CN222573406U - Medical accessory carrier transferring device - Google Patents

Abstract

The utility model provides a medical accessory carrier transferring device, which relates to the technical field of medical accessory production equipment, and particularly comprises a workbench, wherein a first conveying belt and a second conveying belt which are parallel to each other are arranged on the workbench, the conveying directions of the first conveying belt and the second conveying belt are opposite, the medical accessory carrier transferring device further comprises a first platform, a second platform, an adjusting mechanism and a limiting piece, the first platform and the second platform are respectively arranged on two sides of the transferring direction of the first conveying belt and the second conveying belt, the adjusting mechanism is arranged on two sides of the workbench and used for driving a carrier to move in the horizontal direction, and the limiting piece is arranged on the first platform and the second platform. The two conveying belts are arranged on the workbench, the carrier is firstly moved into the adjusting platform in the turning process, the carrier is pushed onto the conveying belts by the adjusting mechanism in the adjusting platform, the carrier receives the same force as the conveying direction of the conveying belts, the stability of the carrier in the turning process is better, and the phenomenon of tilting and overturning caused by too much stress direction of the carrier is avoided.

Description

Medical accessory carrier transferring device

Technical Field

The utility model relates to the technical field of medical accessory production equipment, in particular to a medical accessory carrier transferring device.

Background

The infusion apparatus is a human body infusion mediating mechanism commonly used in modern medical centers and is commonly used in all hospitals and clinics.

The infusion apparatus is automatically assembled during production, medical accessories are required to be placed on the carrier, and the carrier drives the medical accessories to be sequentially conveyed to each assembly station for assembly. In order to ensure the stability and the efficiency of assembly, the smooth and reliable movement of the carrier should be ensured. The carrier is usually recycled, so the assembly production line is also in a closed ring shape, in the prior art, two opposite rolling conveyor belts are arranged on two sides of a tabletop for containing the carrier, the carrier is placed on the conveyor belts and driven to move by the conveyor belts, and when the carrier moves to the end part of the conveyor belts, the carrier is dragged by a dragging mechanism to move to the opposite conveyor belts for reversing movement, so that the reciprocating transfer is formed.

However, in the above transferring manner, when the carrier is reversed, the carrier is directly dragged onto the reverse moving conveyor belt from the conveyor belt, and in the dragging process, two ends of the carrier are respectively positioned on the two opposite rolling conveyor belts, so that the carrier receives forces in two different directions at the same time, and in the moving process, the stability of the carrier is poor, and the carrier is easy to incline and topple due to the forces in two different directions.

Disclosure of utility model

The utility model aims to provide a medical accessory carrier transferring device which is used for solving the technical problem that a carrier is poor in stability in the process of circulating movement in the prior art.

The medical accessory carrier transferring device comprises a workbench, a first conveying belt, a second conveying belt, a first platform, a second platform, an adjusting mechanism and a limiting piece, wherein the first conveying belt and the second conveying belt are arranged on the workbench in parallel, the conveying directions of the first conveying belt and the second conveying belt are opposite, the first platform and the second platform are respectively arranged on two sides of the first conveying belt and the second conveying belt in the transferring direction, the adjusting mechanism is arranged on two sides of the workbench and used for driving a carrier to move in the horizontal direction, and the limiting piece is arranged on the first platform and the second platform.

The first conveyer belt and the second conveyer belt form two conveyer belts of reciprocal transport carrier, the carrier moves to terminal point department along first conveyer belt or second conveyer belt, the carrier of terminal point department is promoted to first platform or second platform by the carrier on the rear conveyer belt, the locating part can block the carrier, avoid the carrier to drop, afterwards, adjustment mechanism drives the carrier by the terminal point department of one conveyer belt to the start point department of another conveyer belt, thereby realize the turning of carrier, the in-process of turning, the carrier is promoted to the conveyer belt by adjustment mechanism in the adjustment platform, receive the same power with conveyer belt direction of transfer, the stability of carrier is better in the turning, be difficult for because of the too much phenomenon that takes place of tilting of carrier atress direction.

The adjusting mechanism further comprises a longitudinal adjusting piece and a transverse pushing piece, the carrier is provided with a connecting portion, the longitudinal adjusting piece is matched with the connecting portion, the moving direction of the transverse pushing piece is the same as the moving direction of the first conveying belt and the second conveying belt, and an included angle is formed between the moving direction of the transverse pushing piece and the moving direction of the longitudinal adjusting piece.

The longitudinal adjusting piece can push the carrier on the first platform beside the end point of the first conveying belt to beside the start point of the second conveying belt, or push the carrier on the second platform beside the end point of the second conveying belt to beside the start point of the first conveying belt, so that the movement of the carrier perpendicular to the conveying directions of the first conveying belt and the second conveying belt is realized. The transverse pushing piece pushes the carrier to the first conveying belt or the second conveying belt along the transverse direction, so that the direction change and the transfer of the carrier from the first conveying belt to the second conveying belt or from the second conveying belt to the first conveying belt are realized.

Furthermore, the first platform and the second platform are respectively provided with a chute, and the two longitudinal adjusting parts are respectively arranged in the chute on the first platform and the chute on the second platform.

The sliding chute can guide and limit the longitudinal adjusting piece, and the driving mechanism and the transmission mechanism of the longitudinal adjusting piece can be arranged in the workbench, so that the space on the workbench, the first platform or the second platform is not required to be occupied too much, and sundries in the driving mechanism and the transmission mechanism can be protected.

Further, the extending direction of the sliding groove is perpendicular to the transferring direction of the first conveying belt and the second conveying belt.

The moving direction of the longitudinal adjusting piece is perpendicular to the moving direction of the transverse pushing piece, so that the pushing of the carrier in the horizontal direction is realized.

The adjusting mechanism further comprises a lifting driving part, the longitudinal adjusting part is in transmission connection with the lifting driving part, the lowest position of the top surface of the longitudinal adjusting part is lower than the table top of the workbench, and the highest position of the top surface of the longitudinal adjusting part is higher than the table top of the workbench.

The lifting driving assembly can drive the longitudinal adjusting parts on the first platform and the second platform to move in the vertical direction, when the carrier is pushed, the longitudinal adjusting parts move upwards, after the carrier is pushed, the longitudinal adjusting parts move downwards to reset, the carrier movement on the longitudinal adjusting parts cannot be influenced, and accordingly the reduction of conveying efficiency due to resetting of the moving parts is avoided.

The connecting part is a jack, and the longitudinal adjusting piece is inserted into the jack after ascending to drive the carrier to move and descends to be separated from the jack.

The jack is used for being matched and inserted with the longitudinal adjusting piece so that the longitudinal adjusting piece drives the carrier to move.

The two transverse pushing members are respectively arranged on the first platform and the second platform and are positioned at one end far away from the first conveying belt and the second conveying belt.

When the carrier moves to the first platform or the second platform, the carrier is positioned between the transverse pushing piece and the first conveying belt or the second conveying belt, so that the transverse pushing piece pushes the carrier to the first conveying belt or the second conveying belt.

Further, two of the lateral pushers are respectively used for pushing the carriers to the starting points of the second conveyor belt or the first conveyor belt.

Further, the transverse pushing piece is a push plate.

The limiting piece is a baffle plate, and the baffle plate is arranged at two ends of the first platform and the second platform along the transfer direction of the first conveyor belt and the second conveyor belt.

The beneficial effects are that:

Specifically, the two conveying belts are arranged on the workbench, the first conveying belt and the second conveying belt are arranged in parallel, the conveying directions of the first conveying belt and the second conveying belt are opposite to each other, so that the two conveying belts of the carrier are conveyed in a reciprocating mode, when the carrier follows the first conveying belt or the second conveying belt to the destination point, the carrier at the destination point is pushed onto the first platform or the second platform by the carrier on the rear conveying belt, the limiting parts of the first platform and the second platform can block the carrier, the carrier is prevented from being pushed to the first platform or the second platform to fall off, then the carrier pushed onto the adjusting platform is driven to the starting point of the other conveying belt by the end point of the adjusting mechanism, the carrier continues to move from the starting point to the destination point along with the conveying belt, so that the carrier is turned, the carrier moves into the adjusting platform in advance, the carrier is pushed onto the conveying belt by the adjusting mechanism in the adjusting platform in the turning process, the carrier is easy to be stressed in the same direction as the conveying belt, and the carrier is prevented from being overturned in the turning process.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present utility model, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a medical accessory carrier transferring device according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram II of a medical accessory carrier transferring device according to an embodiment of the present utility model;

FIG. 3 is a schematic top view of a medical accessory carrier transfer apparatus according to an embodiment of the present utility model;

FIG. 4 is an enlarged view of FIG. 1 at A;

Fig. 5 is an enlarged view at B in fig. 2.

Icon:

100-workbench, 110-first conveyer belt, 120-second conveyer belt;

200-adjusting platform, 210-first platform, 220-second platform, 230-limiting piece and 240-chute;

300-adjusting mechanism, 310-longitudinal adjusting piece, 320-transverse pushing piece;

400-carrier and 410-jack.

Detailed Description

The utility model will now be described in further detail with reference to specific examples thereof in connection with the accompanying drawings.

Referring to fig. 1 to 5, the medical accessory carrier 400 transferring device provided in this embodiment includes a workbench 100, a first conveyor belt 110 and a second conveyor belt 120 parallel to each other are disposed on the workbench 100, the conveying directions of the first conveyor belt 110 and the second conveyor belt 120 are opposite, the medical accessory carrier further includes a first platform 210, a second platform 220, an adjusting mechanism 300 and a limiting member 230, the first platform 210 and the second platform 220 are disposed on two sides of the first conveyor belt 110 and the second conveyor belt 120 in the transferring direction, the adjusting mechanism 300 is disposed on two sides of the workbench 100, the adjusting mechanism 300 is used for driving the carrier 400 to move in the horizontal direction, and the limiting member 230 is disposed on the first platform 210 and the second platform 220.

Specifically, the two conveyor belts in the present embodiment are both disposed on the workbench 100, the first conveyor belt 110 and the second conveyor belt 120 are disposed in parallel, and the conveying directions of the first conveyor belt 110 and the second conveyor belt 120 are opposite to form the two conveyor belts of the shuttle carrier 400.

When the carrier 400 moves to the destination point along with the first conveying belt 110 or the second conveying belt 120, the carrier 400 at the destination point is pushed onto the first platform 210 or the second platform 220 by the carrier 400 on the rear conveying belt, and the stoppers 230 of the first platform 210 and the second platform 220 can block the carrier 400, so that the carrier 400 is prevented from being pushed to the outside of the first platform 210 or the second platform 220 to drop.

Subsequently, the carrier 400 pushed onto the adjustment platform 200 by the adjustment mechanism 300 is driven from the end point of one conveyor belt to the start point of the other conveyor belt, and the carrier 400 continues to move from the start point to the end point along with the conveyor belt, so that the turning of the carrier 400 is realized.

The carrier 400 moves into the adjusting platform 200 in advance in the steering process, the carrier 400 is pushed onto the conveying belt by the adjusting mechanism 300 in the adjusting platform 200, the carrier 400 receives the same force as the conveying direction of the conveying belt, the stability of the carrier 400 is better in the steering process, and the phenomenon of tilting and overturning caused by too much stress direction of the carrier 400 is not easy to happen.

In this embodiment, the adjusting mechanism 300 includes a longitudinal adjusting member 310 and a transverse pushing member 320, a connecting portion is disposed on the carrier 400, the longitudinal adjusting member 310 is adapted to the connecting portion, and a moving direction of the transverse pushing member 320 is the same as a transferring direction of the first conveyor belt 110 and the second conveyor belt 120, wherein the moving direction of the transverse pushing member 320 forms an included angle with the moving direction of the longitudinal adjusting member 310.

Specifically, taking the carrier 400 on the first conveyor belt 110 as an example, the carrier 400 on the first conveyor belt 110 moves toward the first platform 210 under the transfer of the first conveyor belt 110, and the carrier 400 at the end point of the first conveying section is pushed into the first platform 210 under the pushing of the rear carrier 400. The longitudinal adjustment member 310 moves from one end near the first conveyor belt 110 to one end near the second conveyor belt 120 on the first platform 210, pushes the carrier 400 located beside the end point of the first conveyor belt 110 on the first platform 210 to the side of the start point of the second conveyor belt 120, and achieves movement of the carrier 400 perpendicular to the conveying direction of the first conveyor belt 110 and the second conveyor belt 120. After the carrier 400 is pushed by the longitudinal adjuster 310, the carrier 400 is located beside the start point of the second conveyor belt 120, and at this time, the carrier 400 is pushed onto the second conveyor belt 120 by the transverse pushing member 320, and the carrier 400 enters the second conveyor belt 120 to move along with the second conveyor belt 120, so as to realize the reversing and transferring of the carrier 400 from the first conveyor belt 110 to the second conveyor belt 120.

Similarly, the carriers 400 on the second conveyor belt 120 move onto the second platform 220, are pushed by the longitudinal adjusting member 310 to the starting point of the first conveyor belt 110, and then are sent onto the first conveyor belt 110 under the pushing of the transverse pushing member 320, so as to realize the reversing and transferring of the carriers 400 from the second conveyor belt 120 to the first conveyor belt 110.

In the present embodiment, the first platform 210 and the second platform 220 are provided with sliding grooves 240, and the two longitudinal adjusting members 310 are respectively disposed in the sliding grooves 240 on the first platform 210 and the second platform 220.

The two longitudinal adjusting members 310 are disposed in the chute 240, and the driving mechanism and the transmission mechanism for driving the longitudinal adjusting members 310 to move are disposed in the first platform 210 and the second platform 220, so that excessive space on the working platform 100, the first platform 210 or the second platform 220 is not required, and sundries are not easy to fall into the driving mechanism and the transmission mechanism.

Taking the chute 240 on the first platform 210 as an example, in this embodiment, the starting point of the chute 240 on the first platform 210 is at the end of the first platform 210, the ending point is at the center of the first platform 210, and when the longitudinal adjustment member 310 pushes the carrier 400, the carrier 400 can be pushed through half of the platform, so that the carrier 400 just reaches a position opposite to the starting point of the second conveyor belt 120.

Similarly, the chute 240 on the second platform 220 has the same structure as the chute 240 on the first platform 210, and can push the carrier 400 just opposite to the start point of the first conveyor belt 110.

In the present embodiment, the extending direction of the chute 240 is perpendicular to the transferring direction of the first conveyor belt 110 and the second conveyor belt 120.

Specifically, the extending direction of the chute 240 is the moving direction of the longitudinal adjuster 310, and the moving direction of the transverse pushing member 320 is the same as the moving direction of the first conveyor belt 110 and the second conveyor belt 120. Therefore, the moving direction of the longitudinal adjuster 310 is perpendicular to the moving direction of the transverse pushing member 320, so that the pushing of the carrier 400 in the horizontal direction is realized, so that the carrier 400 can move from the end point of the first conveyor belt 110 to the start point of the second conveyor belt 120, or from the end point of the second conveyor belt 120 to the start point of the first conveyor belt 110.

In this embodiment, the adjusting mechanism 300 further includes a lifting driving member, the longitudinal adjusting member 310 is in transmission connection with the lifting driving member, the lowest position of the top surface of the longitudinal adjusting member 310 is lower than the table surface of the table 100, and the highest position of the top surface of the longitudinal adjusting member 310 is higher than the table surface of the table 100.

The elevation driving assembly can move in a vertical direction, thereby driving the longitudinal adjuster 310 on the first and second stages 210 and 220 to move.

Specifically, taking the longitudinal adjustment member 310 and the first platform 210 as an example, when the carrier 400 is pushed to move, the lifting assembly drives the longitudinal adjustment member 310 to move upwards, so that the top end of the longitudinal adjustment member 310 is higher than the first platform 210, and the carrier 400 on the first platform 210 can be pushed by the longitudinal adjustment member 310 when moving. After pushing the carrier 400 to the preset position, the lifting assembly drives the longitudinal adjustment member 310 to move downward, so that the top end of the longitudinal adjustment member 310 is lower than the first platform 210, the longitudinal adjustment member 310 is retracted into the chute 240 to perform the reset movement, and the carrier 400 on the longitudinal adjustment member 310 is not affected to enter the first platform 210, thereby avoiding the reduction of the conveying efficiency due to the reset of the moving member.

Similarly, the movement mode of the longitudinal adjustment member 310 on the second platform 220 is the same as that of the longitudinal adjustment member 310 on the first platform 210, and the carrier 400 on the longitudinal adjustment member 310 can be prevented from entering the second platform 220 under the auxiliary cooperation of the lifting assembly and the chute 240.

In this embodiment, the connection portion is a jack 410. The longitudinal adjustment member 310 is lifted and then inserted into the insertion hole 410 to drive the carrier 400 to move, and lowered to be separated from the insertion hole 410.

Specifically, the two sets of jacks 410 in the present embodiment are respectively disposed at two ends of the base, and the two sets of jacks 410 are respectively used for mating with the longitudinal adjustment members 310 on the first platform 210 and the second platform 220.

In addition, it should be noted that, in the present embodiment, there are four longitudinal adjustment members 310, two first platforms 210 and two second platforms 220 respectively, and accordingly, two insertion holes 410 of each group on the carrier 400 are two, and the two insertion holes 410 can cooperate to form two stress points during pushing, so that the pushing direction is more stable.

In addition, the driving and lifting of the translation of the longitudinal adjusting member 310 can be realized by an air cylinder, a screw rod or a motor, and the longitudinal adjusting members 310 on the first platform 210 and the second platform 220 can be driven by a driving member connected with a transmission mechanism.

In the present embodiment, there are two lateral pushing members 320, and two lateral pushing members 320 are respectively disposed on the first platform 210 and the second platform 220 and are located at one end far from the first conveyor belt 110 and the second conveyor belt 120.

The two transverse pushing members 320 are respectively located at two ends far away from the first conveyor belt 110 and the second conveyor belt 120, so that when the carrier 400 moves onto the first platform 210 or the second platform 220, the carrier 400 is located between the transverse pushing members 320 and the first conveyor belt 110 or the second conveyor belt 120, so that the transverse pushing members 320 push the carrier 400 onto the first conveyor belt 110 or the second conveyor belt 120.

In the present embodiment, two lateral pushers 320 are used to push the carriers 400 to the start of the second conveyor belt 120 or the first conveyor belt 110, respectively.

Specifically, taking the second platform 220 as an example, the transverse pushing member 320 on the second platform 220 is disposed at one side of the starting point of the first conveying portion, and the moving direction of the transverse pushing member 320 is the same as the conveying direction of the first conveying belt 110. The initial position of the transverse pushing member 320 is located at one end of the second platform 220 away from the first conveyor belt 110 and the second conveyor belt 120, and when the transverse pushing member 320 moves, the end of the second platform 220 away from the first conveyor belt 110 and the second conveyor belt 120 moves towards the first conveyor belt 110, so that the carrier 400 is pushed to move onto the first conveyor belt 110, and position adjustment and transfer of the carrier 400 on the second platform 220 are achieved.

Similarly, the moving manner and moving direction of the transverse pushing member 320 on the first platform 210 are the same as the moving manner and moving direction of the transverse pushing member 320 on the second platform 220, and the moving direction of the pushing carrier 400 is opposite, so that the starting position of the transverse pushing member 320 on the first platform 210 is located at one end of the first platform 210 away from the first conveying belt 110 and the second conveying belt 120, and the carrier 400 on the first platform 210 is pushed onto the second conveying belt 120.

In this embodiment, the lateral pushing member 320 is a push plate.

The contact area between the pushing plate and the base of the carrier 400 is larger, the moving direction during pushing is more stable, and the pushing direction deviation is not easy to occur, so that the carrier 400 cannot be smoothly pushed onto the first conveying belt 110 or the second conveying belt 120.

It should be noted that, the driving of the transverse pushing member 320 may be implemented by an air cylinder, a screw rod or a motor, and the driving of the transverse pushing member 320 on the two platforms may be implemented by a driving member connected to a transmission mechanism.

Specifically, in this embodiment, the driving members connected to the transverse pushing members 320 are cylinders, and there are two cylinders, and the transverse pushing members 320 on the first platform 210 and the second platform 220 are respectively and individually connected to one cylinder to achieve individual control. Specifically, the cylinders are horizontally disposed at the edge of the workbench 100, and the moving ends of the two cylinders face the first platform 210 and the second platform 220, respectively, and the lateral pushers 320 on the first platform 210 and the second platform 220 are connected to the moving ends of the two cylinders, respectively, so as to implement the movement of the two lateral pushers 320.

In this embodiment, the limiting member 230 is a baffle plate, and the baffle plate is disposed at two ends of the first platform 210 and the second platform 220 along the transfer direction of the first conveyor belt 110 and the second conveyor belt 120.

The baffle can block the carrier 400, so as to prevent the carrier 400 on the first platform 210 or the second platform 220 from being ejected out of the first platform 210 or the second platform 220 under the pushing of the subsequent carrier 400. In this embodiment, the baffle is disposed on a side of the transverse pushing member 320 away from the first conveyor belt 110 and the second conveyor belt 120.

It should be noted that the above-mentioned embodiments are merely for illustrating the technical solution of the present utility model, and not for limiting the same, and although the present utility model has been described in detail with reference to the above-mentioned embodiments, it should be understood by those skilled in the art that the technical solution described in the above-mentioned embodiments may be modified or some or all of the technical features may be equivalently replaced, and these modifications or substitutions do not deviate from the essence of the corresponding technical solution from the scope of the technical solution of the embodiment of the present utility model.

Claims (10)

1. The medical accessory carrier transferring device comprises a workbench (100), wherein a first conveying belt (110) and a second conveying belt (120) which are parallel to each other are arranged on the workbench (100), the conveying directions of the first conveying belt (110) and the second conveying belt (120) are opposite, and the medical accessory carrier transferring device is characterized by further comprising a first platform (210), a second platform (220), an adjusting mechanism (300) and a limiting piece (230), wherein the first platform (210) and the second platform (220) are respectively arranged on two sides of the conveying direction of the first conveying belt (110) and the second conveying belt (120), the adjusting mechanism (300) is arranged on two sides of the workbench (100), the adjusting mechanism (300) is used for driving the carrier (400) to move in the horizontal direction, and the limiting piece (230) is arranged on the first platform (210) and the second platform (220).

2. The medical accessory carrier transfer device of claim 1, wherein the adjustment mechanism (300) comprises a longitudinal adjustment member (310) and a lateral pushing member (320);

The carrier is provided with a connecting part, and the longitudinal adjusting piece (310) is matched with the connecting part;

The moving direction of the transverse pushing piece (320) is the same as the transferring direction of the first conveying belt (110) and the second conveying belt (120);

Wherein the moving direction of the transverse pushing piece (320) forms an included angle with the moving direction of the longitudinal adjusting piece (310).

3. The medical accessory carrier transfer apparatus of claim 2, wherein the first platform (210) and the second platform (220) are each provided with a chute (240);

The number of the longitudinal adjusting parts (310) is two, and the longitudinal adjusting parts are respectively arranged in the sliding grooves (240) on the first platform (210) and the second platform (220).

4. A medical accessory carrier transfer apparatus according to claim 3, wherein the direction of extension of the chute (240) is perpendicular to the transfer direction of the first conveyor belt (110) and the second conveyor belt (120).

5. A medical accessory carrier transfer apparatus as in claim 3, wherein the adjustment mechanism (300) further comprises a lift drive;

The vertical adjusting piece (310) is in transmission connection with the lifting driving piece, the lowest position of the top surface of the vertical adjusting piece (310) is lower than the table top of the workbench (100), and the highest position of the top surface of the vertical adjusting piece (310) is higher than the table top of the workbench (100).

6. The medical accessory carrier transfer apparatus of claim 5, wherein the connection portion is a receptacle (410);

The longitudinal adjusting piece (310) is inserted into the jack (410) after being lifted to drive the carrier (400) to move, and is lowered to be separated from the jack (410).

7. The medical accessory carrier transfer device of claim 2, wherein there are two of said lateral pushers (320);

The two transverse pushing members (320) are respectively arranged on the first platform (210) and the second platform (220) and are positioned at one end far away from the first conveying belt (110) and the second conveying belt (120).

8. The medical accessory carrier transfer device of claim 7, wherein two of the lateral pushers (320) are used to push carriers (400) to the start of the second conveyor belt (120) or the first conveyor belt (110), respectively.

9. The medical accessory carrier transfer device of claim 8, wherein the lateral pushing member (320) is a push plate.

10. The medical accessory carrier transfer device of claim 1, wherein the stop (230) is a baffle;

The baffle is arranged at two ends of the first platform (210) and the second platform (220) along the transfer direction of the first conveying belt (110) and the second conveying belt (120).