 3 are schematic structural views of an auxiliary plate driving device according to the present utility model. The auxiliary plate driving device comprises a net belt 10, a connecting chain 20 arranged at two sides of the net belt 10, and a rolling device group 30 fixedly connected with the net belt 10 and the connecting chain 20. The auxiliary plate drive also comprises other functional modules, such as fastening components, assembly components, etc., which should be known to the person skilled in the art and will not be described in any greater detail here.

The net belt 10 is formed by twisting a plurality of twisted iron wires, is firm and has toughness, and is not easy to deform. The mesh belt 10 includes a plurality of twisted portions 11 formed at twisted portions of twisted wires, two connecting portions 12 respectively provided at both sides of the mesh belt 10, and a plurality of abutting portions 13 provided at the bottom of the mesh belt 10. Part of the torsion parts 11 is used to cooperate with an inner support plate 3111 of the rolling device set 30, which will be described later, for the purpose of supporting and fixing the inner support plate 3111. The connection portion 12 is adapted to be connected to the connecting chain 20. The abutting portion 13 is used to abut against an external supporting table such as a base, a supporting table, etc. that supports the mesh belt 10. The structure of the link chain 20 will be described in detail.

The connecting chain 20 itself is a prior art, and may be made of metal and bendable. The connecting chain 20 comprises a connecting surface 21 facing the belt 10 side and a supporting surface 22 at the top. The connecting surface 21 is connected with the connecting portion 12, and is used for connecting the connecting chain 20 with the mesh belt 10, so that the overall structural stability of the mesh belt 10 can be enhanced, synchronous advancing at two sides of the mesh belt 10 can be realized, friction of the abutting portion 13 is reduced, and the service life of the mesh belt 10 is prolonged. The support surface 22 cooperates with an outer support plate 3112 of the rolling device set 30 for fixedly connecting the rolling device set 30, and a structure of the rolling device set 30 will be described in detail below.

The rolling means set 30 comprises a plurality of rolling means 31. A plurality of the rolling means 31 are arranged in at least one row. In the present embodiment, the structure and the operation principle of the present application are merely explained. In the description herein, only one rolling device 31 is taken as an example, and each rolling device 31 has the same structure, and includes a support plate group 311 disposed at both ends of the rolling device 31, a rolling shaft 312 interposed between the support plate groups 311, and a roller 313 sleeved outside the rolling shaft 312. The support plate set 311 includes an inner support plate 3111 on the inside of the webbing 10, and an outer support plate 3112 on the link chain 20. The inner support plate 3111 includes an inner abutment surface 3111A facing the torsion portion 11 side, and an inner engagement portion 3111B facing the roll shaft 312 side. The outer support plate 3112 includes an outer abutment surface 3112A facing the support surface 22 side, and an outer engagement portion 3112B facing the roll shaft 312 side. The inner abutment surface 3111A is connected to the torsion portion 11. The outer contact surface 3112A contacts the support surface 22. The roll axis 312 includes an inner side 3121 facing the side of the web 10 and an outer side facing away from the side of the web 10. The inner side surface 3121 is configured to connect to the inner engagement portion 3111B. The outer side surface 3122 is configured to connect to the outer engagement portion 3112B. The drum 313 includes a through hole 3131. The diameter of the through hole 3131 is larger than that of the rolling shaft 312, and the roller 313 may be coupled to the rolling shaft 312. The through hole 3131 and the rolling shaft 312 are not coaxial, so that the roller 313 has a certain moving space on the rolling shaft 312 to reduce friction force, and the force is more uniform when carrying the belt material.

Compared with the prior art, the auxiliary plate transmission device provided by the utility model has the advantages that the mesh belt 10 is formed by twisting a plurality of torsion iron wires, so that the auxiliary plate transmission device has hardness, certain toughness and longer service life. Meanwhile, due to the connecting chains 20 connected to the two sides of the mesh belt 10, the two sides can be kept consistent when the mesh belt 10 moves, the abrasion of the auxiliary plate transmission device is reduced, and the stability of the whole structure is enhanced. Since the same plurality of rolling means 31 are provided, the rolling means 31 comprises a rolling shaft 312 and a roller 313, the roller 313 can support the web to change the friction of the web in driving from sliding friction to rolling friction, and the web bottom is not pulled when the speed of the web 10 is not synchronous with the speed of the web. Since the diameter of the through hole 3131 of the roller 313 is larger than the diameter of the rolling shaft 312, and the through hole 3131 is not coaxial with the rolling shaft 312, the roller 313 has a certain movable space and has small friction force with the rolling shaft 312, so that the support belt can be better attached. When it is desired to stop the advancing web 10 at a cost, the web may still assist in the advancing web by the rolling of the rollers 313.

The above is only a preferred embodiment of the present utility model and is not intended to limit the scope of the present utility model, and any modifications, equivalent substitutions or improvements within the spirit of the present utility model are intended to be covered by the claims of the present utility model.

Claims (9)

1. An auxiliary plate transmission device is characterized in that: the auxiliary plate transmission device comprises a net belt, two connecting chains respectively arranged on two sides of the net belt, and a rolling device group fixedly connected with the net belt and the connecting chains, wherein the net belt comprises a plurality of twisting parts, two connecting parts respectively arranged on two sides of the net belt, and a plurality of abutting parts in contact with the outside, the connecting chains comprise a connecting surface connected with the net belt, and a supporting surface arranged on the top of the connecting chains, the connecting surface is connected with the connecting parts, the rolling device group comprises a plurality of rolling devices, each rolling device comprises a supporting plate group arranged at two ends of the rolling device, a rolling shaft clamped between the supporting plate groups, and a roller sleeved outside the rolling shaft.

2. The auxiliary panel transmission as defined in claim 1, wherein: the net belt is formed by twisting a plurality of twisted iron wires.

3. The auxiliary panel transmission as defined in claim 1, wherein: the support plate group comprises an inner support plate connected with the mesh belt and an outer support plate connected with the connecting chain.

4. An auxiliary panel transmission as claimed in claim 3, wherein: the rolling shaft comprises an inner side surface facing one side of the mesh belt and an outer side surface facing away from one side of the mesh belt.

5. The auxiliary panel transmission as defined in claim 4, wherein: the inner support plate comprises an inner abutting surface abutting against the torsion joint part and an inner clamping part connected with the inner side surface.

6. The auxiliary panel transmission as defined in claim 4, wherein: the outer support plate comprises an outer abutting surface abutting against the support surface and an outer clamping part connected with the outer side surface.

7. The auxiliary panel transmission as defined in claim 1, wherein: the drum includes a through hole.

8. The auxiliary panel transmission of claim 7, wherein: the diameter of the through hole is larger than that of the rolling shaft.

9. The auxiliary panel transmission of claim 8, wherein: the through hole is not coaxial with the rolling shaft.