CN213140440U - Conveying device - Google Patents

Abstract

The utility model discloses a conveyer for just, realize the buffer memory to the material above conveyer. The transfer device includes a first transfer track, a second transfer track, and a top stop mechanism. The first conveying track and the second conveying track are used for conveying materials. The jacking mechanism comprises a jacking component and a jacking power mechanism, and the jacking power mechanism comprises a seat part and a telescopic part which can move relatively. The telescopic piece is fixedly connected with the bottom of the jacking component. The jacking component is positioned between the first conveying track and the second conveying track, and a supporting surface at the top of the jacking component is used for supporting the materials. The jacking power mechanism is used for driving the jacking component to move along the vertical direction so as to enable the supporting surface of the jacking component to move between the first position and the second position. The conveying surface of the first conveying track and the conveying surface of the second conveying track are arranged between the first position and the second position, and the jacking part is driven by the jacking power mechanism, so that the materials can be conveniently cached on the conveying device.

Description

Conveying device

Technical Field

The utility model relates to a transfer apparatus technical field especially relates to a conveyer.

Background

The conveying equipment can convey the materials through the conveying belt so as to improve the treatment efficiency of the materials.

Existing conveying equipment is often provided with two conveyor chains through which the material is conveyed. In some scenarios, buffering of material on the conveyor chain is required to stop the conveying operation. The existing treatment mode is to stop the conveying work of the conveying chain and to make the materials still on the conveying chain. Due to the fact that the conveying equipment needs to be started and stopped frequently, the processing method consumes long time in the processing process, influences all materials on the conveying equipment, and is inconvenient to operate.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a conveyer for just, realize the buffer memory to the material above conveyer.

To achieve the purpose, the embodiment of the present invention adopts the following technical solutions:

a transfer device includes a first transfer track, a second transfer track, and a top stop mechanism;

the conveying surface of the first conveying track and the conveying surface of the second conveying track are used for cooperatively conveying materials;

the jacking mechanism comprises a jacking component and a jacking power mechanism;

the jacking power mechanism comprises a seat part and a telescopic part which can move relatively;

the telescopic piece is fixedly connected with the bottom of the jacking component;

the jacking component is positioned between the first conveying track and the second conveying track, and a supporting surface at the top of the jacking component is used for supporting the materials;

the jacking power mechanism is used for driving the jacking component to move along the vertical direction so as to enable the supporting surface of the jacking component to move between a first position and a second position, the first position is higher than the conveying surface of the first conveying rail and the conveying surface of the second conveying rail, and the second position is lower than the conveying surface of the first conveying rail and the conveying surface of the second conveying rail.

Optionally, the transfer device further comprises a support, and the top stop mechanism further comprises a connecting mechanism;

the first conveying track and the second conveying track are arranged on the bracket;

the connecting mechanism comprises a first connecting piece, a second connecting piece and a fixing piece;

one end of the fixing piece is fixedly connected with the first connecting piece, the other end of the fixing piece is fixedly connected with the second connecting piece, and the first connecting piece and the second connecting piece are both fixedly connected with the bracket;

the first conveying track and the second conveying track are positioned above the fixing piece;

the seat part is fixedly connected with the fixing piece.

Optionally, the transmission further comprises a gear stop plate and a gear stop cylinder;

a piston rod of the gear stop cylinder is fixedly connected with the gear stop plate;

the stop plate and the stop cylinder are located between the first transfer rail and the second transfer rail;

the stop plate is positioned downstream of the top stop mechanism along the conveying direction of the materials;

the gear stopping cylinder is used for driving the gear stopping plate to block the movement of the material when rising along the vertical direction and driving the gear stopping plate to release the material when falling along the vertical direction.

Optionally, the conveyor further comprises a stop sensor;

the gear stop sensor is arranged on the bracket and is in signal connection with the gear stop cylinder;

the gear stop sensor is used for controlling the gear stop cylinder to lift the gear stop plate along the vertical direction to block the transmission of the material when the material is detected to be transmitted to a gear stop detection position, wherein the gear stop plate is positioned at the downstream of the gear stop detection position along the transmission direction of the material.

Optionally, the number of the top stop mechanisms is multiple;

the plurality of top stop mechanisms are sequentially arranged along the conveying direction of the materials.

Optionally, the conveyor further comprises a synchronizing shaft, a first synchronizing wheel and a second synchronizing wheel;

one end of the synchronizing shaft is fixedly connected with the first synchronizing wheel, and the other end of the synchronizing shaft is fixedly connected with the second synchronizing wheel;

the first conveying track is arranged around the first synchronizing wheel, and the second conveying track is arranged around the second synchronizing wheel;

the first conveying track and the second conveying track are used for synchronously rotating through the synchronous shaft and the first synchronous wheel and the second synchronous wheel.

Optionally, the conveyor further comprises a first edge cleaning head and a second edge cleaning head;

the first side dust collection head and the second side dust collection head are arranged above the conveying surface of the first conveying rail and the conveying surface of the second conveying rail;

the area between the first side dust collection head and the second side dust collection head is used for allowing the materials to pass through;

the first side dust collection head and the second side dust collection head are used for carrying out dust removal operation on the materials.

Optionally, the jacking component comprises a first support rod, a second support rod and a support connecting plate;

one end of the support connecting plate is fixedly connected with the first support rod, and the other end of the support connecting plate is fixedly connected with the second support rod;

the telescopic piece is fixedly connected with the bottom of the support connecting plate;

the first supporting rod and the second supporting rod are used for supporting the materials.

Optionally, both ends of the first support bar and both ends of the second support bar are provided with jacking pads, and the jacking pads are elastic pieces;

the top surface of the jacking pad is a supporting surface of the jacking component.

Optionally, the stand comprises a first frame, a second frame, a first crossbar and a second crossbar;

two ends of the first cross rod are respectively connected with one end of the first frame and one end of the second frame, and two ends of the second cross rod are respectively connected with the other end of the first frame and the other end of the second frame;

the first conveying track is arranged on one side of the first frame close to the second frame, and the second conveying track is arranged on one side of the second frame close to the first frame;

the first connecting piece is fixedly connected with the bottom of the first frame, and the second connecting piece is fixedly connected with the bottom of the second frame;

the jacking power mechanism is a jacking cylinder, the seat part is a cylinder body of the jacking cylinder, and the telescopic piece is a piston rod of the jacking cylinder.

The utility model has the advantages that:

the utility model discloses conveyer includes first transfer orbit, second transfer orbit and top stop mechanism. The conveying surface of the first conveying track and the conveying surface of the second conveying track are used for cooperatively conveying the materials, so that the materials are conveyed on the conveying surfaces of the first conveying track and the second conveying track. The jacking mechanism comprises a jacking component and a jacking power mechanism, and the jacking power mechanism comprises a seat part and a telescopic part which can move relatively. The telescopic piece is fixedly connected with the bottom of the jacking component. The jacking component is positioned between the first conveying track and the second conveying track, and a supporting surface at the top of the jacking component is used for supporting the materials. The jacking power mechanism is used for driving the jacking component to move along the vertical direction so as to enable the supporting surface of the jacking component to move between the first position and the second position. Wherein the first position is a position higher than the conveying surfaces of the first conveying rail and the second conveying rail, and the second position is a position lower than the conveying surfaces of the first conveying rail and the second conveying rail. Like this, the material drives jack-up part along vertical direction rebound on first transfer orbit's transfer surface and second transfer orbit's transfer surface as jack-up power unit to when making jack-up part's holding surface move to the primary importance, this material can be supported to the holding surface of jack-up part, makes the material break away from first transfer orbit's transfer surface and second transfer orbit's transfer surface, on the holding surface of jack-up part, has realized the buffer memory to the material. When jack-up power unit drove jack-up part and moves down along vertical direction, the supporting surface of jack-up part moves towards the second position, and the material falls back on first transfer orbit's conveying face and second transfer orbit's conveying face to, first transfer orbit's conveying face and second transfer orbit's conveying face can continue to convey the material. This realizes just realizing the buffer memory of material above the conveyer.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of a conveying device according to an embodiment of the present invention;

fig. 2 is a top view of a conveyor according to an embodiment of the present invention;

fig. 3 is a schematic view of a partial structure of a conveying device according to an embodiment of the present invention.

In the figure:

1. a first transfer track; 2. a second transfer rail; 3. a top stop mechanism; 4. a top stop sensor; 5. a jacking power mechanism; 6. a second connecting member; 7. a fixing member; 8. a gear stop plate; 9. a gear stop cylinder; 10. a synchronizing shaft; 11. a second synchronizing wheel; 12. a first side dust collection head; 13. a second side dust collection head; 14. a first support bar; 15. a second support bar; 16. supporting the connecting plate; 17. jacking up the pad; 18. a first frame; 19. a second frame; 20. a first cross bar; 21. a second cross bar; 22. and (3) feeding.

Detailed Description

An embodiment of the utility model provides a conveyer for just realize the buffer memory to material 22 above conveyer.

In order to make the objects, features and advantages of the present invention more obvious and understandable, the drawings in the embodiments of the present invention are combined below to clearly and completely describe the technical solutions in the embodiments of the present invention, and obviously, the embodiments described below are only some embodiments of the present invention, but not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a conveying device provided in an embodiment of the present invention, and fig. 2 is a top view of a conveying device provided in an embodiment of the present invention.

Referring to fig. 1, 2 and 3, a transfer apparatus according to an embodiment of the present invention includes a first transfer rail 1, a second transfer rail 2, and a top stop mechanism 3.

Wherein the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2 are used for co-operating conveying of the material 22. In other words, the material 22 is conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2. In a specific example, the conveying face of the first conveying track 1 and the conveying face of the second conveying track 2 may be located on the same plane.

In the embodiment of the present invention, there are various implementations of the first conveying track 1 and the second conveying track 2, for example, in the example shown in fig. 1, the first conveying track 1 and the second conveying track 2 are transmission chains. In other examples, the first conveying track 1 and the second conveying track 2 may also be conveying belts, etc., and the embodiment of the present invention is not particularly limited thereto.

In a specific example, the transfer trajectory of the first transfer rail 1 and the transfer trajectory of the second transfer rail 2 may be arranged in parallel to smoothly transfer the material 22.

The jacking mechanism 3 comprises a jacking component and a jacking power mechanism 5, and the jacking power mechanism 5 comprises a seat part and a telescopic part which can move relatively. Wherein, the telescopic part of the jacking power mechanism 5 is fixedly connected with the bottom of the jacking part.

A jacking member is located between the first transfer track 1 and the second transfer track 2, the supporting surface at the top of the jacking member being used to support the material 22.

The jacking power mechanism 5 is used for driving the jacking component to move along the vertical direction so as to enable the supporting surface of the jacking component to move between the first position and the second position. Specifically, the jacking power mechanism 5 may drive the jacking member to move upward along the vertical direction, so that the supporting surface of the jacking member moves to the first position. The jacking power mechanism 5 drives the jacking component to move downwards along the vertical direction so as to enable the supporting surface of the jacking component to move to the second position.

In the embodiment of the present invention, the first position is a position higher than the transfer surface of the first transfer rail 1 and the transfer surface of the second transfer rail 2, and the second position is a position lower than the transfer surface of the first transfer rail 1 and the transfer surface of the second transfer rail 2.

Thus, the material 22 is conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2, and when the jacking power mechanism 5 drives the jacking component to move upwards along the vertical direction so as to move the supporting surface of the jacking component to the first position, the supporting surface of the jacking component can support the material 22, so that the material 22 is separated from the conveying surfaces of the first conveying track 1 and the second conveying track 2. At this point, on the support surface of the jacking member, a buffer of the material 22 is achieved.

If the materials 22 need to be conveyed continuously, the jacking power mechanism 5 drives the jacking component to move downwards along the vertical direction, at the moment, the supporting surface of the jacking component moves towards the second position, the materials 22 can fall back onto the conveying surface of the first conveying rail 1 and the conveying surface of the second conveying rail 2, and therefore the conveying surfaces of the first conveying rail 1 and the second conveying rail 2 can convey the materials 22 continuously. This achieves that the buffer of the material 22 is facilitated above the conveyor.

It should be understood that there are many implementations of the jacking mechanism 5, for example, the jacking mechanism 5 is an electric cylinder, the moving output end of the electric cylinder and the bottom of the jacking component are fixedly connected in the examples of fig. 1 and 3, the jacking mechanism 5 is a jacking cylinder, the seat part is the cylinder body of the jacking cylinder, and the telescopic part is the piston rod of the jacking cylinder. The jacking cylinder can control the piston rod to move in a telescopic mode along the vertical direction relative to the cylinder body.

In order to stably arrange the transfer device, optionally, as shown in fig. 1 and 3, the transfer device further includes a stand, and the overhead parking mechanism 3 further includes a connecting mechanism.

Wherein, the first transfer rail 1 and the second transfer rail 2 are both disposed on the support to fix the positions of the first transfer rail 1 and the second transfer rail 2.

The connecting mechanism comprises a first connecting piece, a second connecting piece 6 and a fixing piece 7. One end of the fixing member 7 is fixedly connected with the first connecting member, and the other end of the fixing member 7 is fixedly connected with the second connecting member 6. The first and second connectors 6 are fixedly connected to the bracket, so that the position of the connecting mechanism is fixed.

In the embodiment of the present invention, the first conveying rail 1 and the second conveying rail 2 are located above the fixing member 7, and the seat portion of the jacking power mechanism 5 is fixedly connected to the fixing member 7. In this way, the position of the jack-up power mechanism 5 is fixed by the connecting mechanism, and the jack-up power mechanism 5 can drive the jack-up member to move the support surface of the jack-up member between the first position and the second position.

In the embodiment of the present invention, the specific implementation manner of the support is multiple, for example, the support is two independent support structures, the first conveying rail 1 is installed on one support structure, and the second conveying rail 2 is installed on another support structure.

In one particular implementation, as shown in fig. 3, the stand includes a first frame 18, a second frame 19, a first crossbar 20, and a second crossbar 21.

Wherein, two ends of the first cross bar 20 are respectively connected with one end of the first frame 18 and one end of the second frame 19, and two ends of the second cross bar 21 are respectively connected with the other end of the first frame 18 and the other end of the second frame 19.

Thus, the first frame 18, the second frame 19, the first cross bar 20 and the second cross bar 21 constitute a frame structure.

The first transfer rail 1 is arranged on the side of the first frame 18 close to the second frame 19 and the second transfer rail 2 is arranged on the side of the second frame 19 close to the first frame 18, whereby the first transfer rail 1 and the second transfer rail 2 are located between the first frame 18 and the second frame 19, facilitating the mounting of the first transfer rail 1 and the second transfer rail 2 and avoiding that the first frame 18 and the second frame 19 obstruct the transfer of the material 22 on the first transfer rail 1 and the second transfer rail 2.

In addition, the first connecting member is fixedly connected to the bottom of the first frame 18, and the second connecting member 6 is fixedly connected to the bottom of the second frame 19.

To facilitate the placement of the conveyor, support feet may be mounted on the bottom of the first frame 18 and the second frame 19 to support the conveyor.

In the present embodiment, the support surface at the top of the jacking members is used to support the material 22. In other words, the jacking members may jack the material 22. At the top of the jacking members there is a support surface which can abut the material 22.

In order to reduce the loss of material and to ensure the firmness of the jacking members, the jacking members optionally comprise a first support bar 14, a second support bar 15 and a support tie 16, as shown in fig. 1 and 2.

Wherein, one end of the support connecting plate 16 is fixedly connected with the first support bar 14, and the other end of the support connecting plate 16 is fixedly connected with the second support bar 15.

The telescopic part of the jacking power mechanism 5 is fixedly connected with the bottom of the support connecting plate 16, for example, when the jacking power mechanism 5 is a jacking cylinder, the jacking cylinder is positioned below the support connecting plate 16, and a piston rod of the jacking cylinder is fixedly connected with the bottom of the support connecting plate 16.

In this example, a first support bar 14 and a second support bar 15 are used to support the material 22. That is, the jacking member supports the material 22 by the first support bar 14 and the second support bar 15 to jack up the material 22.

In order to avoid damage to the material 22 after collision, optionally, as shown in fig. 1, both ends of the first support bar 14 and both ends of the second support bar 15 are provided with a jacking pad 17, and the jacking pad 17 is an elastic member, wherein the top surface of the jacking pad 17 is a supporting surface of the jacking member. Thus, the jacking member supports the material 22 through the elastic jacking pad 17, and the jacking pad 17 has a buffering function, thereby avoiding damaging the material 22. Meanwhile, in some embodiments, after the jacking pad 17 rises, the material 22 conveyed upstream can be blocked, at this time, the material 22 collides with the side surface of the jacking pad 17, and the jacking pad 17 has a buffering function because the jacking pad 17 is an elastic member, thereby avoiding damaging the material 22.

Optionally, as shown in fig. 1 and 2, the transfer device further comprises a shift stop plate 8 and a shift stop cylinder 9. Wherein, the piston rod of the gear stop cylinder 9 is fixedly connected with the gear stop plate 8. The shift stop plate 8 may be a plate-shaped structure, and after the shift stop plate 8 is fixedly connected with the piston rod of the shift stop cylinder 9, the shift stop cylinder 9 may drive the shift stop plate 8 to move.

A gear stop plate 8 and a gear stop cylinder 9 are located between the first transfer rail 1 and the second transfer rail 2.

The stop plate 8 is located downstream of the top stop mechanism 3 in the conveying direction of the material 22. Specifically, when the material 22 is conveyed on the conveying surface of the first conveying rail 1 and the conveying surface of the second conveying rail 2, the material passes through the position of the top stop mechanism 3 and then passes through the position of the stop plate 8.

The gear stop cylinder 9 is used for blocking the movement of the material 22 when driving the gear stop plate 8 to ascend along the vertical direction, and releasing the material 22 when driving the gear stop plate 8 to descend along the vertical direction.

For example, with reference to fig. 2, the cylinder body of the deactivation cylinder 9 is mounted on a support, in particular on the first crossbar 20. The materials 22 are conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2, the gear stopping cylinder 9 extends out of the piston rod to drive the gear stopping plate 8 to rise along the vertical direction, and the materials 22 in the transmission are stopped and conveyed by the gear stopping plate 8 after contacting the gear stopping plate 8. At this time, the material 22 may be subjected to sliding friction on the conveying surface of the first conveying rail 1 and the conveying surface of the second conveying rail 2. When the stop cylinder 9 retracts the piston rod to drive the stop plate 8 to descend along the vertical direction, the stop plate 8 no longer blocks the material 22, the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2 continue to convey the material 22, and the material 22 passes above the stop plate 8.

In order to increase the degree of automation, the transfer device optionally further comprises a gear stop sensor, which is arranged on the carriage and is in signal connection with the gear stop cylinder 9, so that the gear stop sensor can control the gear stop cylinder 9.

The transmission device is provided with a gear stop detection position, and the gear stop detection position is the detection range of the gear stop sensor. When the material 22 is located at the stop detection position, the stop sensor can detect the material 22 and trigger the stop sensor to generate a signal. The stop plate 8 is located downstream of the stop detection position in the conveying direction of the material 22. In other words, when the material 22 is conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2, the material 22 passes through the stop detection position and then passes through the position where the stop plate 8 is located.

The stop sensor serves to control the stop cylinder 9 to raise the stop plate 8 in a vertical direction to block the transfer of the material 22 when it is detected that the material 22 is transferred to the stop detection position.

For example, the material 22 is conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2, when the material 22 is conveyed to the gear stop detection position, the gear stop sensor is triggered to generate a signal, the gear stop sensor sends a signal to the gear stop cylinder 9, the gear stop cylinder 9 is controlled to lift the gear stop plate 8 in the vertical direction, and the gear stop plate blocks the material 22 and blocks the conveying of the material 22.

In the embodiment of the present invention, the number of the top stop mechanisms 3 may be one or more. For example, as shown in fig. 1 and 2, the number of the top stop mechanisms 3 is plural, wherein the plural top stop mechanisms 3 are arranged in sequence in the conveying direction of the material 22. In this way, the material 22 passes through the top stop mechanisms 3 in order while being conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2.

The embodiment of the utility model provides an in, when the quantity of top stop mechanism 3 is a plurality of, arrange in proper order along the direction of transfer of material 22 because of a plurality of top stop mechanisms 3 to, from the low reaches to the upper reaches of the direction of transfer of material 22, a plurality of top stop mechanisms 3 can drive jack-up part jack-up in proper order, are located terminal top stop mechanism 3, stop the shelves of material 22 because of shelves that rise along vertical direction stop plate 8, make material 22 be located this top stop mechanism 3's top, be convenient for by this jack-up part jack-up of top stop mechanism 3. In addition, the jacking member that is raised first in the vertical direction may block the transfer of the subsequent material 22, for example, the second support bar 15 or the jacking pad 17 of the jacking member may block the transfer of the subsequent material 22 after being raised. Thereby, the material 22 is positioned above the adjacent overhead stop mechanism 3, and the jacking member of the overhead stop mechanism 3 is facilitated to jack up the subsequent material 22.

In the embodiment of the utility model provides an, optionally, the utility model discloses conveyer still stops inductor 4 including the top, and jack-up power unit 5 stops inductor 4 signal connection with the top.

The top stop sensor 4 is arranged on a support, for example on the first frame 18 or the second frame 19, the top stop sensor 4 being adjacent to the jacking members. When the jacking sensor 4 detects that the material 22 is arranged above the jacking part, the jacking sensor 4 sends a signal to the jacking power mechanism 5, and the jacking power mechanism 5 can drive the jacking part to move along the vertical direction. In this way it is ensured that the support surface at the top of the jacking members can jack up against the material 22.

In order to achieve a synchronized transfer of the first transfer track 1 and the second transfer track 2, the transfer device optionally further comprises a synchronizing shaft 10, a first synchronizing wheel and a second synchronizing wheel 11.

One end of the synchronizing shaft 10 is fixedly connected with the first synchronizing wheel, and the other end of the synchronizing shaft 10 is fixedly connected with the second synchronizing wheel 11. Specifically, the synchronizing shaft 10 is located between the first synchronizing wheel and the second synchronizing wheel 11, one end of the synchronizing shaft 10 is fixedly connected with the side surface of the first synchronizing wheel, and the other end of the synchronizing shaft 10 is fixedly connected with the side surface of the second synchronizing wheel 11. Thus, the first and second synchronizing wheels 11 are rotated synchronously by the synchronizing shaft 10.

The first transfer rail 1 is disposed around the first timing wheel, and the second transfer rail 2 is disposed around the second timing wheel 11. The first and second transfer rails 1 and 2 are adapted to be rotated in synchronization by a synchronizing shaft 10, a first synchronizing wheel, and a second synchronizing wheel 11.

The first conveying track 1 and the first synchronizing wheel rotate synchronously, the second conveying track 2 and the second synchronizing wheel 11 rotate synchronously, and the first synchronizing wheel and the second synchronizing wheel 11 rotate synchronously under the action of the synchronizing shaft 10, so that the first conveying track 1 and the second conveying track 2 can rotate synchronously to cooperatively convey the materials 22.

Optionally, the conveyor further comprises a first edge cleaning head 12 and a second edge cleaning head 13. Wherein, the first side dust suction head 12 and the second side dust suction head 13 are both provided with dust suction openings through which dust can be absorbed.

Wherein, the first side dust-collecting head 12 and the second side dust-collecting head 13 are both arranged above the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2. The area between the first edge cleaning head 12 and the second edge cleaning head 13 is used for the passage of material 22. In other words, the first edge cleaning head 12 and the second edge cleaning head 13 are spaced above the conveying surface of the first conveying path 1 and the conveying surface of the second conveying path 2, so that the materials 22 can pass through the area between the first edge cleaning head 12 and the second edge cleaning head 13.

The first side suction head 12 and the second side suction head 13 are used for performing a dust removing operation on the materials 22. Specifically, one end of the first side suction head 12 is communicated with the vacuum suction device, and one end of the second side suction head 13 is communicated with the vacuum suction device, so that the suction port of the first side suction head 12 and the suction port of the second side suction head 13 can suck air when the vacuum suction device works. When the material 22 is located in the area between the first side dust collecting head 12 and the second side dust collecting head 13, the dust collecting opening of the first side dust collecting head 12 and the dust collecting opening of the second side dust collecting head 13 face the material 22, and the dust collecting opening of the first side dust collecting head 12 and the dust collecting opening of the second side dust collecting head 13 can absorb the dust on the material 22, so that the dust removing operation is realized.

For example, the first edge cleaning head 12 is mounted on the first frame 18, and the second edge cleaning head 13 is mounted on the second frame 19, and more specifically, the first edge cleaning head 12 and the second edge cleaning head 13 are also positioned above the conveying surface of the first conveying rail 1 and the conveying surface of the second conveying rail 2. The materials 22 are conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2, and when the materials 22 are positioned in the area between the first side dust suction head 12 and the second side dust suction head 13, and the vacuum suction device works, dust on the materials 22 is absorbed by the dust suction ports of the first side dust suction head 12 and the dust suction ports of the second side dust suction head 13 which face the edges of the materials 22.

It should be understood that there are a variety of implementations of the material 22 of embodiments of the present invention, and in one particular example, the material 22 is a tray and a charger component, wherein the charger component is placed on the tray. The tray is conveyed on the conveying surface of the first conveying rail 1 and the conveying surface of the second conveying rail 2.

The utility model discloses conveyer can be applied to on the production line to realize buffer memory material 22 on the production line.

For example, the charger component is a bottom case of the charger, which is placed on the tray. The conveying surface of the first conveying rail 1 and the conveying surface of the second conveying rail 2 convey the tray on which the bottom chassis is placed. When the tray passes through the region between the first side cleaning head 12 and the second side cleaning head 13, the first side cleaning head 12 and the second side cleaning head 13 can suck dust on the edge of the bottom case to realize dust removal operation. When it is desired to buffer the material 22 on the conveyor, the jacking members may jack up the tray, preventing the tray from continuing to be conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2. The jacking component moves downwards to drive the tray to fall back to the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2, and the tray can be conveyed continuously. Because each process on the production line is different in time use and temporary errors can occur, the materials 22 are required to be temporarily buffered sometimes, and the situation that the production is influenced by too many semi-finished products accumulated in the previous process is avoided.

To sum up, the utility model discloses conveyer of embodiment includes first transfer orbit 1, second transfer orbit 2 and top stop mechanism 3. The conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2 are used for co-operating conveying of the material 22, so that the material 22 is conveyed on the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2. The jacking mechanism 3 comprises a jacking component and a jacking power mechanism 5, and the jacking power mechanism 5 comprises a seat part and a telescopic part which can move relatively. The telescopic piece is fixedly connected with the bottom of the jacking component. A jacking member is located between the first transfer track 1 and the second transfer track 2, the supporting surface at the top of the jacking member being used to support the material 22. The jacking power mechanism 5 is used for driving the jacking component to move along the vertical direction so as to enable the supporting surface of the jacking component to move between the first position and the second position. Wherein the first position is a position higher than the conveying surface of the first conveying rail 1 and the conveying surface of the second conveying rail 2, and the second position is a position lower than the conveying surface of the first conveying rail 1 and the conveying surface of the second conveying rail 2. Like this, material 22 is on the transfer surface of first transfer orbit 1 and the transfer surface of second transfer orbit 2, and when jack-up power unit 5 drove the jack-up part along vertical direction upward movement to when making the holding surface of jack-up part move to the primary importance, the holding surface of jack-up part can support this material 22, makes material 22 break away from the transfer surface of first transfer orbit 1 and the transfer surface of second transfer orbit 2, on the holding surface of jack-up part, has realized the buffer memory to material 22. When the jacking power mechanism 5 drives the jacking component to move downwards along the vertical direction, the supporting surface of the jacking component moves towards the second position, and the materials 22 fall back to the conveying surface of the first conveying track 1 and the conveying surface of the second conveying track 2, so that the conveying surfaces of the first conveying track 1 and the second conveying track 2 can continuously convey the materials 22. This facilitates the buffering of the material 22 on the conveyor.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (10)

1. A transfer device comprising a first transfer track, a second transfer track, and a top stop mechanism;

the conveying surface of the first conveying track and the conveying surface of the second conveying track are used for cooperatively conveying materials;

the jacking mechanism comprises a jacking component and a jacking power mechanism;

the jacking power mechanism comprises a seat part and a telescopic part which can move relatively;

the telescopic piece is fixedly connected with the bottom of the jacking component;

the jacking component is positioned between the first conveying track and the second conveying track, and a supporting surface at the top of the jacking component is used for supporting the materials;

the jacking power mechanism is used for driving the jacking component to move along the vertical direction so as to enable the supporting surface of the jacking component to move between a first position and a second position, the first position is higher than the conveying surface of the first conveying rail and the conveying surface of the second conveying rail, and the second position is lower than the conveying surface of the first conveying rail and the conveying surface of the second conveying rail.

2. The transfer device of claim 1,

the conveying device further comprises a support, and the top stopping mechanism further comprises a connecting mechanism;

the first conveying track and the second conveying track are arranged on the bracket;

the connecting mechanism comprises a first connecting piece, a second connecting piece and a fixing piece;

one end of the fixing piece is fixedly connected with the first connecting piece, the other end of the fixing piece is fixedly connected with the second connecting piece, and the first connecting piece and the second connecting piece are both fixedly connected with the bracket;

the first conveying track and the second conveying track are positioned above the fixing piece;

the seat part is fixedly connected with the fixing piece.

3. The transfer device of claim 1,

the transmission device also comprises a gear stop plate and a gear stop cylinder;

a piston rod of the gear stop cylinder is fixedly connected with the gear stop plate;

the stop plate and the stop cylinder are located between the first transfer rail and the second transfer rail;

the stop plate is positioned downstream of the top stop mechanism along the conveying direction of the materials;

the gear stopping cylinder is used for driving the gear stopping plate to block the movement of the material when rising along the vertical direction and driving the gear stopping plate to release the material when falling along the vertical direction.

4. The transfer device of claim 3,

the conveying device further comprises a bracket and a gear stop sensor;

the gear stop sensor is arranged on the bracket and is in signal connection with the gear stop cylinder;

the gear stop sensor is used for controlling the gear stop cylinder to lift the gear stop plate along the vertical direction to block the transmission of the material when the material is detected to be transmitted to a gear stop detection position, wherein the gear stop plate is positioned at the downstream of the gear stop detection position along the transmission direction of the material.

5. The transfer device of claim 3,

the number of the top stop mechanisms is multiple;

the plurality of top stop mechanisms are sequentially arranged along the conveying direction of the materials.

6. The transfer device of claim 2,

the conveying device further comprises a synchronizing shaft, a first synchronizing wheel and a second synchronizing wheel;

one end of the synchronizing shaft is fixedly connected with the first synchronizing wheel, and the other end of the synchronizing shaft is fixedly connected with the second synchronizing wheel;

the first conveying track is arranged around the first synchronizing wheel, and the second conveying track is arranged around the second synchronizing wheel;

the first conveying track and the second conveying track are used for synchronously rotating through the synchronous shaft and the first synchronous wheel and the second synchronous wheel.

7. The transfer device of claim 2,

the conveying device also comprises a first side dust collection head and a second side dust collection head;

the first side dust collection head and the second side dust collection head are arranged above the conveying surface of the first conveying rail and the conveying surface of the second conveying rail;

the area between the first side dust collection head and the second side dust collection head is used for allowing the materials to pass through;

the first side dust collection head and the second side dust collection head are used for carrying out dust removal operation on the materials.

8. The transfer device of claim 1,

the jacking component comprises a first supporting rod, a second supporting rod and a supporting connecting plate;

one end of the support connecting plate is fixedly connected with the first support rod, and the other end of the support connecting plate is fixedly connected with the second support rod;

the telescopic piece is fixedly connected with the bottom of the support connecting plate;

the first supporting rod and the second supporting rod are used for supporting the materials.

9. The transfer device of claim 8,

jacking pads are arranged at two end parts of the first supporting rod and two end parts of the second supporting rod, and the jacking pads are elastic pieces;

the top surface of the jacking pad is a supporting surface of the jacking component.

10. The transfer device of claim 2,

the bracket comprises a first frame, a second frame, a first cross bar and a second cross bar;

two ends of the first cross rod are respectively connected with one end of the first frame and one end of the second frame, and two ends of the second cross rod are respectively connected with the other end of the first frame and the other end of the second frame;

the first conveying track is arranged on one side of the first frame close to the second frame, and the second conveying track is arranged on one side of the second frame close to the first frame;

the first connecting piece is fixedly connected with the bottom of the first frame, and the second connecting piece is fixedly connected with the bottom of the second frame;

the jacking power mechanism is a jacking cylinder, the seat part is a cylinder body of the jacking cylinder, and the telescopic piece is a piston rod of the jacking cylinder.

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