CN216996410U - Conveying machine - Google Patents

Abstract

The utility model belongs to the technical field of photovoltaic module production, and discloses a conveyor for producing photovoltaic modules, which comprises a rack, an X-direction conveying mechanism, a Y-direction conveying mechanism and a reversing mechanism, wherein the X-direction conveying mechanism, the Y-direction conveying mechanism and the reversing mechanism are all arranged on the rack, the X-direction conveying mechanism is used for conveying the photovoltaic modules along the X-axis direction, the Y-direction conveying mechanism is used for conveying the photovoltaic modules along the Y-axis direction, and the reversing mechanism is used for adjusting the orientation of the photovoltaic modules and can convey the photovoltaic modules on the X-direction conveying mechanism to the Y-direction conveying mechanism or convey the photovoltaic modules on the Y-direction conveying mechanism to the X-direction conveying mechanism. The conveyor can realize multi-directional conveying of the photovoltaic assembly, and production efficiency of the photovoltaic assembly is effectively improved.

Description

Conveying machine

Technical Field

The utility model relates to the technical field of photovoltaic module production, in particular to a conveyor.

Background

With the rapid development of photovoltaic power generation, the demand for photovoltaic modules is increasing. Currently, photovoltaic modules are produced using automated production lines.

However, in the using process of the traditional conveyor of the automatic production line of the photovoltaic modules, the conveyor can only convey the photovoltaic modules in a single direction, and the production efficiency is low.

Therefore, it is desirable to provide a conveyor capable of conveying photovoltaic modules in multiple directions to improve production efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model provides a conveyor which can convey photovoltaic modules in multiple directions and effectively improve the production efficiency of the photovoltaic modules.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a conveyor is used for producing photovoltaic modules and comprises a frame, an X-direction conveying mechanism, a Y-direction conveying mechanism and a reversing mechanism,

x is to conveying mechanism Y is to conveying mechanism and reversing mechanism all sets up in the frame, X is to conveying mechanism be used for with photovoltaic module carries along X axle direction, Y is to conveying mechanism be used for with photovoltaic module carries along Y axle direction, reversing mechanism is used for adjusting photovoltaic module's orientation, and can with X is to conveying mechanism photovoltaic module carry extremely Y is to conveying mechanism is last, or will Y is to conveying mechanism on photovoltaic module carries extremely X is to conveying mechanism is last.

Optionally, the reversing mechanism comprises a reversing table, a jacking unit and a reversing unit,

the photovoltaic module supporting device comprises a reversing table, a jacking unit, a reversing unit and a reversing unit, wherein the reversing table is used for supporting the photovoltaic module, the jacking unit can drive the reversing table to rise and fall along the Z-axis direction, and the reversing unit can drive the reversing table to rotate around the axis of the reversing table.

Optionally, the reversing unit further comprises a first mounting plate, a second mounting plate, a third mounting plate and a first support rod,

the second mounting plate is fixed on the rack, the first supporting rod penetrates through the second mounting plate in a sliding mode, one end of the first supporting rod is fixedly connected with the first mounting plate, the other end of the first supporting rod is fixedly connected with the third mounting plate, the fixed end of the jacking unit is fixed on the third mounting plate, the output end of the jacking unit penetrates through the third mounting plate and is fixedly connected with the second mounting plate, the reversing unit is fixed on the first mounting plate, and the reversing unit is in driving connection with the reversing table.

Optionally, the reversing unit comprises a cam divider and a first motor, an output end of the first motor is in driving connection with an input shaft of the cam divider, and an output shaft of the cam divider is in driving connection with the reversing table.

Optionally, the reversing table is cross-shaped.

Optionally, the X-direction conveying mechanism comprises an X-direction conveyor, a first transmission shaft and a second motor, at least two groups of the X-direction conveyors are connected through the first transmission shaft, and an output end of the second motor is in driving connection with the first transmission shaft and is used for driving the first transmission shaft to rotate;

y to conveying mechanism with X sets up to conveying mechanism is perpendicular, Y includes Y to conveyer, second transmission shaft and third motor to conveying mechanism, at least two sets of Y passes through to the conveyer the second transmission shaft links to each other, the output of third motor with the second transmission shaft drive is connected, is used for the drive the second transmission shaft rotates.

Optionally, the conveyor further includes a plurality of lifting mechanisms, and the plurality of lifting mechanisms are respectively connected to the X-direction conveying mechanism and the Y-direction conveying mechanism, and are configured to drive the X-direction conveying mechanism and the Y-direction conveying mechanism to lift and fall along the Z-axis direction.

Optionally, the photovoltaic module further comprises a plurality of auxiliary supporting wheels, the plurality of auxiliary supporting wheels are arranged at intervals along the Y-axis direction and used for supporting the photovoltaic module, and the plurality of auxiliary supporting wheels can lift along with the Y-axis conveying mechanism synchronously.

Optionally, the photovoltaic module further comprises an electric roller, the electric roller is arranged along the Y-axis direction and is abutted to the photovoltaic module, and the electric roller can synchronously lift along with the Y-direction conveying mechanism.

Optionally, the photovoltaic module further comprises auxiliary supporting mechanisms, wherein the auxiliary supporting mechanisms are arranged at four corners of the rack and used for supporting the edges of the photovoltaic module.

The utility model has the beneficial effects that:

the photovoltaic module can be conveyed along an X axis by arranging the X-direction conveying mechanism, the photovoltaic module can be conveyed along a Y axis by arranging the Y-direction conveying mechanism, the photovoltaic module conveyed along the X axis direction can be conveyed to the Y axis direction by arranging the reversing mechanism, or the photovoltaic module conveyed along the Y axis direction can be conveyed to the X axis direction by reversing, so that the multi-direction conveying of the photovoltaic module is realized, and the production efficiency of the photovoltaic module is effectively improved.

Drawings

FIG. 1 is a schematic structural view of a conveyor provided by the present invention;

FIG. 2 is a first schematic structural diagram of a reversing mechanism provided by the present invention;

FIG. 3 is a second schematic structural view of the reversing mechanism provided by the present invention (the reversing table is not shown);

FIG. 4 is a top view of the reversing mechanism provided by the present invention;

FIG. 5 is a schematic structural diagram of an X-direction conveying mechanism provided by the present invention;

FIG. 6 is a schematic structural view of a Y-direction conveying mechanism provided by the present invention;

FIG. 7 is a schematic structural diagram of a first lifting mechanism provided in the present invention;

FIG. 8 is a schematic structural diagram of a second lifting mechanism provided in the present invention;

fig. 9 is a schematic structural diagram of an auxiliary supporting mechanism provided in the present invention.

In the figure:

100. a frame; 200. an X-direction conveying mechanism; 210. an X-direction conveyor; 220. a first drive shaft; 230. a second motor; 300. a Y-direction conveying mechanism; 310. a Y-direction conveyor; 320. a second transmission shaft; 330. a third motor; 400. a reversing mechanism; 410. a reversing table; 411. a first bearing part; 412. a second bearing part; 420. a jacking unit; 430. a commutation unit; 431. a cam indexer; 432. a first motor; 440. a first mounting plate; 450. a second mounting plate; 460. a third mounting plate; 470. a first support bar; 500. a first lifting mechanism; 510. a first driving member; 520. a first fixing plate; 530. a second fixing plate; 540. a synchronous lifter; 541. a connecting rod; 550. a bearing seat; 600. a second lifting mechanism; 610. a fourth mounting plate; 620. a fifth mounting plate; 630. a sixth mounting plate; 640. a second support bar; 650. a second driving member; 700. an auxiliary support wheel; 800. a motorized pulley; 900. an auxiliary support mechanism; 910. a connecting rod; 920. a universal ball.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the utility model and are not limiting of the utility model. It should be further noted that, for the convenience of description, only some structures related to the present invention are shown in the drawings, not all of them.

In the description of the present invention, unless otherwise explicitly specified or limited, the terms "connected," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integral to one another; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or may be connected through the use of two elements or the interaction of two elements. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

In the present invention, unless expressly stated or limited otherwise, the recitation of a first feature "on" or "under" a second feature may include the recitation of the first and second features being in direct contact, and may also include the recitation that the first and second features are not in direct contact, but are in contact via another feature between them. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

In the description of the present embodiment, the terms "upper", "lower", "left", "right", and the like are used based on the orientations and positional relationships shown in the drawings only for convenience of description and simplification of operation, and do not indicate or imply that the referred device or element must have a specific orientation, be configured and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used only for descriptive purposes and are not intended to have a special meaning.

The utility model provides a conveyor which can convey photovoltaic modules in multiple directions and effectively improve the production efficiency of the photovoltaic modules.

Specifically, as shown in fig. 1, the conveyor includes a frame 100, an X-direction conveying mechanism 200, a Y-direction conveying mechanism 300, and a reversing mechanism 400, wherein the X-direction conveying mechanism 200, the Y-direction conveying mechanism 300, and the reversing mechanism 400 are all disposed on the frame 100, and the frame 100 is used for supporting the X-direction conveying mechanism 200, the Y-direction conveying mechanism 300, and the reversing mechanism 400. The X-direction conveying mechanism 200 can convey the photovoltaic module in the X-axis direction, and the Y-direction conveying mechanism 300 can convey the photovoltaic module in the Y-axis direction. The reversing mechanism 400 can convey the photovoltaic modules on the X-direction conveying mechanism 200 to the Y-direction conveying mechanism 300, so that the photovoltaic modules are conveyed in a reversing manner. Of course, the reversing mechanism 400 can also convey the photovoltaic module on the Y-direction conveying mechanism 300 to the X-direction conveying mechanism 200, so as to realize the reversing conveying of the photovoltaic module.

Through setting up X to conveying mechanism 200 and Y to conveying mechanism 300, can carry photovoltaic module along X axle direction, can carry photovoltaic module along Y axle direction again, realize photovoltaic module's multi-direction transport. Through setting up reversing mechanism 400, can realize the feeding and the ejection of compact of photovoltaic module all directions, improve photovoltaic module's production efficiency.

Further, as shown in fig. 2 to 4, the reversing mechanism 400 includes a reversing table 410, a jacking unit 420, and a reversing unit 430, where the reversing table 410 is used to support the photovoltaic module, the jacking unit 420 is used to drive the reversing table 410 to ascend and descend, and the reversing unit 430 is used to drive the reversing table 410 to rotate, so as to reverse the photovoltaic module. In one embodiment, the commutation unit 430 can be a motor.

Preferably, as shown in fig. 3, in one embodiment, the reversing mechanism 400 may include a first mounting plate 440, a second mounting plate 450, a third mounting plate 460, and a first supporting rod 470, wherein the second mounting plate 450 is fixedly connected to the rack 100, the first supporting rod 470 is inserted through the second mounting plate 450, and one end of the first supporting rod 470 is fixedly connected to the first mounting plate 440 and the other end of the first supporting rod is fixedly connected to the third mounting plate 460, and the first supporting rod 470 can slide relative to the second mounting plate 450. In order to improve the coupling strength between the first mounting plate 440 and the third mounting plate 460, a plurality of first support bars 470 may be provided. In the present embodiment, four first support bars 470 are provided, and the four first support bars 470 are provided at four corners of the first mounting plate 440 and the third mounting plate 460. Of course, in other embodiments, the number of the first support rods 470 may be other, and may be set according to actual needs. The fixed end of the jacking unit 420 is fixed to the third mounting plate 460, and the output end of the jacking unit 420 passes through the third mounting plate 460 and is fixedly connected with the second mounting plate 450. Since the second mounting plate 450 is fixed to the frame 100, when the conveyor operates, the second mounting plate 450 is fixed, and when the output end of the jacking unit 420 extends, the distance between the second mounting plate 450 and the third mounting plate 460 is increased, and since the length of the first support bar 470 is unchanged, the distance between the first mounting plate 440 and the second mounting plate 450 is decreased, so that the direction changing table 410 falls along the Z-axis direction. Similarly, when the output end of the jacking unit 420 retracts, the distance between the second mounting plate 450 and the third mounting plate 460 is shortened, and since the length of the first support rod 470 is unchanged, the distance between the first mounting plate 440 and the second mounting plate 450 is increased, so that the direction-changing table 410 is lifted along the Z-axis direction.

Through the structure, the reverse driving of the jacking unit 420 is realized, on one hand, the driving force of the jacking unit 420 can be saved, and the service life of the jacking unit 420 is prolonged; on the other hand, the working stability of the jacking unit 420 is improved; on the other hand, generally use two jacking units 420 direct drive among the prior art to reach the jacking stationarity of this application, and this application has reduced jacking unit 420's use quantity through back drive, is favorable to reduce cost. The jacking unit 420 may be a mechanism capable of conveying a linear motion, such as an air cylinder, a hydraulic cylinder, or the like. The reversing unit 430 is fixed on the first mounting plate 440 and is used for driving the reversing table 410 to rotate.

In this embodiment, when the photovoltaic module transported along the X-axis direction needs to be reversed to be transported along the Y-axis direction, the photovoltaic module is first transported to the reversing table 410. Then the jacking unit 420 drives the reversing table 410 carrying the photovoltaic module to rise along the Z-axis direction, so that the photovoltaic module is separated from the X-direction conveying mechanism 200, the reversing unit 430 drives the reversing table 410 to rotate, so that the photovoltaic module is positioned above the Y-direction conveying mechanism 300, and the orientation of the photovoltaic module is adjusted. Finally, the jacking unit 420 drives the reversing table 410 carrying the photovoltaic module to fall along the Z-axis direction, so that the photovoltaic module is contacted with the Y-axis conveying mechanism, and the reversing of the photovoltaic module is completed. Of course, the same is true when the photovoltaic module conveyed along the Y-axis direction needs to be reversed to be conveyed along the X-axis direction.

Preferably, a linear bearing may be disposed at a joint of the first support rod 470 and the second mounting plate 450, and specifically, the linear bearing is sleeved outside the first support rod 470, so that on one hand, friction between the first support rod 470 and the second mounting plate 450 can be reduced, which is beneficial to protecting the outer surface of the first support rod 470, so that the first support rod 470 moves more smoothly and stably along the Z-axis direction, the working stability of the reversing mechanism 400 is improved, and damage to the photovoltaic module is avoided; on the other hand, the movement of the first support bar 470 can be guided.

Preferably, with continued reference to fig. 3, the reversing unit 430 may include a cam divider 431 and a first motor 432, and have an output of the first motor 432 drivingly connected to an input shaft of the cam divider 431 and an output shaft of the cam divider 431 drivingly connected to the reversing stage 410. The cam divider 431 has the advantage of high-precision rotation, and the first motor 432 and the cam divider 431 can improve the rotation precision of the reversing table 410, so that the reliability of the reversing operation of the conveyor can be ensured. In this embodiment, the first motor 432 is a three-phase motor. In other embodiments, the first motor 432 may be of other types, which may be selected according to actual needs.

Preferably, as shown in fig. 1 and 4, in one embodiment, the reversing station 410 may be a cross-shaped, and the reversing unit 430 is disposed at the center of the cross-shaped reversing station 410. For convenience of understanding, the horizontal portion of the cross-shaped reversing table 410 is defined as a first bearing portion 411, the vertical portion of the cross-shaped reversing table 410 is defined as a second bearing portion 412, and the X-direction conveying mechanism 200 and the Y-direction conveying mechanism 300 can be disposed between the adjacent first bearing portion 411 and the second bearing portion 412, so that the structural compactness of the conveyor can be improved, and the occupied space of the conveyor can be reduced.

Preferably, the first bearing portion 411 and the second bearing portion 412 may be hollow structures, which is beneficial to reduce the weight of the direction changing table 410; on the other hand, the hollow structure can be used for avoiding the installation of other structures on the conveyor, and the structural compactness of the conveyor is further improved.

Further, as shown in fig. 5, the X-direction conveying mechanism 200 includes an X-direction conveyor 210, a first transmission shaft 220, and a second motor 230. In this embodiment, every four sets of the X-direction conveyors 210 are connected by a first transmission shaft 220, the output end of the second motor 230 is in driving connection with the first transmission shaft 220, and the second motor 230 can drive the first transmission shaft 220 to rotate. When the second motor 230 drives the first transmission shaft 220 to rotate, the X-direction conveyor 210 can be driven to convey the photovoltaic module along the X-axis direction. Of course, in other embodiments, the number of the X-directional conveyors 210 may be other, and may be set according to actual needs.

Preferably, the X-direction conveyor 210 includes two first conveying wheels and a first conveying belt, and the first conveying belt is sleeved on the two first conveying wheels. The two first conveyor wheels and the first conveyor belt form a belt drive. The first transmission shaft 220 is fixedly connected to a first conveying wheel.

In this embodiment, 8 sets of X-direction conveyors 210 are provided, every four sets of X-direction conveyors 210 are connected by a first transmission shaft 220, every two sets of X-direction conveyors 210 are arranged oppositely, and 8 sets of X-direction conveyors 210 are arranged in 4 rows and 2 columns. In other embodiments, the number and arrangement of the X-direction conveyors 210 may be other, and may be set according to actual needs.

Further, as shown in fig. 1 and fig. 6, the Y-direction conveying mechanism 300 is disposed perpendicular to the X-direction conveying mechanism 200, and the Y-direction conveying mechanism 300 includes a Y-direction conveyor 310, a second transmission shaft 320, and a third motor 330, wherein in this embodiment, two sets of Y-direction conveyors 310 are connected through the second transmission shaft 320, an output end of the third motor 330 is drivingly connected to the second transmission shaft 320, and the third motor 330 can drive the second transmission shaft 320 to rotate. When the third motor 330 drives the second transmission shaft 320 to rotate, the Y-direction conveyor 310 can be driven to convey the photovoltaic module along the Y-axis direction.

Preferably, the Y-direction conveyor 310 includes two second conveying wheels and a second conveying belt, and the second conveying belt is sleeved on the two second conveying wheels. The two second conveyor wheels and the second conveyor belt form a belt drive. The second drive shaft 320 is fixedly connected to a second conveyor wheel.

In this embodiment, 16 sets of Y-direction conveyors 310 are provided, each two sets of Y-direction conveyors 310 are connected by a second transmission shaft 320, and each two sets of Y-direction conveyors 310 are arranged oppositely. In other embodiments, the number and arrangement of the Y-direction conveyors 310 may be other, and may be set according to actual needs.

Further, as shown in fig. 7 and 8, the conveyor further includes a first lifting mechanism 500 and a second lifting mechanism 600, wherein the first lifting mechanism 500 is used for driving the X-direction conveying mechanism 200 to lift and drop along the Z-axis direction. The second elevating mechanism 600 is used to drive the Y-direction conveying mechanism 300 to ascend and descend in the Z-axis direction.

In this embodiment, if the photovoltaic module needs to be transported along the X-axis direction during production, the first lifting mechanism 500 lifts the X-direction transport mechanism 200, and the X-direction transport mechanism 200 is used to transport the photovoltaic module. If the photovoltaic module needs to be conveyed along the Y-axis direction during production, the Y-direction conveying mechanism 300 is lifted up by the second lifting mechanism 600, and the photovoltaic module is conveyed to the Y-direction conveying mechanism 300. Moreover, through setting up first elevating system 500 and second elevating system 600, can also realize photovoltaic module along the not transport of the co-altitude of Z axle direction, improve photovoltaic module's production effect.

Preferably, with continued reference to fig. 7, the first lifting mechanism 500 includes two first driving members 510, two first fixing plates 520, two second fixing plates 530, and a synchronous lifter 540, wherein the second fixing plates 530 are fixedly connected to the rack 100, a fixed end of one first driving member 510 is fixedly connected to one second fixing plate 530, and an output end of one first driving member 510 passes through the second fixing plate 530 and is fixedly connected to the first fixing plate 520. The synchronous lifter 540 is disposed between the first fixing plate 520 and the second fixing plate 530. When the two first driving members 510 are driven simultaneously, the synchronous lifter 540 can make the lifting distances of the two first fixing plates 520 the same, so as to ensure that the X on the first lifting mechanism 500 is always kept horizontal to the conveying mechanism 200, thereby avoiding the damage of the photovoltaic module on the X conveying mechanism 200, and ensuring the working reliability of the conveyor. Since the synchronous lifter 540 is a prior art, the structure of the synchronous lifter 540 is not described in detail.

Preferably, in order to improve the working stability of the synchronous lifter 540, the connecting rod 541 of the synchronous lifter 540 may be fixed on the rack 100 through the bearing seat 550, specifically, the bearing seat 550 is fixedly connected with the rack 100, and the connecting rod 541 penetrates through the bearing seat 550 and can rotate relative to the bearing seat 550, so as to avoid the vibration of the connecting rod 541 due to too long in the using process, and ensure the stability of the rotation of the connecting rod 541.

Further, in order to facilitate the first lifting mechanism 500 to drive the X-direction conveying mechanism 200 to lift along the Z-axis direction, a first support frame may be provided, and the X-direction conveying mechanism 200 is fixed to the first support frame. The first fixing plate 520 of the first lifting mechanism 500 is fixedly connected to the first support frame. When the output end of the first driving element 510 extends out, the second fixing plate 530 can be jacked up along the Z-axis direction, so as to jack up the first support frame, and further jack up the X-direction conveying mechanism 200.

Further, as shown in fig. 8, the second lifting mechanism 600 includes a fourth mounting plate 610, a fifth mounting plate 620, a sixth mounting plate 630, a second supporting rod 640 and a second driving member 650, wherein the fifth mounting plate 620 is fixedly connected to the rack 100, the second supporting rod 640 is inserted into the fifth mounting plate 620, one end of the second supporting rod is fixedly connected to the fourth mounting plate 610, the other end of the second supporting rod is fixedly connected to the sixth mounting plate 630, and the second supporting rod 640 can slide relative to the fifth mounting plate 620. In order to improve the coupling strength between the fourth mounting plate 610 and the sixth mounting plate 630, a plurality of second support bars 640 may be provided. In the present embodiment, four second support bars 640 are provided, and the four second support bars 640 are provided at four corners of the fourth mounting plate 610 and the sixth mounting plate 630. The fixed end of the second driving member 650 is fixed to the sixth mounting plate 630, and the output end of the second driving member 650 penetrates through the sixth mounting plate 630 and is fixedly connected to the fifth mounting plate 620. Since the fifth mounting plate 620 is fixed to the frame 100, when the conveyor operates, the fifth mounting plate 620 is fixed, and when the output end of the second driving element 650 extends out, the distance between the fifth mounting plate 620 and the sixth mounting plate 630 is increased, and since the length of the second supporting bar 640 is unchanged, the distance between the fourth mounting plate 610 and the fifth mounting plate 620 is decreased, so that the Y-direction conveying mechanism 300 falls down along the Z-axis direction. Similarly, when the output end of the second driving element 650 retracts, the distance between the fifth mounting plate 620 and the sixth mounting plate 630 is shortened, and since the length of the second supporting bar 640 is unchanged, the distance between the fourth mounting plate 610 and the fifth mounting plate 620 is increased, so that the Y-conveying mechanism 300 is lifted along the Z-axis direction. Through the structure, the reverse driving of the second driving piece 650 is realized, on one hand, the driving force of the second driving piece 650 can be saved, and the service life of the second driving piece 650 is prolonged; on the other hand, the working stability of the second driving element 650 is improved; on the other hand, generally use two second driving piece 650 direct drive among the prior art to reach the jacking stationarity of this application, and this application has reduced second driving piece 650's use quantity through the backdrive, is favorable to reduce cost. The second driving member 650 may be a cylinder, a hydraulic cylinder, or the like capable of transmitting a linear motion.

Further, in order to facilitate the second lifting mechanism 600 to drive the Y-direction conveying mechanism 300 to lift along the Z-axis direction, a second supporting frame may be provided, and the Y-direction conveying mechanism 300 is fixed to the second supporting frame. The fourth mounting plate 610 of the second lifting mechanism 600 is fixedly connected with the second support frame. When the output end of the second driving element 650 retracts, the fourth mounting plate 610 can be jacked up along the Z-axis direction, so that the second support frame is jacked up, and the Y-direction conveying mechanism 300 is jacked up.

In this embodiment, 4 sets of Y-direction conveyors 310 are fixed on one second supporting frame, and one second supporting frame is driven to move up and down by one second lifting mechanism 600.

Preferably, as shown in fig. 6, the Y-direction conveyor 310 is arranged on two sides of the second support frame, and the photovoltaic module is large, so as to avoid the inner wall from being hidden and cracked due to the middle groove of the photovoltaic module, a plurality of auxiliary support wheels 700 may be arranged, and the auxiliary support wheels 700 are arranged in the middle of the second support frame, which is beneficial to ensuring that the stress of the photovoltaic module is uniform, and reducing the failure rate of the photovoltaic module. In this embodiment, the auxiliary support wheels 700 are spaced apart in the Y-axis direction, and two auxiliary support wheels are provided on each second support frame. In other embodiments, the number of the auxiliary support wheels 700 may be other, and may be set according to actual needs.

Optionally, as shown in fig. 1 and fig. 6, in this embodiment, four second supporting frames are provided, two second supporting frames are located on one side of the first bearing portion 411 of the reversing table 410, and the other two second supporting frames are located on the other side of the first bearing portion 411 of the reversing table 410, so that, since the first bearing portion 411 makes the distance between the Y-direction conveyors 310 on the second supporting frames farther, uniformity of stress on each portion of the photovoltaic module is not facilitated. Therefore, a motorized pulley 800 may be provided at the position of the first carrying portion 411, and the motorized pulley 800 may be capable of rotating and falling with the raising and lowering of the Y-direction conveying mechanism 300. On the one hand, the Y-direction conveyor 310 can be assisted in conveying the photovoltaic modules; on the other hand, the stress uniformity of the photovoltaic module can be improved, and the quality of the photovoltaic module is guaranteed.

Further, as shown in fig. 1 and 9, in one embodiment, an auxiliary support mechanism 900 may be further provided for supporting the edge of the photovoltaic module. The number of the auxiliary supporting mechanisms 900 can be set according to actual needs, in this embodiment, four auxiliary supporting mechanisms 900 are provided, and the four auxiliary supporting mechanisms 900 are provided at four corners of the rack 100.

Further, the auxiliary support mechanism 900 may include a connection rod 910 and a universal ball 920. Specifically, one end of the connecting rod 910 is fixedly connected to the rack 100, the other end of the connecting rod is fixedly connected to the universal ball 920, and the universal ball 920 is slidably connected to the edge of the photovoltaic module. Because in photovoltaic module's transportation process, probably carry along X axle direction, also can carry along Y axle direction, consequently set up universal ball 920, be favorable to adapting to photovoltaic module's switching-over to carry.

The conveyer has four conveying directions in all, namely an X-axis positive direction, an X-axis negative direction, a Y-axis positive direction and a Y-axis negative direction, and during work, generally three directions are feeding directions and are butted with other conveying devices, one direction is a feeding direction, and other conveying devices do not need to be butted.

For ease of understanding, the operation of the conveyor is briefly described (the conveyor can only carry one photovoltaic module at a time):

use X axle forward as the material loading direction, through above-mentioned conveyer with photovoltaic module switching-over to carrying along Y axle forward direction as the example.

First, the X-direction conveying mechanism 200 is in a lifting state along the Z-axis direction, and after the photovoltaic module is conveyed to a position right above the reversing mechanism 400, the output end of the jacking unit 420 retracts, so that the reversing table 410 is lifted along the Z-axis direction and separated from the X-direction conveying mechanism 200.

Then, the X-direction conveying mechanism 200 falls down along the Z-axis direction, the Y-direction conveying mechanism 300 rises along the Z-axis direction, the reversing unit 430 drives the reversing table 410 to rotate by 90 degrees, the output end 420 of the jacking unit extends out, the reversing table 410 falls down along the Z-axis direction until the photovoltaic module abuts against the Y-direction conveying mechanism 300, and the reversing table 410 continues to fall down until the photovoltaic module is separated from the Y-direction conveying mechanism.

Finally, the photovoltaic modules are conveyed along the Y-axis direction by the Y-direction conveying mechanism 300, and reversing conveying of the photovoltaic modules is completed.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Numerous obvious variations, adaptations and substitutions will occur to those skilled in the art without departing from the scope of the utility model. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. A conveyor for producing photovoltaic modules is characterized by comprising a rack (100), an X-direction conveying mechanism (200), a Y-direction conveying mechanism (300) and a reversing mechanism (400),

x is to conveying mechanism (200), Y is to conveying mechanism (300) and reversing mechanism (400) all set up in frame (100), X is used for with conveying mechanism (200) photovoltaic module carries along the X axle direction, Y is to conveying mechanism (300) be used for with photovoltaic module carries along the Y axle direction, reversing mechanism (400) are used for adjusting photovoltaic module's orientation, and can with X is to conveying mechanism (200) photovoltaic module carry extremely Y is to conveying mechanism (300) on, or will Y is to conveying mechanism (300) photovoltaic module carry extremely X is to conveying mechanism (200) on.

2. The conveyor of claim 1, wherein the diverting mechanism (400) comprises a diverting table (410), a jacking unit (420), and a diverting unit (430),

the photovoltaic module supporting device is characterized in that the reversing table (410) is used for supporting the photovoltaic module, the jacking unit (420) can drive the reversing table (410) to rise and fall along the Z-axis direction, and the reversing unit (430) can drive the reversing table (410) to rotate around the axis of the reversing table (410).

3. The conveyor of claim 2, wherein the reversing mechanism (400) further comprises a first mounting plate (440), a second mounting plate (450), a third mounting plate (460), and a first support bar (470),

second mounting panel (450) are fixed in frame (100), first bracing piece (470) slide and wear to establish on second mounting panel (450), the one end of first bracing piece (470) with first mounting panel (440) fixed connection, the other end with third mounting panel (460) fixed connection, the stiff end of jacking unit (420) is fixed in third mounting panel (460), the output of jacking unit (420) passes third mounting panel (460) with second mounting panel (450) fixed connection, switching-over unit (430) are fixed in first mounting panel (440), switching-over unit (430) with switching-over platform (410) drive connection.

4. A conveyor according to claim 2, wherein the reversing unit (430) comprises a cam divider (431) and a first motor (432), an output end of the first motor (432) is in driving connection with an input shaft of the cam divider (431), and an output shaft of the cam divider (431) is in driving connection with the reversing table (410).

5. Conveyor according to claim 2, characterized in that the reversing table (410) is cross-shaped.

6. The conveyor according to claim 5, wherein the X-direction conveying mechanism (200) comprises X-direction conveyors (210), a first transmission shaft (220) and a second motor (230), at least two groups of the X-direction conveyors (210) are connected through the first transmission shaft (220), and the output end of the second motor (230) is in driving connection with the first transmission shaft (220) and is used for driving the first transmission shaft (220) to rotate;

y to conveying mechanism (300) with X sets up to conveying mechanism (200) is perpendicular, Y includes Y to conveying mechanism (300) and passes through to conveying machine (310) second transmission shaft (320) and third motor (330), at least two sets of Y is to conveying machine (310) second transmission shaft (320) link to each other, the output of third motor (330) with second transmission shaft (320) drive is connected for the drive second transmission shaft (320) rotate.

7. The conveyor of any one of claims 1-6, further comprising a first lifting mechanism (500) and a second lifting mechanism (600), wherein the first lifting mechanism (500) is connected to the X-direction conveying mechanism (200) for driving the X-direction conveying mechanism (200) to lift and fall along the Z-axis direction, and the second lifting mechanism (600) is connected to the Y-direction conveying mechanism (300) for driving the Y-direction conveying mechanism (300) to lift and fall along the Z-axis direction.

8. The conveyor of claim 7, further comprising a plurality of auxiliary support wheels (700), wherein the plurality of auxiliary support wheels (700) are arranged at intervals along the Y-axis direction and used for supporting the photovoltaic module, and the plurality of auxiliary support wheels (700) can be lifted and lowered synchronously with the Y-direction conveying mechanism (300).

9. The conveyor of claim 7, further comprising a motorized pulley (800), wherein the motorized pulley (800) is disposed along the Y-axis and abuts against the photovoltaic module, and the motorized pulley (800) can be synchronously lifted and lowered along with the Y-axis conveying mechanism (300).

10. The conveyor according to any one of claims 1 to 6, further comprising auxiliary support mechanisms (900), wherein the auxiliary support mechanisms (900) are arranged at four corners of the machine frame (100) and are used for supporting the edges of the photovoltaic modules.

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