Disclosure of Invention
The invention aims to overcome the problems in the prior art, and provides a photovoltaic solar panel folding and unfolding frame, wherein a conveying platform is arranged on a fixed base, a rotating first conveying belt is arranged on the conveying platform, so that the solar panel can be further driven to slide through the rotation of the first conveying platform, and further conveyed, an installation frame is arranged on the fixed base, a rotating second conveying belt is arranged on the installation frame, so that the solar panel can be further driven to convey through the rotation of the second conveying belt, the solar panel can be conveyed to the installation frame, the solar panel can be further conveyed to the installation frame, and the laying amount of the solar panel can be further increased, therefore, the laying area of the solar cell panel can be further increased, and the power generation capacity is increased.
The invention is realized by the following technical scheme:
the utility model provides an intelligence photovoltaic solar cell panel receive and releases frame, including unable adjustment base, the last mounting bracket that is provided with of unable adjustment base, unable adjustment base on still be provided with one with the corresponding conveying platform of mounting bracket, the last first recess that is provided with of conveying platform, the both ends of first recess are provided with a pivoted second pivot and first pivot respectively, first pivot with be provided with a first runner, two in the second pivot respectively the tensioning has a first conveyor belt on the first runner, be provided with one row of support slot on the first conveyor belt, be provided with a solar cell panel in the support slot respectively. Be provided with a conveying platform on the unable adjustment base, thereby can pass through conveying platform is further to solar cell panel save the transport be provided with a pivoted second conveyor belt on the mounting bracket, thereby can pass through second conveyor belt's rotation, can be further carry solar cell panel, thereby can be further carry solar cell panel extremely on the mounting bracket, thereby can be further increase solar cell panel's installation area, thereby can be further increase the generated energy, thereby avoided because of the limited problem of the area of laying that sets up solar cell panel and lead to subaerial.
A third rotating shaft and a fourth rotating shaft which are rotated are respectively arranged at two ends of the mounting frame, a second rotating wheel is respectively arranged on the third rotating shaft and the fourth rotating shaft, a second conveying belt is tensioned between the two second rotating wheels, a control head is arranged on the second conveying belt, a first sliding shaft which slides is arranged on the control head, a butt joint is arranged on the first sliding shaft, a fixed block is respectively arranged on the solar cell panel, a second clamping groove corresponding to the butt joint is respectively arranged on the fixed block, a first electromagnet which controls the first sliding shaft to slide is arranged on the mounting frame, a plurality of control sliders which are swung are arranged on the butt joint, the control sliders are swung to be respectively clamped in the second clamping grooves after the butt joint slides into the second clamping groove, the fixed block is internally provided with a second electromagnet for controlling the control slide block to swing, the second conveying belt is provided with a section of meshing fluted disc, the mounting frame is provided with a second gear which is correspondingly meshed and connected with the meshing fluted disc, and the second gear drives the second rotating shaft to rotate. Can be through the rotation of first conveyor belt, drive that can step forward solar cell panel's slip can pass through the drive that second conveyor belt's rotation can step forward the rotation of butt joint, thereby can pass through the butt joint can step forward with the fixed block carries out corresponding joint, thereby drive that can step forward solar cell panel's transport.
The both sides of fixed block are provided with a connecting axle respectively, set up on the mounting bracket multirow with the corresponding first joint groove of connecting axle, be provided with a gliding third magnet on the connecting axle respectively, first joint inslot be provided with respectively one with the corresponding magnetism of third magnet is inhaled the third electro-magnet of connection, third magnet drives the connecting axle is in slide in the first joint inslot, first joint inslot still is provided with respectively the gliding fourth slide bar of mounting bracket, the fourth slide bar respectively with the corresponding joint of third magnet, still be provided with control in the mounting bracket respectively the gliding fourth electro-magnet of fourth slide bar. Can be through the circular telegram of fourth electro-magnet, control that can be further the fourth slide-shaft is in the connection and the separation in first joint inslot to can be further with solar cell panel fixes on the mounting bracket.
The connecting shaft is provided with second conducting rings respectively, the first clamping grooves are internally provided with first conducting rings respectively, after the connecting shaft slides into the first clamping grooves, the second conducting rings are correspondingly connected with the first conducting rings, and wires of the solar cell panel are correspondingly connected with the second conducting rings. The first conducting ring and the second conducting ring can be correspondingly connected, so that the electric quantity generated by the solar cell panel can be further transmitted, and the transmission of power generation is completed.
Furthermore, a supporting slide block for supporting the first conveying belt to slide is arranged in the first groove, the bottom of the mounting rack is provided with a second groove correspondingly communicated with the first groove, a sixth rotating shaft connected to the mounting rack is arranged in the second groove, the second gear rotates on the sixth rotating shaft, a fifth rotating shaft which rotates in the mounting rack is also arranged in the second groove, a first gear which is correspondingly meshed and connected with the second gear is arranged on the fifth rotating shaft, the fifth rotating shaft is also provided with a second chain wheel, the second rotating shaft is provided with a first chain wheel, the first chain wheel is correspondingly connected with the second chain wheel through a first chain, and the mounting frame is further provided with a first motor for driving the third rotating shaft to rotate.
Furthermore, a first sliding hole for supporting the first sliding shaft to slide is arranged on the control head, a second sliding groove correspondingly communicated with the first sliding hole is formed in the end portion of the control head, a first magnet sliding in the second sliding groove is arranged at one end of the first sliding shaft, the first electromagnet is correspondingly repelled by the first magnet after being electrified, a first spring for ejecting the first magnet to slide is arranged in the second sliding groove, the butt joint is arranged at the other end of the first sliding shaft, and the position of the first electromagnet corresponds to that of the second clamping groove.
Furthermore, the butt joint is arranged in a conical shape, four fifth chutes are arranged on the butt joint, seventh rotating shafts connected to the butt joint are respectively arranged in the fifth chutes, the control slide blocks respectively rotate on the seventh rotating shafts, and third springs for elastically pressing the control slide blocks are respectively arranged in the fifth chutes;
the second clamping grooves are respectively arranged in a T shape, the second clamping grooves respectively comprise a third sliding groove arranged on the fixed block, the fixed blocks are also respectively provided with a fourth sliding chute corresponding to the third sliding chute, the second electromagnets are respectively arranged in the fourth sliding chutes, a second sliding magnet is respectively arranged in the fourth sliding grooves, a second sliding shaft which slides in the third sliding grooves is respectively arranged on the second magnets, the second sliding shafts are respectively provided with a first clamping joint which slides in the third sliding groove, the first clamping joint is respectively provided with an extrusion groove which corresponds to the four control slide blocks, the second electromagnet is correspondingly repelled with the second magnet after being electrified, and a second spring for biasing the second magnet is respectively arranged in the fourth sliding grooves.
Furthermore, the end portions of the connecting shafts are respectively provided with a sixth sliding chute, the sixth sliding chutes are respectively arranged in a T shape, the third magnets are respectively provided with a third sliding shaft which slides in the sixth sliding chutes, the third sliding shafts and the sixth sliding chutes are correspondingly respectively arranged in a T shape, and the sixth sliding chutes are respectively internally provided with a fourth spring which can pull the third sliding shafts to slide.
Furthermore, the first clamping grooves respectively comprise four seventh sliding grooves arranged in the mounting frame, the mounting frame is respectively internally provided with an eighth sliding groove corresponding to the seventh sliding grooves, the fourth electromagnets are respectively arranged in the eighth sliding grooves, the end parts of the fourth sliding shafts are respectively provided with a fourth magnet sliding in the eighth sliding grooves, the fourth electromagnets are connected with the fourth magnet in a magnetic attraction manner corresponding to the fourth magnet after being electrified, the fourth sliding shafts are respectively provided with a jacking disc sliding in the seventh sliding grooves, the seventh sliding grooves are respectively internally provided with a fourth spring for elastically pressing the jacking disc, the end parts of the fourth sliding shafts are respectively provided with a clamping surface arranged in an inclined manner, the third magnets respectively correspond to the clamping surfaces, the mounting frame is provided with a row of fifth electromagnets corresponding to the first clamping grooves, and the fifth electromagnet is correspondingly repelled with the first magnet after being electrified.
Further, the both sides of mounting bracket are provided with one respectively and support the gliding first spout of second conveyer belt, first spout is the T type setting, second conveyer belt is the T type setting, the top of mounting bracket is provided with one and supports the first rotary trough of second runner pivoted.
Furthermore, the meshing fluted disc is made of rubber.
Compared with the prior art, the invention has the beneficial effects that: the solar cell panel storage and transportation device comprises a fixed base, a transportation platform, a mounting frame, a rotary second transportation belt, a first transportation belt, a second transportation belt, a first transmission belt, a second;
a control head is arranged on the second conveying belt, a fixed block is arranged on the solar cell panel, a second clamping groove is arranged on the fixed seat, a sliding butt joint is arranged on the control head, so that the control head can be further correspondingly connected with the fixed seat after the butt joint slides into the second clamping groove, so that the solar cell panel can be further driven to slide by the rotation of the second conveying belt, thereby being capable of further conveying the solar cell panel to the mounting rack, further utilizing the mounting rack to mount the solar cell panel, therefore, the problem that the mounting number of the solar panels is limited due to the limited area of the ground can be further solved, and the mounting area of the solar panels can be further increased;
the two sides of the fixing block are respectively provided with a connecting shaft, and the connecting shafts are respectively provided with a sliding third magnet, so that after the first connecting shaft slides into the first clamping groove, the fixing block can be further fixed on the mounting frame, a solar panel can be further fixed on the mounting frame, meanwhile, the third electromagnet can be further used for controlling the magnetic attraction connection with the third magnet, the fixing block can be further controlled, the solar panel can be conveniently detached, the detachment of the solar panel can be controlled under the condition of strong wind, and the solar panel can be further prevented from being damaged by the strong wind;
the second conducting ring can be connected with the first conducting ring, so that electric quantity generated by the solar cell panel can be further transmitted, and electric power transmission is completed.
Drawings
The invention is further described below with reference to the accompanying drawings.
Fig. 1 is a schematic view of the overall structure of a photovoltaic solar panel folding and unfolding rack according to an embodiment of the invention.
Fig. 2 is a schematic view of an overall structure of a conveying platform and a mounting rack according to an embodiment of the invention.
Fig. 3 is a side view of the overall structure of the second groove formed in the mounting bracket according to the embodiment of the present invention.
Fig. 4 is a top view of the overall structure of the fixing block mounted on the bracket according to the embodiment of the present invention.
FIG. 5 is a top view of an overall structure of the control head and the fixing block according to the embodiment of the present invention.
Fig. 6 is a schematic view of an overall structure of a fixing block according to an embodiment of the present invention.
FIG. 7 is a side view of the overall structure of the butt joint according to the embodiment of the present invention.
FIG. 8 is a top view of the overall structure of the butt joint according to the embodiment of the present invention.
Fig. 9 is a schematic view of a connection structure of a mounting frame and a fixing block according to an embodiment of the present invention.
Fig. 10 is a schematic view of an overall structure of the first engaging groove according to the embodiment of the invention.
In the figure: 1 fixed base, 2 mounting rack, 3 conveying platform, 4 first groove, 5 first rotating shaft, 6 second rotating shaft, 7 first conveying belt, 8 first rotating wheel, 9 supporting clamping groove, 10 solar cell panel, 11 third rotating shaft, 12 second rotating wheel, 13 fourth rotating shaft, 14 second conveying belt, 15 control head, 16 first electromagnet, 17 supporting sliding block, 18 first chain wheel, 19 second groove, 20 fifth rotating shaft, 21 second chain wheel, 22 first gear, 23 sixth rotating shaft, 24 second gear, 25 meshing fluted disc, 26 fixed block, 27 connecting shaft, 28 first sliding hole, 29 first rotating groove, 30 first clamping groove, 31 first sliding groove, 32 second sliding groove, 33 first magnet, 34 first sliding shaft, 35 first spring, 36 second clamping groove, 37 butt joint, 38 third sliding groove, 39 fourth sliding groove, 40 second magnet, 41 second electromagnet, 42 second sliding shaft, 43 a second spring, 44 a first clamping joint, 45 a squeezing groove, 46 a control slide block, 47 a fifth slide groove, 48 a seventh rotating shaft, 49 a third spring, 50 a first conductive ring, 51 a second conductive ring, 52 a third magnet, 53 a third electromagnet, 54 a sixth slide groove, 55 a third slide shaft, 56 a seventh slide groove, 57 a fourth slide shaft, 58 a pressing plate, 59 a fourth spring, 60 a fourth magnet, 61 a fourth electromagnet, 62 a clamping surface, 63 an eighth slide groove, 64 a first motor, 65 a control module, 66 a first chain, 67 a fourth spring, 68 a fifth electromagnet, 69 a sixth electromagnet and 70 a fifth spring.
Detailed Description
As shown in fig. 1 to 10, an intelligent photovoltaic solar cell panel folding and unfolding frame comprises a fixed base 1, a mounting frame 2 is arranged on the fixed base 1, a conveying platform 3 corresponding to the mounting frame 2 is further arranged on the fixed base 1, a first groove 4 is formed in the conveying platform 3, two ends of the first groove 4 are respectively provided with a second rotating shaft 6 and a first rotating shaft 5, the first rotating shaft 5 and the second rotating shaft 6 are respectively provided with a first rotating wheel 8, the first rotating wheel 8 is tensioned with a first conveying belt 7, the first conveying belt 7 is provided with a row of supporting clamping grooves 9, and a solar cell panel 10 is respectively arranged in the supporting clamping grooves 9.
The number of the fixed bases 1 can be multiple, the number of the fixed bases 1 can be set according to the design requirement, the fixed bases 1 are respectively provided with a mounting rack 20, the height of the mounting rack 2 can be set according to the design requirement, the fixed bases 1 are provided with a conveying platform 3, the conveying platform 3 is provided with a first groove 4, the first groove 4 is internally provided with a first rotating shaft 5 and a second rotating shaft 6, the first rotating shaft 5 and the second rotating shaft 16 are respectively provided with a first rotating wheel 8, the first conveying belt 7 is provided with a row of supporting clamping grooves 9, the supporting clamping grooves 9 are respectively arranged in a concave shape, so that the solar cell panel 10 can be clamped and fixed in the supporting clamping grooves 9, and the solar cell panel 10 can be further conveyed through the rotation of the first conveying belt 7, thereby enabling further transport installation of the solar panels 11.
The both ends of mounting bracket 2 are provided with a pivoted third pivot 11 and fourth pivot 13 respectively, third pivot 11 with be provided with a second runner 12 on the fourth pivot 13 respectively, two the tensioning has a second conveyor belt 14 between the second runner 12, be provided with a control head 15 on the second conveyor belt 14, be provided with a gliding first slide-shaft 34 on the control head 15, be provided with a butt joint 37 on the first slide-shaft 34, be provided with a fixed block 26 on the solar cell panel 10 respectively, be provided with on the fixed block 26 respectively one with the corresponding second joint groove 36 of butt joint 37, be provided with a control on the mounting bracket 2 the gliding first electro-magnet 16 of first slide-shaft 34, be provided with a plurality of wobbling control slider 46 on the butt joint 37, butt joint 37 slides to after in the second joint groove 36 control slider 46 swings respectively the joint be in second joint groove 36 the joint In the groove 36, be provided with a control in the fixed block 26 respectively the wobbling second electro-magnet 41 of control slider 46, be provided with one section meshing fluted disc 25 on the second conveyor belt 14, be provided with on the mounting bracket 2 one with the corresponding second gear 24 that meshes the connection of meshing fluted disc 25, second gear 24 drives second pivot 6 rotates.
A third rotating shaft 11 and a fourth rotating shaft 13 are respectively disposed at two ends of the mounting frame 20, a second rotating wheel 12 is respectively disposed on the third rotating shaft 11 and the fourth rotating shaft 13, a second conveying belt 14 is disposed between the two second rotating wheels 12, so that the second conveying belt 14 can be further driven to rotate by the third rotating shaft 11, a control head 15 is disposed on the second conveying belt 14, so that the control head 15 can be further driven to rotate by the rotation of the second conveying belt 14, a fixing block 26 is disposed on the solar cell panel 10, so that the solar cell panel 10 can be supported by the fixing block 26, a second clamping groove 36 is respectively disposed on the fixing block 26, a first sliding shaft 34 is respectively disposed on the control head 15, the end portions of the first sliding shaft 34 are respectively provided with a butt joint 37, so that the butt joint 37 can be further clamped in the second clamping groove 36 by sliding of the first sliding shaft 34, the butt joint 37 is provided with a plurality of swinging control sliders 46, so that after the butt joint 37 slides into the second clamping groove 36, the butt joint 37 can be further clamped in the second clamping groove 36 by swinging of the control sliders 46, so that the fixed block 26 can be further connected to the control head 15, so that the fixed block 26 can be further driven to slide on the mounting frame 2 by rotation of the second conveying belt 14, so that the fixed block 26 can be further lifted to the mounting frame 2, and the fixed block 26 is respectively provided with a second electromagnet 41, therefore, the swinging of the control slide block 46 can be further controlled by the energization of the second electromagnet 41, so that the butt joint 37 can be further separated from the second clamping groove 36, so that after the fixed block 26 is further fixed on the mounting frame 2, the separation of the control head 15 and the fixed block 26 can be further controlled by the energization of the second electromagnet 41, so that the next solar cell panel 10 can be transported and mounted by the rotation of the second transport belt 14, a section of meshing fluted disc 25 is arranged on the second transport belt 14, a gullet is arranged on the meshing fluted disc 25, the position of the meshing fluted disc 25 corresponds to the control head 15, a rotating second gear 24 is arranged on the mounting frame 2, so that the rotation of the second transport belt 14 can further drive the meshing fluted disc 25 to rotate, the second gear 24 can be further rotated by the rotation of the meshing fluted disc 25, so that the second rotating shaft 6 can be further rotated by the rotation of the second gear 24, so as to further drive the first conveying belt 14 to rotate, so as to further convey the solar cell panel 10, the meshing fluted disc 25 is arranged at a position corresponding to the position of the control head 15, so that it is possible to further ensure the synchronous action of the solar panel 10 with the control head 15, thereby can further guarantee to control head 15 can with the connection that fixed block 26 can be corresponding, can further guarantee to the joint that butt joint 37 can be accurate the joint is in second joint groove 36 to can guarantee to carry solar cell panel 10.
The both sides of fixed block 26 are provided with a connecting axle 27 respectively, set up on mounting bracket 2 the multirow with the corresponding first joint groove 30 of connecting axle 27, be provided with a gliding third magnet 52 on the connecting axle 27 respectively, be provided with one respectively in the first joint groove 30 with the corresponding magnetism of third magnet 52 is inhaled the third electro-magnet 53 of connecting, third magnet 52 drives connecting axle 27 is in slide in first joint groove 30, still be provided with respectively in the first joint groove 30 the gliding fourth sliding shaft 56 of mounting bracket 2, fourth sliding shaft 57 respectively with the corresponding joint of third magnet 52, still be provided with control respectively in the mounting bracket 2 the gliding fourth electro-magnet 61 of fourth sliding shaft 57.
Two connecting shafts 27 are respectively arranged on two sides of the fixed block 26, a plurality of rows of first clamping grooves 30 are arranged on the mounting frame 2, the first clamping grooves 30 are arranged in two rows and respectively correspond to the connecting shafts 27, so that the connecting shafts 27 can be further slid to the position corresponding to the first clamping grooves 30 in the sliding process of the fixed block 26, a sliding third magnet 52 is respectively arranged on the connecting shafts 27, a third electromagnet 53 is respectively arranged in the first clamping grooves 30, and after the third electromagnet 53 is electrified, the connecting shafts 27 can be further magnetically attracted and connected corresponding to the third magnet 52, so that the connecting shafts 27 can be further brought into the first clamping grooves 30, and a sliding fourth sliding shaft 57 is arranged in the first clamping grooves 30, thereby can pass through the slip of fourth slide shaft 57 can be further right third magnet 52 carries out the joint, thereby can be further with connecting axle 27 is fixed in first joint groove 30, thereby can with fixed block 26 is fixed on mounting bracket 2, from the installation that can realize solar cell panel 10, the quantity that first joint groove 30 set up can set up according to the needs of design, thereby can pass through the circular telegram respectively of third electro-magnet 53, thereby can fix solar cell panel 10 respectively on different first joint grooves 30, thereby can be further avoided because of the ground mounting area is limited, the limited problem of solar cell panel 10 installation quantity that leads to, the installation quantity of improvement solar cell panel 10 that can be further, thereby increase the generated energy.
The connecting shaft 27 is provided with second conducting rings 51, the first clamping grooves 30 are provided with first conducting rings 50, the second conducting rings 51 are correspondingly connected with the first conducting rings 50 after the connecting shaft 27 slides into the first clamping grooves 30, and the wires of the solar cell panel 11 are correspondingly connected with the second conducting rings 51.
The connecting shaft 27 is respectively provided with a second conductive ring 51, the second conductive rings 51 are arranged in a circular ring shape, the first clamping grooves 30 are respectively provided with a first conductive ring 50, the first conductive rings 50 are arranged in a circular ring shape, when the connecting shaft 27 is clamped in the first clamping grooves 30, the second conductive rings 51 can be further connected with the first conductive rings 50 correspondingly, electric quantity generated by the solar cell panel 10 can be further transmitted to the second conductive rings 51 through wires, the electric quantity can be further transmitted through the first conductive rings 50, the fourth sliding shaft 57 can be further controlled to slide through the fourth electromagnet 61, so that the fourth sliding shaft 57 can be further controlled to be separated from the third magnet 52, and the mounting and the dismounting of the fixed block 26 can be further controlled, therefore, the solar cell panel 10 can be unloaded in case of strong wind, thereby preventing damage to the solar cell panel 10 due to excessive wind.
As shown in fig. 1 to 3, a supporting slider 17 for supporting the first conveying belt 7 to slide is disposed in the first groove 4, a second groove 19 correspondingly communicating with the first groove 4 is disposed at the bottom of the mounting frame 2, a sixth rotating shaft 23 connected to the mounting frame 2 is disposed in the second groove 19, the second gear 24 rotates on the sixth rotating shaft 23, a fifth rotating shaft 20 rotates in the mounting frame 2 is further disposed in the second groove 19, a first gear 22 correspondingly engaged with the second gear 24 is disposed on the fifth rotating shaft 20, a second sprocket 21 is further disposed on the fifth rotating shaft 20, a first sprocket 18 is disposed on the second rotating shaft 6, and the first sprocket 18 and the second sprocket 21 are correspondingly connected through a first chain 66, the mounting bracket 2 is further provided with a first motor 64 for driving the third rotating shaft 11 to rotate.
A supporting slide block 17 is arranged in the first groove 4, so that the first conveying belt 7 can be supported by the supporting slide block 17, so that the first conveying belt 7 can be further ensured to normally convey the solar cell panel 10, a second groove 19 is arranged at the bottom of the mounting frame 2, a sixth rotating shaft 23 is arranged in the second groove 19, the second gear 24 can be supported by the sixth rotating shaft 23, so that the normal rotation of the second gear 24 can be further ensured, a fifth rotating shaft 20 is further arranged in the second groove 19, a first gear 22 and a second chain wheel 21 are arranged on the fifth rotating shaft 20, so that the meshing fluted disc 25 can be further driven to rotate in the sliding process of the second conveying belt 14, therefore, the meshing fluted disc 25 can be correspondingly meshed with the second gear 24, so that the second gear 24 can be further driven to rotate, the first gear 22 can be further driven to rotate, meanwhile, the second chain wheel 21 can be further driven to rotate, after the first chain wheel 18 and the second chain wheel 21 are correspondingly connected through the first chain 66, the second rotating shaft 6 can be further driven to rotate, the first conveying belt 7 can be further driven to rotate, the solar cell panel 10 can be driven to slide, the solar cell panel 10 can be further conveyed, and the first motor 64 can drive the third rotating shaft 11 to rotate, so that the second conveying belt 14 can be further driven to slide.
As shown in fig. 5, a first sliding hole 28 for supporting the first sliding shaft 34 to slide is disposed on the control head 15, a second sliding slot 32 correspondingly communicated with the first sliding hole 28 is disposed at an end of the control head 15, a first magnet 33 sliding in the second sliding slot 32 is disposed at one end of the first sliding shaft 34, the first electromagnet 16 is correspondingly repelled from the first magnet 33 after being powered on, a first spring 35 for biasing the first magnet 33 to slide is disposed in the second sliding slot 32, the butt joint 37 is disposed at the other end of the first sliding shaft 34, and the position of the first electromagnet 16 corresponds to the second engaging slot 36.
A first slide hole 28 is formed in the control head 15 so as to support the first slide shaft 34 through the first slide hole 28, thereby further ensuring the normal sliding of the first slide shaft 34, a second slide groove 32 is further formed in the control head 15, the second slide groove 32 is correspondingly communicated with the first slide hole 28, a first magnet 33 is arranged at one end of the first slide shaft 34, and the abutment 37 is arranged at the other end of the first slide shaft 34, after the first electromagnet 16 is powered on, the first slide shaft 34 can be further pushed to slide, the abutment 37 can be further pushed to slide into the second clamping groove 36, so that the control slider 46 can be further pushed to slide into the second clamping groove 36, the abutment 37 can be fixed by the control slider 46, so that the fixed block 26 can be further connected to the control head 15 in a corresponding manner, the fixed block 26 can be further conveyed, and the abutment 37 can be further returned by the biasing force of the first spring 35.
As shown in fig. 6, 7 and 8, the butt joint 37 is disposed in a conical shape, four fifth sliding grooves 47 are disposed on the butt joint 37, seventh rotating shafts 48 connected to the butt joint 37 are disposed in the fifth sliding grooves 47, the control sliders 46 rotate on the seventh rotating shafts 48, and third springs 49 for biasing the control sliders 46 are disposed in the fifth sliding grooves 47.
The butt joint 37 is the toper setting be provided with four fifth spouts 47 on the butt joint 37 be provided with a seventh pivot 48 in the fifth spout 47 respectively, thereby can pass through seventh pivot 48 is right control slider 46 supports, can butt joint 37 slides to after in the second joint groove 36, can pass through third spring 49 is right control slider 46 carries out the suppress after, can further make control slider 46 joint be in the second draw-in groove 36, thereby can further make fixed block 26 connects on the control head 15.
The second clamping grooves 36 are respectively arranged in a T shape, the second clamping grooves 36 respectively comprise a third sliding groove 38 arranged on the fixed block 26, the fixed block 26 is also respectively provided with a fourth sliding groove 39 corresponding to the third sliding groove 38, the second electromagnets 41 are respectively arranged in the fourth sliding grooves 39, the fourth sliding grooves 39 are respectively provided with a sliding second magnet 40, the second magnets 40 are respectively provided with a second sliding shaft 42 sliding in the third sliding grooves 38, the second sliding shafts 42 are respectively provided with a first clamping joint 44 sliding in the third sliding grooves 38, the first clamping joint 44 is respectively provided with an extrusion groove 45, the extrusion grooves 45 correspond to the four control sliding blocks 46, and the second electromagnets 41 repel corresponding to the second magnets 40 after being electrified, a second spring 43 for biasing the second magnet 40 is disposed in each of the fourth sliding grooves 39.
After the second electromagnet 41 is energized, the second electromagnet 40 can be further repelled, so that the second sliding shaft 42 can be further driven to slide, so that the first clamping head 44 can be further pushed to slide, the first clamping head 44 is provided with a pressing groove 45, so that the four control sliders 46 can be further pushed by the pressing groove 45, so that the control sliders 46 can be further contracted, so that the butt joint 37 can be further pushed out of the second clamping groove 36, so that after the fixed blocks 26 are conveyed, the butt joint 37 can be further separated from the second clamping groove 36, the solar cell panel 10 can be further conveyed, and the second magnet 40 can be pressed by the second spring 43, the first tab 44 can be further restored, the first tab 44 can be supported by the third slide groove 38, the normal sliding of the first tab 44 can be further ensured, and the separation of the control head 15 from the fixed block 26 can be further controlled by the energization of the second electromagnet 41.
As shown in fig. 10, a sixth sliding groove 54 is respectively disposed at an end of the connecting shaft 27, the sixth sliding grooves 54 are respectively disposed in a T shape, a third sliding shaft 55 sliding in the sixth sliding groove 54 is respectively disposed on the third magnet 52, the third sliding shaft 55 and the sixth sliding groove 54 are respectively disposed in a T shape, and a fourth spring 67 pulling the third sliding shaft 55 to slide is respectively disposed in the sixth sliding groove 54.
A sixth sliding groove 54 is provided at an end of the connecting shaft 27, the third sliding shaft 55 can be supported by the sixth sliding groove 54, so that the third sliding shaft 55 can be further ensured to slide normally, and the third sliding shaft 55 can be tensioned by the fourth spring 67, so that the third sliding shaft 55 can be further restored, and the third magnet 52 can be further pulled to be restored.
As shown in fig. 9 and 10, the first engaging groove 30 includes four seventh sliding grooves 56 respectively disposed in the mounting frame 2, the mounting frame 2 is provided with an eighth sliding groove 63 corresponding to the seventh sliding groove 56, the fourth electromagnet 61 is disposed in the eighth sliding groove 63, the end of the fourth sliding shaft 57 is provided with a fourth magnet 60 sliding in the eighth sliding groove 63, the fourth electromagnet 61 is magnetically connected to the fourth magnet 60 after being energized, the fourth sliding shaft 57 is provided with a pressing plate 58 sliding in the seventh sliding groove 56, the seventh sliding groove 56 is provided with a fourth spring 59 pressing the pressing plate 58, the end of the fourth sliding shaft 57 is provided with an engaging surface 62 disposed in an inclined manner, and the third magnet 52 corresponds to the engaging surface 62, a row of fifth electromagnets 68 corresponding to the first clamping grooves 30 are arranged on the mounting frame 2, and the fifth electromagnets 68 are repelled correspondingly to the first magnets 33 after being electrified.
In the sliding process of the fixing block 26, after the connecting shaft 27 slides to the position of the first engaging groove 30, in the power-on process of the third electromagnet 53, the magnetic attraction corresponding to the third magnet 52 can be further connected, so that the sliding of the third magnet 52 can be further driven, so that the connecting shaft 27 can be further driven to slide into the first engaging groove 30, since the end portions of the fourth sliding shaft 57 are respectively provided with the engaging surfaces 62 arranged in an inclined manner, the engaging surfaces 62 corresponding to the engaging surfaces 62 can be further engaged in the sliding process of the third magnet 52, so that the sliding of the fourth sliding shaft 57 can be pushed, the connecting shaft 47 can be further engaged with the third magnet 52 correspondingly, and the connection of the connecting shaft 27 to the mounting frame 2 can be realized, thereby enabling the fixation of the solar cell panel 10;
when the solar cell panel 10 is unloaded, the fourth electromagnet 61 can be energized to further magnetically attract and connect with the fourth magnet 60, so as to further drive the fourth sliding shaft 57 to slide, so as to further separate the third magnet 52 from the fourth sliding shaft 57, and the third magnet 52 can be further pulled to reset under the tension of the fourth spring 67, a row of fifth electromagnets 68 is disposed on the mounting bracket 2, the fifth electromagnets 68 respectively correspond to the first clamping grooves 30 disposed side by side, so as to further repel corresponding to the first magnet 33 after the fifth electromagnet 68 is energized, so as to further push the first magnet 33 to slide, so as to further push the docking head 37 to move, therefore, the butt joint 37 can further slide into the second clamping groove 36, further conveying of the fixing block 26 can be further achieved, unloading of the solar cell panel is achieved, damage to the solar cell panel under the condition of strong wind is prevented, and the fourth sliding shaft 57 can be further reset through elastic pressing of the fourth spring 59.
As shown in fig. 1 and 4, two sides of the mounting frame 2 are respectively provided with a first chute 31 for supporting the second conveyor belt 14 to slide, the first chute 31 is a T-shaped configuration, the second conveyor belt 14 is a T-shaped configuration, and the top of the mounting frame 2 is provided with a first rotary groove 29 for supporting the second rotary wheel 12 to rotate.
Can with first spout 31 sets up to be the setting of T type to can further assurance arrives second conveyor belt 14's normal slip, thereby guarantee to fixed block 26 carries out normal transport, can further assurance arrives first electro-magnet 16 can with the corresponding repulsive force of first magnet 33, simultaneously can further assurance arrives connection that the connecting axle can be accurate in first joint groove 30.
As shown in fig. 2, the meshing toothed plate 25 is made of rubber. The meshing toothed plate 25 can be made of a rubber material, and it can be further ensured that the meshing toothed plate 25 can rotate along with the second conveyor belt 14.
A storage battery is arranged in the fixed block 26, so that the storage battery can further store the electric power generated by the solar cell 10, and the second electromagnet 41 can be further powered, and a control module 65 can be arranged on the mounting frame 2, so that the coordinated operation of all the components can be further ensured through the control module 65.
The above-mentioned embodiments are only for convenience of description, and are not intended to limit the present invention in any way, and those skilled in the art will understand that the technical features of the present invention can be modified or changed by other equivalent embodiments without departing from the scope of the present invention.