CN114242610A

CN114242610A - Thermophotovoltaic cell performance test equipment

Info

Publication number: CN114242610A
Application number: CN202111622143.2A
Authority: CN
Inventors: 朱昱名
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-12-28
Filing date: 2021-12-28
Publication date: 2022-03-25

Abstract

The invention discloses a thermophotovoltaic cell performance testing device, which belongs to the technical field of thermophotovoltaic cells, has very low efficiency and accuracy rate through manual detection and sampling detection, is detected by an infrared scanner, and is difficult to realize continuous detection effect, and comprises a bottom plate, wherein two guide plates are fixedly arranged on the upper surface of the bottom plate, a feeding mechanism is slidably arranged between the inner walls of the guide plates, a motor drives the feeding mechanism to intermittently rotate through an intermittent disc, so that a cell panel is intermittently conveyed to a lifting assembly, the motor continuously rotates, a conical gear set can be driven to rotate through a turntable, a piston rod and a cam are driven to continuously rotate through a rotating sleeve, a push rod pushes a lifting belt wheel shaft to move up and down, so that the two feeding belt wheel shafts synchronously ascend, a pinch roller presses the upper surface of a conveying belt, the displacement of the cell panel can be prevented, the cell panel is stopped, and then the conveying belt is driven to reset through a spring, and repeating the action, and then realizing the detection of the continuity.

Description

Thermophotovoltaic cell performance test equipment

Technical Field

The invention relates to the field of thermophotovoltaic cells, in particular to thermophotovoltaic cell performance testing equipment.

Background

The performance of a solar panel needs to be detected in the production process of the thermal photovoltaic cell, the performance testing method is characterized in that sampling and checking are carried out manually by using a detection device, checking efficiency and accuracy are very low, surface scratches, edge width and thickness of the solar panel are detected by an infrared scanner, however, continuous detection effect is difficult to achieve, and therefore the thermal photovoltaic cell performance testing device is provided for solving the problems.

Disclosure of Invention

The invention aims to provide thermophotovoltaic cell performance testing equipment to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a thermophotovoltaic cell performance test equipment, includes the bottom plate, fixed surface is equipped with two baffles on the bottom plate, slidable mounting has feeding mechanism, lifting subassembly and prevents running the material subassembly between the baffle inner wall, the lifting subassembly with prevent running the material subassembly and all rotate the laminating with feeding mechanism and be connected, the lifting subassembly with prevent running the material subassembly and mesh and be connected, the panel has been placed on the feeding mechanism upper surface, sliding surface installs power component, runner assembly on the bottom plate, power component and feeding mechanism fixed connection, power component and runner assembly fixed connection, fixed surface installs the promotion subassembly on the bottom plate, runner assembly and promotion subassembly fixed connection, promote the subassembly upper end and rotate the laminating and connect the lifting subassembly bottom.

As a preferred technical scheme of the present invention, the upper surface of the bottom plate is symmetrically provided with second convex sliding grooves, the two second convex sliding grooves are respectively arranged at the outer sides of the two guide plates, the upper surface of the bottom plate is provided with a first convex sliding groove, the first convex sliding groove is internally and slidably provided with a power assembly, and the second convex sliding groove is internally and slidably provided with a rotating assembly.

As a preferred technical scheme of the present invention, a cross-shaped sliding groove and a rectangular sliding groove are formed at two ends of the surface of the guide plate, two first strip-shaped grooves and two second strip-shaped grooves are formed on the surface of the guide plate, a feeding mechanism is slidably mounted in the cross-shaped sliding groove, a power component is slidably mounted in the rectangular sliding groove, a lifting component is slidably mounted in the first strip-shaped groove, and a material leakage prevention component is slidably mounted in the second strip-shaped groove.

According to a preferable technical scheme, the feeding mechanism comprises two feeding belt wheel shafts, two conveying belts are sleeved on the feeding belt wheel shafts, one end of one feeding belt wheel shaft is fixedly connected with a power assembly, the surface of each conveying belt is rotationally attached to a lifting assembly and a material leakage prevention assembly, two ends of each feeding belt wheel shaft are rotationally connected with guide wheels, the guide wheels are slidably mounted in cross sliding grooves, one end of a spring is fixedly arranged on the outer surface of each guide wheel, the other end of the spring is fixedly connected with a rectangular fixing block, and the inner wall of each rectangular fixing block is fixedly arranged on the outer side surface of a guide plate.

According to a preferable technical scheme, the lifting assembly comprises two lifting belt wheel shafts, belt wheels at two ends of each lifting belt wheel shaft are rotatably attached to the bottom surface of the conveying belt, two ends of each lifting belt wheel shaft movably penetrate through a first strip-shaped groove and are rotatably connected with a circular seat, a first rack is fixedly arranged on the outer surface of the circular seat, the first rack is meshed with the material leakage prevention assembly, a push rod is fixedly arranged at the bottom end of the circular seat, a fixing plate movably penetrates through the bottom end of the push rod, the inner side of the fixing plate is fixedly arranged on the outer side surface of the guide plate, and the bottom end of the push rod is rotatably attached to the pushing assembly.

As a preferred technical scheme of the invention, the material leakage preventing assembly comprises two gear shafts, the gear shafts are rotatably mounted on the outer side surface of the guide plate, the gear shafts are in meshed connection with the first rack, the gear shafts are in meshed connection with the second rack, the side surface of the second rack is fixedly connected with a first rotating shaft, two ends of the first rotating shaft are slidably mounted in the second strip-shaped grooves, two pressing wheels are rotatably mounted outside the first rotating shaft, and the pressing wheels are rotatably attached to the upper surface of the conveying belt.

According to a preferable technical scheme, the power assembly comprises a motor, a convex seat is fixedly arranged on the motor, the bottom end of the convex seat is slidably mounted in a first convex sliding groove, a rotary disc and an L-shaped deflector rod are fixedly connected to the output end of the motor, an intermittent disc is rotatably mounted on the inner side of the convex seat, the outer surface of the rotary disc is rotatably attached to the outer surface of the intermittent disc, one end of a feeding belt wheel shaft is fixedly connected to the inner side of the intermittent disc, a first conical gear set is fixedly connected to the output end of the motor, a second rotating shaft is fixedly mounted on the first conical gear set, movably penetrates through the rectangular sliding groove and is fixedly connected with a second conical gear set, and rotating assemblies are fixedly connected to the first conical gear set and the second conical gear set.

As a preferred technical scheme of the invention, the surface of the turntable is provided with a first arc-shaped groove, the surface of the intermittent disc is provided with a plurality of rectangular grooves and a second arc-shaped groove, the rectangular grooves are connected with the L-shaped deflector rod in a sliding manner, and the inner arc surface of the second arc-shaped groove is connected with the outer surface of the turntable in a rotating and fitting manner.

As a preferred technical scheme of the present invention, the rotating assembly includes two vertical plates, side surfaces of the vertical plates are fixedly connected to inner side surfaces of the convex seats, bottom ends of the vertical plates are slidably mounted in the second convex sliding grooves, the vertical plates are rotatably and fixedly connected with rotating sleeves, one ends of the two rotating sleeves are respectively and fixedly connected with the first conical gear set and the second conical gear set, inner walls of the other ends of the rotating sleeves are fixedly provided with a plurality of clamping blocks, the other ends of the rotating sleeves are slidably and fixedly connected with the piston rods, the surfaces of the piston rods are provided with a plurality of spline grooves, the clamping blocks are slidably and fixedly clamped in the spline grooves, and the other ends of the piston rods are fixedly connected with the pushing assembly.

As a preferred technical solution of the present invention, the pushing assembly includes a third rotating shaft, one end of the third rotating shaft is fixedly connected to the other end of the piston rod, the third rotating shaft is rotatably connected to two supporting blocks, bottom surfaces of the supporting blocks are fixedly disposed on an upper surface of the bottom plate, two cams are fixedly disposed on an outer surface of the third rotating shaft, and an outer surface of each cam is rotatably attached to a bottom end of the corresponding push rod.

Compared with the prior art, the invention has the beneficial effects that:

the motor drives the intermittent type nature of feeding mechanism through the intermittent type dish and rotates, thereby make panel intermittent type nature carry to lifting subassembly department, the motor continuation rotates, can drive the bevel gear group through the carousel and rotate, and drive the piston rod through changeing the cover, the cam rotates in succession, make the push rod promote the lifting band pulley axle and reciprocate, thereby make two pay-off band pulley axles rise in step, and make the pinch roller press and hold the conveyer belt upper surface, then can prevent the displacement of panel, make the panel realize the parking, later drive the conveyer belt through the spring and reset, repetitive motion, then realize the detection of continuity.

Drawings

FIG. 1 is a schematic structural view of the present invention,

figure 2 is a schematic view of a structural base plate of the present invention,

figure 3 is a schematic view of the feeding mechanism of the structure of the invention,

figure 4 is a schematic view of a structural lift assembly of the present invention,

figure 5 is a schematic view of the structural anti-spillage component of the present invention,

figure 6 is a schematic view of a pushing assembly of the present invention,

figure 7 is a schematic view of the structural power assembly of the present invention,

fig. 8 is a schematic view of the rotating assembly of the present invention.

In the figure: 1. a base plate; 11. a first convex chute; 12. a second convex chute; 13. a guide plate; 14. a cross-shaped chute; 15. a rectangular chute; 16. a first bar-shaped groove; 17. a second strip groove; 2. a feeding mechanism; 21. a feeding belt wheel shaft; 22. a guide wheel; 23. a spring; 24. a rectangular fixed block; 25. a conveyor belt; 3. a lifting assembly; 31. lifting the pulley shaft; 33. a circular seat; 34. a push rod; 35. a fixing plate; 36. a first rack; 4. a run-out prevention assembly; 41. a gear shaft; 42. a second rack; 43. a first rotating shaft; 44. a pinch roller; 5. a power assembly; 51. a motor; 511. a convex seat; 52. a turntable; 521. a first arc-shaped slot; 53. an L-shaped deflector rod; 54. an intermittent disk; 541. a rectangular groove; 542. a second arc-shaped slot; 55. a first bevel gear set; 56. a second bevel gear set; 57. a second rotating shaft; 6. a pushing assembly; 61. a support block; 62. a cam; 63. a third rotating shaft; 7. a rotating assembly; 71. a vertical plate; 72. rotating the sleeve; 721. a clamping block; 73. a piston rod; 731. a spline groove; 8. and (7) a battery plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b): as shown in fig. 1-8, the invention provides a thermophotovoltaic cell performance testing device, which comprises a bottom plate 1, wherein two guide plates 13 are fixedly arranged on the upper surface of the bottom plate 1, a feeding mechanism 2, a lifting assembly 3 and a material leakage prevention assembly 4 are slidably arranged between the inner walls of the guide plates 13, the lifting assembly 3 and the material leakage prevention assembly 4 are both connected with the feeding mechanism 2 in a rotating and fitting manner, the lifting assembly 3 is connected with the material leakage prevention assembly 4 in a meshing manner, a cell panel 8 is arranged on the upper surface of the feeding mechanism 2 and used for conveying the cell panel 8 through the feeding mechanism 2, then the cell panel 8 is lifted through the lifting assembly 3, and the cell panel 8 is prevented from moving through the material leakage prevention assembly 4, so that the detection time of infrared scanning is prolonged, a power assembly 5 and a rotating assembly 7 are slidably arranged on the upper surface of the bottom plate 1, and the power assembly 5 is fixedly connected with the feeding mechanism 2, power component 5 and runner assembly 7 fixed connection, fixed surface installs promotion subassembly 6 on the bottom plate 1, runner assembly 7 and promotion subassembly 6 fixed connection, promotion 6 upper ends of subassembly rotate the laminating and connect lifting subassembly 3 bottoms, make 2 conveyor battery boards 8 of feeding mechanism carry through power component 5 and carry to linkage promotion subassembly 6 promotes lifting subassembly 3 and rises.

Further, second convex spout 12, two have been seted up to bottom plate 1 upper surface symmetry two 13 outsides of baffle are located respectively to second convex spout 12, first convex spout 11 has been seted up to bottom plate 1 upper surface, slidable mounting power component 5 in the first convex spout 11, slidable mounting rotating assembly 7 in second convex spout 12 to power component 5 can slide with rotating assembly 7 together.

Further, cross spout 14, rectangle spout 15 have been seted up at 13 surperficial both ends of baffle, two first bar grooves 16, second bar groove 17 have been seted up on 13 surfaces of baffle, slidable mounting feeding mechanism 2 in the cross spout 14, slidable mounting power component 5 in the rectangle spout 15, slidable mounting lifting subassembly 3 in the first bar groove 16, slidable mounting prevents running material subassembly 4 in the second bar groove 17, drives feeding mechanism 2 through power component 5 and promotes panel 8 to the messenger prevents running material subassembly 4 and moves down.

Further, the feeding mechanism 2 comprises two feeding belt wheel shafts 21, two conveyor belts 25 are sleeved on the feeding belt wheel shafts 21, one end of one feeding belt wheel shaft 21 is fixedly connected with the power assembly 5, so that the conveyor belts 25 can be driven by the power assembly 5 to rotate on the feeding belt wheel shaft 21, the surfaces of the conveyor belts 25 are rotatably attached to the lifting assembly 3 and the material leakage prevention assembly 4, two ends of the feeding belt wheel shaft 21 are rotatably connected with guide wheels 22, the guide wheels 22 are slidably mounted in the cross-shaped sliding grooves 14, so that the two feeding belt wheel shafts 21 can synchronously move through the guide wheels 22, one end of a spring 23 is fixedly arranged on the outer surface of each guide wheel 22, the other end of the spring 23 is fixedly connected with a rectangular fixed block 24, the inner wall of each rectangular fixed block 24 is fixedly arranged on the outer side surface of the guide plate 13, so that the feeding belt wheel shafts 21 can drive the guide wheels 22 to slide along the cross-shaped sliding grooves 14 through the springs 23, thereby achieving the reset.

Further, the lifting assembly 3 comprises two lifting pulley shafts 31, pulleys at two ends of each lifting pulley shaft 31 are rotatably attached to the bottom surface of the conveyor belt 25, the conveyor belt 25 can be lifted when the lifting pulley shafts 31 are lifted, two ends of each lifting pulley shaft 31 movably penetrate through the first strip-shaped groove 16, and is rotationally connected with a round seat 33, a first rack 36 is fixedly arranged on the outer surface of the round seat 33, the first rack 36 is meshed with the material-leakage-preventing component 4, so that when the lifting pulley shaft 31 rises, the material leakage preventing assembly 4 can move downwards, thereby pressing the conveyor belt 25, a push rod 34 is fixedly arranged at the bottom end of the round seat 33, a fixing plate 35 is movably penetrated at the bottom end of the push rod 34, the fixed plate 35 is inboard fixed to be located the baffle 13 outside surface, push rod 34 bottom is rotated the laminating and is connected pushing assembly 6 to it reciprocates to drive push rod 34 through pushing assembly 6.

Further, the material leakage preventing assembly 4 includes two gear shafts 41, the gear shafts 41 are rotatably mounted on the outer side surface of the guide plate 13, the gear shafts 41 are engaged with the first rack 36, the gear shafts 41 are engaged with the second rack 42, the side surface of the second rack 42 is fixedly connected with the first rotating shaft 43, two ends of the first rotating shaft 43 are slidably mounted in the second strip-shaped groove 17, two pressing wheels 44 are rotatably mounted outside the first rotating shaft 43, and the pressing wheels 44 are rotatably attached to the upper surface of the conveyor belt 25, so that when the first rack 36 is lifted, the gear shafts 41 drive the second rack 42 and the first rotating shaft 43 to move downwards, so that the pressing wheels 44 press the upper surface of the conveyor belt 25, and displacement of the battery panel 8 can be prevented.

Further, the power assembly 5 includes a motor 51, the motor 51 is fixedly provided with a convex base 511, the bottom end of the convex base 511 is slidably mounted in the first convex sliding groove 11, the motor 51 and the convex base 511 slide along the first convex sliding groove 11, the output end of the motor 51 is fixedly connected with a rotary disc 52 and an L-shaped shift lever 53, the motor 51 drives the rotary disc 52 and the L-shaped shift lever 53 to rotate, an intermittent disc 54 is rotatably mounted on the inner side of the convex base 511, the outer surface of the rotary disc 52 is rotatably attached to the outer surface of the intermittent disc 54, so that the intermittent disc 54 can intermittently rotate, the inner side of the intermittent disc 54 is fixedly connected with one end of a feeding belt wheel shaft 21, the intermittent disc 54 can drive the feeding mechanism 2 to intermittently rotate, so that the battery plate 8 is intermittently conveyed, the output end of the motor 51 is fixedly connected with a first conical gear set 55, a second rotating shaft 57 is fixedly mounted on the first conical gear set 55, the second rotating shaft 57 movably penetrates through the rectangular sliding groove 15 and is fixedly connected with a second bevel gear set 56, the rotating assembly 7 is fixedly connected to both the first bevel gear set 55 and the second bevel gear set 56, and therefore the motor 51 continuously drives the first bevel gear set 55 and the second bevel gear set 56 to rotate and drives the rotating assembly 7 to rotate.

Furthermore, a first arc-shaped groove 521 is formed in the surface of the rotating disc 52, a plurality of rectangular grooves 541 and second arc-shaped grooves 542 are formed in the surface of the intermittent disc 54, the rectangular groove 541 is connected with the L-shaped shifting lever 53 in a sliding mode, the inner arc surface of the second arc-shaped groove 542 is connected with the outer surface of the rotating disc 52 in a rotating mode in a fitting mode, and when the L-shaped shifting lever 53 is separated from the rectangular groove 541 in a rotating mode, the outer surface of the rotating disc 52 is connected with the inner arc surface of the second arc-shaped groove 542 in a rotating mode, so that the intermittent disc 54 is limited.

Further, the rotating assembly 7 comprises two vertical plates 71, the lateral surfaces of the vertical plates 71 are fixedly connected with the inner side surfaces of the convex seats 511, the bottom end of the vertical plate 71 is slidably mounted in the second convex chute 12, a rotating sleeve 72 is rotatably clamped in the vertical plate 71, so that the rotating sleeves 72 slide along the second convex sliding grooves 12 together with the vertical plates 71 and the convex seats 511, one end of each of the two rotating sleeves 72 is fixedly connected with the first bevel gear set 55 and the second bevel gear set 56, a plurality of blocks 721 are fixed on the inner wall of the other end of the rotating sleeve 72, a piston rod 73 is slidably clamped in the other end of the rotating sleeve 72, the surface of the piston rod 73 is provided with a plurality of spline grooves 731, the fixture block 721 is slidably clamped in the spline grooves 731, the other end of the piston rod 73 is fixedly connected with the pushing assembly 6, so that the rotating sleeve 72 can slide along the spline groove 731 via the latch 721 and can drive the piston rod 73 to rotate continuously.

Further, the pushing assembly 6 includes a third rotating shaft 63, one end of the third rotating shaft 63 is fixedly connected to the other end of the piston rod 73, so that the piston rod 73 can drive the third rotating shaft 63 to rotate continuously, the third rotating shaft 63 is rotatably connected to two supporting blocks 61, the bottom surfaces of the supporting blocks 61 are fixedly arranged on the upper surface of the base plate 1, two cams 62 are fixedly arranged on the outer surface of the third rotating shaft 63, the outer surface of each cam 62 is rotatably attached to the bottom end of the corresponding push rod 34, and the continuously rotating cam 62 can drive the corresponding push rod 34 to move up and down.

The working principle is as follows: the output end of the motor 51 drives the rotating disc 52 and the L-shaped deflector 53 to rotate, when the L-shaped deflector 53 rotates and is separated from the rectangular groove 541, the outer surface of the rotating disc 52 rotates and is attached to the inner arc surface of the second arc-shaped groove 542, so that the intermittent disc 54 is limited, the intermittent disc 54 intermittently rotates, the battery panel 8 is intermittently conveyed to a detection area at the lifting assembly 3, the motor 51 slides along the first convex sliding groove 11 together with the convex seat 511, the convex seat 511 is fixedly connected with the vertical plate 71, when the L-shaped deflector 53 rotates and is separated from the rectangular groove 541, the intermittent disc 54 and the conveyor belt 25 are in a static state, then the motor 51 continuously rotates, the first conical gear set 55 and the second conical gear set 56 can be driven to rotate by the rotating disc 52, the second conical sleeve 72 is driven to slide along the second convex sliding groove 12 together with the vertical plate 71 and the convex seat 511, and the rotating sleeve 72 can slide along the spline groove 731 by the fixture block 721, and can drive the piston rod 73 to rotate continuously, the continuously rotating cam 62 can drive the push rod 34 to move up and down, thereby enabling the two lifting belt wheel shafts 31 to synchronously lift the conveyor belt 25 through the guide wheel 22 to lift up, when the first rack 36 lifts up, the second rack 42 and the first rotating shaft 43 are driven to move down through the gear shaft 41, thereby enabling the press wheel 44 to press the upper surface of the conveyor belt 25, and then preventing the displacement of the battery panel 8, at this time, because the bottom end of the cam 62 is circular, the battery panel 8 can be lifted to a high place and is parked for a period of time, thereby facilitating the infrared scanning detection, then, the cam 62 continues to rotate, the push rod 34 is lowered, the press wheel 44 is lifted to be separated from the conveyor belt 25, thereby the feeding belt wheel shaft 21 can drive the guide wheel 22 to slide along the cross sliding groove 14 through the spring 23, thereby the conveyor belt 25 is reset, then the L-shaped deflector rod 53 rotates in the rectangular groove 541, and the reciprocating action is realized, and the automatic detection of continuity is realized.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A thermophotovoltaic cell performance test device comprises a base plate (1), and is characterized in that: the utility model discloses a solar cell panel lifting device, including bottom plate (1), fixed surface is equipped with two baffle (13) on bottom plate (1), slidable mounting has feeding mechanism (2), lifting subassembly (3) and prevents running material subassembly (4) between baffle (13) inner wall, lifting subassembly (3) with prevent running material subassembly (4) all with feeding mechanism (2) rotation laminating be connected, lifting subassembly (3) with prevent running material subassembly (4) meshing be connected, panel (8) have been placed to feeding mechanism (2) upper surface, bottom plate (1) upper surface slidable mounting has power component (5), runner assembly (7), power component (5) and feeding mechanism (2) fixed connection, power component (5) and runner assembly (7) fixed connection, bottom plate (1) upper surface fixed mounting has promotion subassembly (6), runner assembly (7) and promotion subassembly (6) fixed connection, the upper end of the pushing component (6) is rotated, attached and connected with the bottom end of the lifting component (3).

2. The thermophotovoltaic cell performance testing device according to claim 1, wherein the upper surface of the base plate (1) is symmetrically provided with second convex sliding grooves (12), the two second convex sliding grooves (12) are respectively arranged outside the two guide plates (13), the upper surface of the base plate (1) is provided with a first convex sliding groove (11), the power assembly (5) is slidably mounted in the first convex sliding groove (11), and the rotating assembly (7) is slidably mounted in the second convex sliding groove (12).

3. The thermophotovoltaic cell performance testing device according to claim 1, wherein a cross sliding groove (14) and a rectangular sliding groove (15) are formed in two ends of the surface of the guide plate (13), two first strip-shaped grooves (16) and two second strip-shaped grooves (17) are formed in the surface of the guide plate (13), the feeding mechanism (2) is installed in the cross sliding groove (14) in a sliding mode, the power component (5) is installed in the rectangular sliding groove (15) in a sliding mode, the lifting component (3) is installed in the first strip-shaped grooves (16) in a sliding mode, and the material leakage preventing component (4) is installed in the second strip-shaped grooves (17) in a sliding mode.

4. The thermophotovoltaic cell performance testing device according to claim 3, wherein the feeding mechanism (2) comprises two feeding pulley shafts (21), two conveyor belts (25) are sleeved on the feeding pulley shafts (21), one end of each feeding pulley shaft (21) is fixedly connected with the power assembly (5), the conveyor belts (25) are connected with the lifting assembly (3) and the anti-leakage assembly (4) in a surface rotating and fitting manner, guide wheels (22) are rotatably connected at two ends of each feeding pulley shaft (21), the guide wheels (22) are slidably mounted in the cross sliding grooves (14), one end of each spring (23) is fixedly arranged on the outer surface of each guide wheel (22), a rectangular fixing block (24) is fixedly connected at the other end of each spring (23), and the inner wall of each rectangular fixing block (24) is fixedly arranged on the outer side surface of the guide plate (13).

5. The thermophotovoltaic cell performance testing apparatus according to claim 4, the lifting assembly (3) comprises two lifting belt wheel shafts (31), belt wheels at two ends of each lifting belt wheel shaft (31) are rotatably attached to the bottom surface of the conveyor belt (25), two ends of each lifting belt wheel shaft (31) movably penetrate through the first strip-shaped groove (16), and is rotationally connected with a circular seat (33), a first rack (36) is fixedly arranged on the outer surface of the circular seat (33), the first rack (36) is engaged and connected with the material leakage preventing component (4), the bottom end of the round seat (33) is fixedly provided with a push rod (34), the bottom end of the push rod (34) is movably penetrated with a fixing plate (35), the inner side of the fixing plate (35) is fixedly arranged on the outer side surface of the guide plate (13), and the bottom end of the push rod (34) is rotated, attached and connected with the pushing assembly (6).

6. The thermophotovoltaic cell performance testing device according to claim 5, wherein the anti-slip assembly (4) comprises two gear shafts (41), the gear shafts (41) are rotatably installed on the outer side surface of the guide plate (13), the gear shafts (41) are engaged with the first rack (36), the gear shafts (41) are engaged with the second rack (42), the side surface of the second rack (42) is fixedly connected with a first rotating shaft (43), two ends of the first rotating shaft (43) are slidably installed in the second strip-shaped groove (17), two pressing wheels (44) are rotatably installed outside the first rotating shaft (43), and the pressing wheels (44) are rotatably attached to the upper surface of the conveyor belt (25).

7. The thermophotovoltaic cell performance testing device according to claim 4, wherein the power assembly (5) comprises a motor (51), the motor (51) is fixedly provided with a convex seat (511), the bottom end of the convex seat (511) is slidably installed in the first convex sliding chute (11), the output end of the motor (51) is fixedly connected with a rotary disc (52) and an L-shaped deflector rod (53), an intermittent disc (54) is rotatably installed on the inner side of the convex seat (511), the outer surface of the rotary disc (52) is rotatably attached to the outer surface of the intermittent disc (54), the inner side of the intermittent disc (54) is fixedly connected with one end of a feeding belt wheel shaft (21), the output end of the motor (51) is fixedly connected with a first conical gear set (55), a second rotating shaft (57) is fixedly installed on the first conical gear set (55), and the second rotating shaft (57) movably penetrates through the rectangular sliding chute (15), and a second bevel gear set (56) is fixedly connected, and the rotating assembly (7) is fixedly connected on both the first bevel gear set (55) and the second bevel gear set (56).

8. The thermophotovoltaic cell performance testing device according to claim 7, wherein a first arc-shaped groove (521) is formed in the surface of the rotating disc (52), a plurality of rectangular grooves (541) and a second arc-shaped groove (542) are formed in the surface of the intermittent disc (54), the L-shaped deflector rod (53) is connected in the rectangular grooves (541) in a sliding mode, and the inner arc surface of the second arc-shaped groove (542) is connected to the outer surface of the rotating disc (52) in a rotating mode in a fitting mode.

9. The thermophotovoltaic cell performance testing apparatus according to claim 7, the rotating assembly (7) comprises two vertical plates (71), the side surfaces of the vertical plates (71) are fixedly connected with the inner side surfaces of the convex seats (511), the bottom end of the vertical plate (71) is slidably arranged in the second convex sliding groove (12), rotating sleeves (72) are rotatably clamped in the vertical plate (71), one ends of the two rotating sleeves (72) are respectively and fixedly connected with a first conical gear set (55) and a second conical gear set (56), a plurality of clamping blocks (721) are fixedly arranged on the inner wall of the other end of the rotating sleeve (72), a piston rod (73) is slidably clamped in the other end of the rotating sleeve (72), the surface of the piston rod (73) is provided with a plurality of spline grooves (731), the fixture block (721) is slidably clamped in the spline grooves (731), the other end of the piston rod (73) is fixedly connected with a pushing assembly (6).

10. The thermophotovoltaic cell performance testing device according to claim 9, wherein the pushing assembly (6) comprises a third rotating shaft (63), one end of the third rotating shaft (63) is fixedly connected with the other end of the piston rod (73), the third rotating shaft (63) is rotatably connected with two supporting blocks (61), the bottom surfaces of the supporting blocks (61) are fixedly arranged on the upper surface of the base plate (1), two cams (62) are fixedly arranged on the outer surface of the third rotating shaft (63), and the outer surfaces of the cams (62) are rotatably attached to the bottom end of the pushing rod (34).