CN209905921U - Stack type material conveying platform of solar cell module laminating machine - Google Patents

Abstract

The utility model provides a stack type material conveying platform of a solar battery component laminating machine, which aims at the problems of slow cooling speed and low efficiency of the stack type material conveying platform of the solar battery component laminating machine in the prior art, and can improve the cooling speed of the solar battery component, and comprises a rack, a conveying device, a stack device and a lifting device for driving the stack device to move up and down, and also comprises a cooling device arranged on the rack, wherein the cooling device comprises a plurality of fans, the air outlet of each fan faces the stack device and/or a conveying working surface, the stack type material conveying platform of the solar battery component laminating machine provided by the utility model integrates a cooling device on the material conveying platform, and the cooling of the solar battery component is accelerated by air cooling, the cooling effect of the cooling device can play a role in the feeding and discharging processes and the time when the solar battery component temporarily exists in the stack device, greatly quickening the cooling speed and improving the cooling efficiency.

Description

Stack type material conveying platform of solar cell module laminating machine

Technical Field

The utility model relates to a solar module processing field, in particular to solar module laminator stack formula transmission material platform.

Background

The solar cell module laminating machine is a laminating device for processing solar cell modules and comprises a laminating device, a heat preservation device, a feeding device, a discharging device and the like. The current solar cell module laminating machines are developed towards large and even ultra-large sizes, and in order to reduce the occupied space and the turnover space of equipment, the prior art starts to make greater use of the space in the vertical direction. For example, the stacking type conveying platform which can be used as a discharging device and a feeding device of a laminating machine, specifically, the stacking type conveying platform disclosed in chinese patent with application number 201620112068.3, comprises a conveying device for horizontal conveying and a stacking device divided into multiple layers, the conveying device comprises a plurality of rotating parts which are arranged in parallel, the conveying part rotates in the same direction under the driving of a driving device, the stacking device comprises a support rod and a support rod lifting device, the support rod is positioned in the conveying platform, when the lifting device lifts the support rod, the support rod can move back and forth between the lower part and the upper part of the transmission working table, such a stacked structure, since the space in the horizontal direction is partially overlapped with the transfer device, the battery pack can be temporarily stacked on the stacked device, a large number of battery components can be stacked in the vertical space, and a large amount of space can be saved.

In the transmission device of the transmission workbench, adjacent rotating parts are generally transmitted in a belt transmission or chain transmission mode, the supporting rods are usually fixed on a plate-shaped frame body, and at least one transmission structure of the supporting rods and the rotating parts, which needs to be adaptively modified, needs to be provided with a certain abdication design in order to extend the supporting rods between the transmission parts without interference. For example, in the above patent, the position of part of the transmission member is changed by using wheels or rollers to move away from the supporting rod, but the transmission chain becomes long, the transmission efficiency is low, and the cost is high. For example, the gantry type storage and stacking machine for solar cell modules disclosed in chinese patent No. 201210287194.9, in which the support rod is arranged in a cantilever structure to give way to the transmission structure, but this may deteriorate the rigidity and stability of the support rod.

In addition, the temperature of the solar cell module is high after the laminating device is finished, the solar cell module needs to be cooled for preventing scalding, the stacking type conveying material platform can enable the laminating device to finish more laminating work in unit time, the solar cell modules needing to be cooled become more and can be concentrated on the stacking type conveying material platform, and when the conventional natural cooling method is adopted for cooling, the cooling speed is low, and the efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a solar module laminator stack formula transmission material platform to the problem that the transmission material platform cooling rate of solar module laminator adoption stack formula is slow, inefficiency among the prior art, can improve solar module's cooling rate.

The above technical purpose of the present invention can be achieved by the following technical solutions:

a stack type material conveying platform of a solar cell module laminating machine comprises a rack, a conveying device, a stack device, a lifting device and a cooling device, wherein the lifting device drives the stack device to move up and down;

the fans of the cooling device comprise a plurality of side air coolers, the side air coolers are arranged at two sides above the transmission plane of the transmission device, and the side air coolers positioned at the same side are uniformly arranged in rows along the transmission direction of the transmission device;

the fans of the cooling device comprise a plurality of end air coolers, the end air coolers are arranged in rows on the horizontal plane along the transmission direction vertical to the transmission device, and the end air coolers are arranged above the discharge end of the transmission device;

the cooling device also comprises a connecting plate and an angle locking device, wherein end air coolers are fixedly connected onto the connecting plate, the top end of the connecting plate is hinged with a beam of the rack, a hinge axis is horizontally arranged and is perpendicular to the transmission direction of the transmission device, and the angle locking device locks the corner of the connecting plate relative to the beam of the rack;

the angle locking device is a gas spring with two ends respectively hinged on the rack and the connecting plate;

the fan of the cooling device comprises a plurality of surface cooling fans which are uniformly distributed right above and/or right below the stacking device;

the transmission device comprises a plurality of transmission rollers arranged in parallel and a transmission mechanism for transmitting between the adjacent transmission rollers, two ends of each transmission roller are rotatably arranged on the rack, and the transmission mechanism is arranged at the end part of each transmission roller and connected with and transmits the adjacent transmission rollers; the stacking device comprises two supporting frames and a supporting rod which are oppositely arranged; the support rods are horizontally arranged in a layered manner, each layer at least comprises two support rods, and the support rods are horizontally arranged and the length direction of the support rods is vertical to the conveying direction of the conveying device; the supporting frames comprise vertical rods and a cross rod, the length direction of the cross rod is parallel to the transmission direction of the transmission device, the number of the vertical rods in each supporting frame is the same as that of the supporting rods on each layer, all the vertical rods are parallel to each other, the top ends of the vertical rods are fixedly connected to the cross rod, two ends of each supporting rod are fixedly connected to the vertical rods of two supporting frames respectively, and the vertical rods are located between two adjacent transmission rollers; each support frame is connected with the rack in a sliding way through a guide mechanism, and the output end of the lifting device is fixedly connected with the support frame;

each supporting rod is provided with at least two supporting roller sleeves, the supporting roller sleeves are rotatably connected to the supporting rods by taking the axis of the supporting roller sleeves as a shaft, and the rotating axes of the supporting sleeves are parallel to the length direction of the supporting rods;

the lifting device comprises a lifting motor fixedly connected on the rack, a driving bevel gear coaxially and fixedly connected with the output end of the lifting motor, a driven bevel gear meshed with the driving bevel gear, a driving wheel coaxially and fixedly connected with the driven bevel gear, a driven wheel rotatably arranged right above or right below the driving wheel, and a transmission part in belt transmission or chain transmission with the driving wheel and the driven wheel; the output end of the lifting motor is vertically arranged, the axes of the driving wheel and the driven wheel are horizontal and parallel to each other, and the cross rod is fixedly connected with the transmission part.

The utility model discloses following beneficial effect has:

the utility model discloses integrated cooling device at transmission material bench, utilize the forced air cooling with higher speed solar module's cooling, cooling device's cooling effect can play a role in last unloading in-process and solar module have the time of storehouse device temporarily, very big quickening cooling rate, improved cooling efficiency.

Drawings

Fig. 1 is a schematic structural view of an embodiment of a stacked material conveying table of a solar cell module laminating machine, wherein the direction indicated by an arrow is the conveying direction of a conveying device;

FIG. 2 is a partial schematic view of an end-cooling fan in accordance with the present embodiment;

FIG. 3 is a partial schematic view of an exemplary structure of a stacked material conveying table of a solar cell module laminator;

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

fig. 5 is a schematic diagram of a second detection device in the present embodiment.

The description of the reference numerals,

10. a rack; 11. a cross beam; 12. a side frame;

20. a transmission device; 21. a transfer roller;

30. a stacking device; 31. a support frame; 311. a cross bar; 312. erecting a rod; 32. a support rod; 321. supporting the roller sleeve;

40. a lifting device; 41. a lifting motor; 42. a drive bevel gear; 43. a driven bevel gear; 44. a driving wheel; 45. a driven wheel; 46. a transmission member; 47. a connecting shaft;

50. a cooling device; 51. a side air cooler; 52. a terminal air cooler; 53. a surface air cooler; 54. a connecting plate; 55. a gas spring;

60. a solar cell module;

70. a guide mechanism; 71. a slider; 72. a slide rail;

80. a first detection device; 90. and a second detection device.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings. In which like parts are designated by like reference numerals.

A stacked material conveying platform of a solar cell module laminating machine is shown in figure 1 and comprises a platform 10, a conveying device 20 arranged on the platform 10, a stacking device 30 arranged in the conveying device 20 in a falling mode, and a cooling device 50 arranged on the platform 10. The cooling device 50 includes a plurality of fans disposed on the rack 10, air outlets of the fans face a transmission plane of the stacking device 30 and/or the transmission device 20, the solar modules 60 are transmitted on the transmission plane, and the fans blow air to the solar modules 60 stored on the stacking device 30 and located on the transmission device to cool the solar modules 60. The utility model discloses at transmission material bench integrated cooling device 50, utilize the forced air cooling with higher speed solar module 60's cooling, cooling device 50's cooling can play a role in last unloading in-process and solar module 60 keep in the time of storehouse device 30, very big quickening cooling rate, improved cooling efficiency.

The rack comprises two side frames 12 respectively positioned at two sides and a beam 11 connecting the side frames 12 at two sides, wherein the length direction of the beam 11 is perpendicular to the conveying direction of the conveying device 20. As shown in fig. 1, fans in the cooling apparatus 50 are distributed in different orientations, and are classified into a side air cooler 51, an end air cooler 52, and a surface air cooler 53 according to the arrangement orientation. Wherein side air-cooler 51 is the fan of blowing from solar module 60 both sides, and side air-cooler distributes on the side frame 12 of rack both sides, and what the transmission direction of side air-cooler 51 was even along transmission device 20 sets up in a row on side frame 12, usually one row can, also can set up the multirow, and side air-cooler 51 is higher than transmission device 20's transmission plane setting respectively. The side air cooler 51 is fixedly connected to the side frame 12 via a fixing plate. The surface air cooler 53 is a fan blowing air in a direction perpendicular to the surface of the solar cell module 60, the surface air cooler 53 can be arranged right above or below the stacking device 30, or arranged simultaneously above or below the stacking device, the surface air cooler 53 is uniformly distributed along the transmission direction of the solar cell module, and the wind power is conveniently dispersed uniformly on the surface of the solar cell module 60. The end cooling fan 52 is a fan blowing air from the discharging end of the transmission device 20 toward the solar cell module 60, that is, the air outlet direction faces the transmission direction of the solar cell module 60, and is disposed facing the transmission direction of the solar cell module 60, and it may be disposed on the beam 11 above the discharging end or the feeding end of the transmission device 20. The end air coolers 52 are uniformly arranged in a row along the length direction of the beam 11, preferably, the end air coolers 52 are arranged above the discharge end of the transmission device 20, and can enter the transmission material platform from the first solar cell module 60 to cool the solar cell module 60 by blowing, and the length of time that the end air coolers 52 are in effect can be prolonged to the maximum extent by the end air coolers 52. The side air cooler 51, the end air cooler 52, and the surface air cooler 53 may be selected from one type or several types according to the shape, size, cooling condition, equipment cost, and the like of the solar cell module 60. Preferably, three types of fans are arranged, so that the cooling efficiency can be improved to the greatest extent.

As shown in FIG. 2, when the end air cooler 52 is provided, it is preferable to provide an attachment plate 54, the top end of which is hinged to the beam of the gantry 10 above the discharge end. The shells of the end cooling fans 52 are all fixedly connected with the connecting plate 54. The hinge axis of the connecting plate 54 is horizontal and perpendicular to the transmission direction of the transmission device 20, so that the air outlet direction of the end air cooler 52 can be changed to a certain extent by rotating the connecting plate 54, and on the premise of ensuring that the blown wind energy cools the solar cell module 60 on the stack device 30, the wind power can be concentrated and sent to the position which needs cooling most by adjusting. An angle locking device should be provided between the connecting plate 54 and the table 10 for locking the rotation angle of the connecting plate 54 with respect to the table 10. The angle locking device can use a bolt, a pin and other structures, and is preferably a gas spring 55 with two ends respectively hinged on the side frame 12 and the connecting plate 54, so that the operation is simple and convenient, and stepless angle locking and angle conversion can be realized. The gas spring is preferably a free gas spring, a self-locking gas spring and a free gas stopping spring, one pressure cylinder end of the gas spring is connected with the cross beam, and one end of the piston rod is connected with the lower end of the connecting plate.

As shown in fig. 1 and 3, the transferring device 20 includes a plurality of parallel transferring rollers 21 rotatably connected to the frame 10, and a certain interval is left between two adjacent transferring rollers 21. The transfer device 20 further includes a drive motor for driving one of the transfer rollers 21 to rotate, and a transmission mechanism for performing transmission between the adjacent transfer rollers 21, and the transfer roller 21 driven to rotate is referred to as an active transfer roller. Preferably, a transmission mechanism is provided at the end of each transfer roller 21. The transmission mechanism can be a chain transmission mechanism or a belt transmission mechanism, the chain transmission mechanism and the belt transmission mechanism respectively comprise a plurality of transmission chains or transmission belts, one of the transmission chains or transmission belts is connected with the driving transmission roller 21 and the driven transmission roller 21 adjacent to the driving transmission roller, and the other transmission chain or transmission belt is connected with the driven transmission roller 21 and the other driven transmission roller 21, so that the adjacent transmission rollers 21 are connected one by one, and the synchronous rotation of all the transmission rollers 21 is realized. The transmission mechanism may also be a worm gear mechanism, in short, it is only necessary to drive the transmission rollers 21 to rotate synchronously.

The stacking device 30 includes two oppositely disposed support frames 31 and a support rod 32. Be provided with guide structure 70 between support frame 31 and the side frame 12, guide structure 70 includes slide rail 72 and the slider 72 of rigid coupling on support frame 31 of rigid coupling on side frame 12, and slide rail 72 is vertical to be set up, opens the spout that has with slide rail 72 looks adaptation on the slider 71, and slide rail 72 is located the spout, makes slider 71 can slide along the length direction of slide rail 72. The support rods 32 are arranged in a plurality of horizontal layers, each layer at least comprises two support rods 32, and each layer is provided with three layers and four layers. The length direction of the supporting rods 32 is horizontal and vertical to the conveying direction of the conveying device 20.

Preferably, each support bracket 31 comprises a vertically disposed upright 312 and a crossbar 311. The length direction of the cross bar 311 is parallel to the transmission direction of the transmission device 20, and the output end of the lifting device 40 and the slide block 71 are fixedly connected with the cross bar 311. The number of the vertical rods 312 in each supporting frame 31 is the same as that of the supporting rods 32 in each layer, and the three vertical rods 312 are parallel to each other and the top ends thereof are all fixedly connected to the cross rods 311. The two support frames 31 are arranged oppositely, the vertical rods 312 are respectively opposite, two ends of each support rod 32 are respectively fixedly connected to the vertical rods 312 of the two support frames 31, and the support rods 32 in different layers are uniformly arranged along the height direction of the vertical rods 312. All the uprights 312 and the upper supporting rods 32 thereof are located between two adjacent conveying rollers 21. The cross rod 311 and the vertical rod 312 form a fork-shaped structure with a downward opening, so that the support frame 31 can stride over the transmission mechanism of the transmission device 20 to be inserted into a gap on the transmission device 20 without interference, and thus the lifting device 40 does not need to consider the problem of interference between the stacking device 30 and the transmission device 20 when driving the support frame 31 to move up and down, the structure of the transmission mechanism is simpler, and the stability and the rigidity of the support rod 32 can be ensured under the common support of the two support frames 31.

Preferably, as shown in fig. 3, at least two supporting roller sleeves 321 are provided on each of the carrier rods 32. The supporting roller sleeve 321 is sleeved on the supporting rod 32 and is rotatably connected with the supporting rod 32, and the rotating axis is overlapped with the axis of the supporting roller sleeve 321 and is parallel to the length direction of the supporting rod 32. The supporting roller sleeve 321 is arranged, and the supporting roller sleeve 321 contacts the solar cell module 60 during charging and discharging, so that resistance required to be overcome when the supporting rod 32 and the solar cell module 60 move relatively can be reduced, and meanwhile, abrasion on the surface of the solar cell module 60 can be reduced.

Preferably, as shown in fig. 3, the lifting device 40 includes a lifting motor 41 fixed on the gantry 10, a driving bevel gear 42 coaxially fixed with the output end of the motor, a driven bevel gear 43 engaged with the driving bevel gear 42, a driving wheel 44 coaxially fixed with the driven bevel gear 43, a driven wheel 45 rotatably disposed right above or right below the driving wheel 44, a driving wheel 44, and a transmission member 46 for transmitting the rotation of the driving wheel 44 to the driven wheel 45. The drive member 46 may be a belt or chain. The axes of the driving pulley 44 and the driven pulley 45 are horizontal and parallel to each other. The driven wheel 45, the driving wheel 44 and the transmission member 46 are provided with two groups for respectively driving the two support frames 31 to move, and the two driving wheels 44 are coaxially and fixedly connected through a connecting shaft 47. The output end of the lifting motor 41 is vertically arranged, and the rotating direction of the output is changed through the driving bevel gear 42 and the driven bevel gear 43, so that the horizontal space occupied by the lifting motor 41 can be reduced by arranging the lifting motor 41, and the whole occupied area of the solar cell module laminating machine is further reduced.

At the beginning of feeding of the conveying device 20, all the support rods 32 are located below the conveying roller 21, when the solar cell module 60 moves to the conveying device 20, the fan of the cooling device 50 is used for cooling the solar cell module 60, when the solar cell module 60 moves to the position above the support rods 32, the lifting device 40 drives the support frame 31 to ascend the distance between the two layers of support rods 32, the solar cell module 60 is supported away from the conveying device 20, the next solar cell module 60 enters the lifting range of the support rods 32, and the lifting device 40 drives the support frame 31 to ascend, so that the circulation is performed until the support rods 32 at the bottommost layer support the solar cell module 60. During discharging, the lifting device 40 drives the support rods 32 to fall down to place the solar cell assemblies 60 on the support rods 32 of each layer on the conveying device 20 and convey the solar cell assemblies out. At the beginning of feeding, the supporting rod 32 at the lowest layer can be positioned below the conveying roller 21, and the rest supporting rods 32 are positioned above the conveying roller 21, so that the supporting frame 31 falls layer by layer in the feeding process.

Preferably, a first detection device 80 is disposed on the rack 10, and the first detection device 80 is used for detecting whether the horizontally moved position of the solar cell module 60 on the transmission device 20 reaches a liftable position, and sending a signal when detecting that the solar cell module reaches the liftable position. Detection device 80 is fixed to be set up in the position that is close to transmission device 20 discharge end, in this embodiment, detection device adopts ball pendulum rod type safety limit switch with adjustable, by limit switch's base and side frame 12 fixed connection, the top of the gyro wheel that its pendulum rod tip set up is a little higher than the transmission plane, when solar module 60 passes through the rubber gyro wheel, the gyro wheel is pressed, the pendulum rod swing, the decline of rubber gyro wheel triggers limit switch, limit switch alright signals, suggestion solar module 60 horizontal migration arrives the position that can go up and down. At this time, the transferring device 20 stops transferring, and the lifting device 40 starts to drive the stacking device 30 to move up and down. When the solar cell module leaves the position, the swing rod drives the rubber roller to return to detect the next workpiece.

Preferably, the second detection device 90 is arranged on the side frame 12, and the second detection device 90 is used for prompting whether the lifting device 40 is lifted in place once. The second detection device 90 comprises a plurality of proximity switches which are arranged along the vertical direction, and the number of the proximity switches is the same as the number of layers of the support rod 32. When the lever 32 is flush with the proximity switch in height, the distance between the lever and the proximity switch is set to the detection distance of the proximity switch. When the support rod is flush with the proximity switch in height, the proximity switch can send a signal to prompt that the lifting is in place, and the single lifting is completed. When the supporting rod 32 is lifted next time, the proximity switch is far away from the previous proximity switch and approaches the next proximity switch, when the supporting rod 32 is aligned with the next proximity switch, the proximity switch sends a signal to prompt that the lifting is finished, and the lifting motor stops working. Which proximity switches are activated can also indicate the position of the stack arrangement 30, e.g. when only the lowest one of the proximity switches is activated, meaning that the entire stack arrangement 30 is in the lowest position, when both the lower proximity switches are activated simultaneously, meaning that the entire stack arrangement 30 has moved one level upwards, and when only the uppermost one of the proximity switches is activated, meaning that the entire stack arrangement 30 is in the highest position. In addition, two trigger switches can be arranged on the upper part and the lower part of the second detection device respectively and used for prompting that the stacking device moves to the limit position.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (9)

1. The utility model provides a solar module laminator stack formula transmission material platform, includes rack (10), transmission device (20), stack device (30) and drive stack device (30) elevating gear (40) that reciprocate, its characterized in that: the device is characterized by further comprising a cooling device (50) arranged on the rack (10), wherein the cooling device (50) comprises a plurality of fans, and air outlets of the fans face the stacking device (30) and/or the conveying working surface.

2. The stacked delivery platform of a solar cell module laminator according to claim 1, wherein: the fan of the cooling device (50) comprises a plurality of side air coolers (51), the side air coolers (51) are arranged on two sides above a transmission plane of the transmission device (20) and are positioned on the same side, and the side air coolers (51) are arranged in a row uniformly along the transmission direction of the transmission device (20).

3. The stacked delivery platform of a solar cell module laminator according to claim 1, wherein: the fan of the cooling device (50) comprises a plurality of end air coolers (52), the end air coolers (52) are arranged in rows on the horizontal plane along the transmission direction perpendicular to the transmission device (20), and the end air coolers (52) are arranged above the discharge end of the transmission device (20).

4. The stacked delivery platform of a solar cell module laminator according to claim 3, wherein: the cooling device (50) further comprises a connecting plate (54) and an angle locking device, the end air coolers (52) are fixedly connected onto the connecting plate (54), the top end of the connecting plate (54) is hinged to the cross beam of the rack (10), the hinge axis is horizontally arranged and perpendicular to the transmission direction of the transmission device (20), and the angle locking device locks the corner of the connecting plate (54) relative to the cross beam of the rack (10).

5. The stacked delivery platform of a solar cell module laminator according to claim 4, wherein: the angle locking device is a gas spring (55) with two ends respectively hinged on the rack (10) and the connecting plate (54).

6. The stacked delivery platform of a solar cell module laminator according to claim 1, wherein: the fan of the cooling device (50) comprises a plurality of surface cooling fans (53), and the surface cooling fans (53) are uniformly distributed right above and/or right below the stack device (30).

7. The stacked delivery platform of a solar cell module laminator according to claim 1, wherein: the conveying device (20) comprises a plurality of conveying rollers (21) arranged in parallel and a transmission mechanism for transmitting between the adjacent conveying rollers (21), two ends of each conveying roller (21) are rotatably arranged on the rack (10), and the transmission mechanism is arranged at the end part of each conveying roller (21) and is connected with and transmits the adjacent conveying rollers (21); the stacking device (30) comprises two oppositely arranged support frames (31) and a support rod (32); the support rods (32) are horizontally arranged in layers, each layer at least comprises two support rods (32), and the support rods (32) are horizontally arranged and the length direction of the support rods is vertical to the transmission direction of the transmission device (20); the supporting frames (31) comprise upright rods (312) and a cross rod (311) which are vertically arranged, the length direction of the cross rod (311) is parallel to the transmission direction of the transmission device (20), the number of the upright rods (312) in each supporting frame (31) is the same as that of the supporting rods (32) on each layer, all the upright rods (312) are parallel to each other, the top ends of the upright rods (312) are fixedly connected to the cross rod (311), the two ends of each supporting rod (32) are fixedly connected to the upright rods (312) of two supporting frames (31), and the upright rods (312) are located between two adjacent transmission rollers (21); each support frame (31) is connected with the rack (10) in a sliding way through a guide mechanism (70), and the output end of the lifting device (40) is fixedly connected with the support frame (31).

8. The stacked transport table for a solar cell module laminator according to claim 7, wherein: each supporting rod (32) is provided with at least two supporting roller sleeves (321), the supporting roller sleeves (321) are rotatably connected to the supporting rods (32) by taking the axes of the supporting roller sleeves as shafts, and the rotating axes of the supporting sleeves are parallel to the length direction of the supporting rods (32).

9. The stacked transport table for a solar cell module laminator according to claim 7, wherein: the lifting device (40) comprises a lifting motor (41) fixedly connected on the rack (10), a driving bevel gear (42) coaxially and fixedly connected with the output end of the lifting motor (41), a driven bevel gear (43) meshed with the driving bevel gear (42), a driving wheel (44) coaxially and fixedly connected with the driven bevel gear (43), a driven wheel (45) rotatably arranged right above or right below the driving wheel (44), and a transmission part (46) in belt transmission or chain transmission with the driving wheel (44) and the driven wheel (45); the output end of the lifting motor (41) is vertically arranged, the axes of the driving wheel (44) and the driven wheel (45) are horizontal and parallel to each other, and the cross rod (311) is fixedly connected with the transmission piece (46).

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