CN218958824U - Stable splicing structure of photovoltaic panel - Google Patents

Abstract

The utility model relates to the technical field of photovoltaic panel splicing structures, in particular to a photovoltaic panel stable splicing structure which comprises two strip blocks, wherein connecting blocks are movably connected between two ends of the two strip blocks, a plurality of linearly arranged mounting grooves are formed in the corresponding side surfaces of the two connecting blocks, racks are mounted at the bottoms of the two connecting blocks through screws, mounting blocks are mounted at one ends of the two racks through screws, the two mounting blocks are respectively mounted at the bottoms of the two connecting blocks, gears are meshed between the two racks, and driving motors coaxially arranged are mounted on the surfaces of the gears through screws. This scheme is through setting up a plurality of linear arrangement mounting grooves and two connecting blocks, and two connecting blocks set up the both sides at a plurality of photovoltaic electric plates, and a plurality of mounting grooves can supply the both ends grafting of a plurality of photovoltaic electric plates for fix the photovoltaic electric plate between two connecting blocks, promoted the stability in a plurality of photovoltaic electric plates place.

Description

Stable splicing structure of photovoltaic panel

Technical Field

The utility model relates to the technical field of photovoltaic panel splicing structures, in particular to a photovoltaic panel stable splicing structure.

Background

In the prior art, the disclosed photovoltaic panel splicing structure with the patent number of CN202121099902.7 is characterized in that six groups of photovoltaic panels form a hexagon, when wind exists outside, wind power can enter and exit through a wind groove, so that the six groups of photovoltaic panels and side plates at two sides of the photovoltaic panels are blown to rotate between support plates at two sides, illumination irradiated to the surfaces of the photovoltaic panels can be continuously utilized after being reflected, and the utilization rate of the photovoltaic panels for illumination is increased; the disadvantage of this patent is that the area of the three photovoltaic panels located below receiving the illumination is small, so the efficiency of the photovoltaic panels for generating electricity is reduced after the photovoltaic panels rotate below, and the power generation efficiency is further reduced;

in the prior art, the photovoltaic electric plates are arranged on the surfaces of the supports through the screws, and the number of the screws required is increased along with the increase of the number of the photovoltaic electric plates, so that the supports convenient for dismounting the photovoltaic electric plates are also arranged.

Disclosure of Invention

The utility model aims to solve the defects in the prior art, and provides a stable splicing structure of a photovoltaic panel.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a stable mosaic structure of photovoltaic panel, includes two rectangular pieces, two rectangular piece symmetrical arrangement, two swing joint has the connecting block between rectangular piece both ends, two a plurality of linear arrangement's mounting groove has all been seted up to the side that the connecting block position corresponds, two connecting block symmetrical arrangement, two the rack is all installed through the screw to the bottom of connecting block, two the installation piece is installed through the screw to the one end of rack, two the installation piece is installed respectively in the bottom of two connecting blocks, two the meshing has the gear between the rack, the driving motor of coaxial arrangement is installed through the screw on the surface of gear.

Preferably, the motor support is installed at the bottom of the shell of the driving motor through screws, and two ends of the motor support are respectively installed at the bottoms of the two long strips through screws.

Preferably, the bottom of connecting block is installed two sliders through the screw, two the spout has all been seted up at the top of rectangular piece, two the bottom of slider extends to the inside of two spouts respectively.

Preferably, a supporting plate is installed between the side surfaces of the two strip-shaped blocks through screws, two strip-shaped holes are formed in the surface of the supporting plate, the positions of the two strip-shaped holes and the positions of the two racks correspond, the two installation blocks are respectively inserted into the two strip-shaped holes in a sliding mode, and a positioning mechanism is arranged between the supporting plate and the racks.

Preferably, the positioning mechanism comprises a second fixing plate and a first fixing plate, one ends of the second fixing plate and the first fixing plate are arranged at the bottom of the supporting plate through screws, sliding rods are arranged on the side surfaces of the second fixing plate in a penetrating mode, the surfaces of the sliding rods are in sliding contact with the inner walls of the second fixing plate, mounting plates are arranged at one ends of the sliding rods through screws, a plurality of tooth blocks are arranged on the side surfaces of the mounting plates through screws, the tooth blocks are inserted into tooth grooves of the gears, compression springs are movably sleeved on the surfaces of the sliding rods, two ends of each compression spring are respectively arranged on the side surfaces of the mounting plates and the side surfaces of the second fixing plate through screws, electromagnets are arranged at the other ends of the sliding rods through screws, metal blocks are arranged on the side surfaces of the first fixing plate through screws, and the side surface spacing between each metal block and each electromagnet is larger than the length dimension of each tooth block.

Preferably, the surface of backup pad runs through and installs the bearing, the inner circle close-fitting grafting of bearing has the transmission shaft, the bottom of transmission shaft passes through the screw and installs on the surface of gear, gear and transmission shaft coaxial arrangement.

Preferably, the bottoms of the two ends of the two long strip blocks are respectively provided with a supporting leg through screws.

Preferably, at least three mounting grooves are arranged, and the mounting grooves are equidistantly arranged.

Compared with the prior art, the utility model has the following beneficial effects:

according to the scheme, the plurality of mounting grooves and the two connecting blocks are linearly arranged, the two connecting blocks are arranged on two sides of the plurality of photovoltaic electric plates, the plurality of mounting grooves can be used for plugging two ends of the plurality of photovoltaic electric plates, the photovoltaic electric plates are fixed between the two connecting blocks, and the stability of the positions of the plurality of photovoltaic electric plates is improved;

this scheme is through setting up driving motor, gear and two racks, and driving motor control gear rotates, and the gear drives two rack synchronous movement, and two racks drive two connecting blocks synchronous movement for make things convenient for two connecting blocks to fix the both ends centre gripping of photovoltaic electricity board, for the mode of using the screw fixation, saved the time of operation, promoted the efficiency of fixed a plurality of photovoltaic electricity boards.

Drawings

FIG. 1 is an isometric view of a photovoltaic panel stabilizing splice structure of the present utility model;

fig. 2 is a schematic diagram of a connection structure of a support plate, a gear and a rack of a photovoltaic panel stable splicing structure according to the present utility model;

fig. 3 is a schematic diagram of a gear and rack structure of a stable splicing structure of a photovoltaic panel according to the present utility model;

fig. 4 is a schematic structural diagram of a positioning mechanism of a stable splicing structure of a photovoltaic panel according to the present utility model;

fig. 5 is a schematic structural diagram of a connecting block of a photovoltaic panel stable splicing structure of the present utility model.

In the figure: the sliding chute 1, the transmission shaft 2, the sliding block 3, the supporting leg 4, the driving motor 5, the motor support 6, the supporting plate 7, the long bar 8, the connecting block 9, the mounting groove 10, the bearing 11, the long bar hole 12, the limiting piece 13, the gear 14, the rack 15, the tooth block 16, the first fixing plate 17, the mounting plate 18, the compression spring 19, the second fixing plate 20, the sliding rod 21, the metal block 22, the electromagnet 23 and the mounting block 24.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the utility model. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art.

The stable splicing structure of the photovoltaic panel shown in fig. 1-5 comprises two strip blocks 8, wherein the two strip blocks 8 are symmetrically arranged, a connecting block 9 is movably connected between two ends of the two strip blocks 8, a plurality of linearly arranged mounting grooves 10 are formed in the corresponding side surfaces of the two connecting blocks 9, the two connecting blocks 9 are symmetrically arranged, racks 15 are arranged at the bottoms of the two connecting blocks 9 through screws, mounting blocks 24 are arranged at one ends of the two racks 15 through screws, the two mounting blocks 24 are respectively arranged at the bottoms of the two connecting blocks 9, gears 14 are meshed between the two racks 15, and a driving motor 5 coaxially arranged is arranged on the surface of each gear 14 through screws; at least three mounting grooves 10 are arranged, and the mounting grooves 10 are equidistantly arranged; when the position of a plurality of photovoltaic electric plates is fixed, firstly, one end of each photovoltaic electric plate is inserted into a plurality of mounting grooves 10 in one connecting block 9 respectively, then the driving motor 5 is controlled to work, the driving motor 5 controls the gear 14 to rotate, the gear 14 drives two racks 15 to move, the two racks 15 drive the two connecting blocks 9 to be close to each other through the two mounting blocks 24, and when the plurality of mounting grooves 10 on the other connecting block 9 are sleeved on the other ends of the photovoltaic electric plates, the two ends of the photovoltaic electric plates are clamped and limited, so that the splicing and the mounting of the photovoltaic electric plates are facilitated, the working efficiency is improved, and the working time is saved.

The bottom of the shell of the driving motor 5 is provided with a motor support 6 through screws, and two ends of the motor support 6 are respectively arranged at the bottoms of two strip blocks 8 through screws; the motor support 6 is used for supporting the drive motor 5.

Two sliding blocks 3 are arranged at the bottom of the connecting block 9 through screws, sliding grooves 1 are formed in the tops of the two strip blocks 8, and the bottom ends of the two sliding blocks 3 extend to the inner parts of the two sliding grooves 1 respectively; the connecting block 9 drives the sliding block 3 to slide in the sliding groove 1 of the strip block 8 during sliding, so that the stability of the connecting block 9 during sliding on the strip block 8 is improved.

The supporting plate 7 is arranged between the side surfaces of the two strip blocks 8 through screws, two strip holes 12 are formed in the surface of the supporting plate 7, the positions of the two strip holes 12 and the positions of the two racks 15 correspond, the two mounting blocks 24 are respectively inserted into the two strip holes 12 in a sliding mode, the supporting plate 7 is used for receiving a photovoltaic electric plate separated from the two connecting blocks 9, the photovoltaic electric plate is prevented from falling on the ground during disassembly, and the photovoltaic electric plate plays a supporting role; the elongated aperture 12 allows the mounting block 24 to slide.

A positioning mechanism is arranged between the supporting plate 7 and the rack 15; the positioning mechanism comprises a second fixed plate 20 and a first fixed plate 17, one ends of the second fixed plate 20 and the first fixed plate 17 are arranged at the bottom of the supporting plate 7 through screws, sliding rods 21 are arranged on the side surfaces of the second fixed plate 20 in a penetrating mode, the surfaces of the sliding rods 21 are in sliding contact with the inner wall of the second fixed plate 20, mounting plates 18 are arranged at one ends of the sliding rods 21 through screws, a plurality of tooth blocks 16 are arranged on the side surfaces of the mounting plates 18 through screws, the tooth blocks 16 are inserted into tooth grooves of the gears 14, compression springs 19 are movably sleeved on the surfaces of the sliding rods 21, two ends of the compression springs 19 are respectively arranged on the side surfaces of the mounting plates 18 and the side surfaces of the second fixed plate 20 through screws, electromagnets 23 are arranged at the other ends of the sliding rods 21 through screws, metal blocks 22 are arranged on the side surfaces of the first fixed plate 17 through screws, and the side surface spacing between the metal blocks 22 and the electromagnets 23 is larger than the length dimension of the tooth blocks 16; after the photovoltaic panel is clamped and fixed, in order to improve the stability of the photovoltaic panel clamped by the two connecting blocks 9, the electrifying operation of the electromagnet 23 is also required to be canceled, at the moment, the compression spring 19 in a compressed state reversely pushes the mounting plate 18, and the mounting plate 18 drives the tooth block 16 to be inserted into the tooth groove of the gear 14 so as to play a limiting role on the torque direction of the gear 14; when the two connecting blocks 9 need to be controlled to move, the electromagnet 23 is electrified, magnetic force is generated after the electromagnet 23 is electrified, the electromagnet 23 attracts the metal block 22 through the magnetic force, and the position of the metal block 22 is unchanged, therefore, the electromagnet 23 pulls the mounting plate 18 through the sliding rod 21, the mounting plate 18 pulls the tooth block 16 to move out of a tooth slot of the gear 14, meanwhile, the mounting plate 18 presses the compression spring 19, the length of the compression spring 19 is shortened after being stressed, and at the moment, the gear 14 is not affected by a limited position in the torque direction.

The surface of the supporting plate 7 is provided with a bearing 11 in a penetrating way, the inner ring of the bearing 11 is closely connected with a transmission shaft 2 in a plugging way, the bottom end of the transmission shaft 2 is arranged on the surface of a gear 14 through a screw, and the gear 14 and the transmission shaft 2 are coaxially arranged; the arrangement of the bearing 11 can enable the transmission shaft 2 to rotate on the supporting plate 7, so that the stability of the gear 14 in the rotating process is improved.

The bottoms of the two ends of the two strip blocks 8 are respectively provided with a supporting leg 4 through screws; the support legs 4 serve to support the device.

In this scheme, driving motor 5 and electro-magnet 23 are all connected with the PLC controller through the wire, and the PLC controller passes through the wire to be connected with external power source, and external power source is chargeable call.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined by the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides a stable mosaic structure of photovoltaic panel, includes two rectangular piece (8), its characterized in that, two rectangular piece (8) symmetrical arrangement, two swing joint has connecting block (9) between rectangular piece (8) both ends, two a plurality of linear arrangement's mounting groove (10) have all been seted up to the side that connecting block (9) correspond in position, two connecting block (9) symmetrical arrangement, two rack (15) are all installed through the screw to the bottom of connecting block (9), two install installation piece (24) through the screw to the one end of rack (15), two install respectively in the bottom of two connecting blocks (9) installation piece (24), two the meshing has gear (14) between rack (15), the surface of gear (14) is through screw-mounting coaxial arrangement's driving motor (5).

2. The photovoltaic panel stable splicing structure according to claim 1, wherein the motor support (6) is mounted on the bottom of the casing of the driving motor (5) through screws, and two ends of the motor support (6) are respectively mounted on the bottoms of two long blocks (8) through screws.

3. The photovoltaic panel stable splicing structure according to claim 1, wherein the bottom of the connecting block (9) is provided with two sliding blocks (3) through screws, the tops of the two long blocks (8) are provided with sliding grooves (1), and the bottom ends of the two sliding blocks (3) respectively extend to the inside of the two sliding grooves (1).

4. The photovoltaic panel stable splicing structure according to claim 1, wherein a supporting plate (7) is mounted between the side surfaces of the two strip blocks (8) through screws, two strip holes (12) are formed in the surface of the supporting plate (7), the positions of the two strip holes (12) and the positions of the two racks (15) correspond, the two mounting blocks (24) are respectively inserted into the two strip holes (12) in a sliding mode, and a positioning mechanism is arranged between the supporting plate (7) and the racks (15).

5. The photovoltaic panel stable splicing structure according to claim 4, wherein the positioning mechanism comprises a second fixing plate (20) and a first fixing plate (17), one ends of the second fixing plate (20) and the first fixing plate (17) are mounted at the bottom of the supporting plate (7) through screws, sliding rods (21) are mounted on the side surfaces of the second fixing plate (20) in a penetrating manner, the surfaces of the sliding rods (21) are in sliding contact with the inner wall of the second fixing plate (20), mounting plates (18) are mounted on one ends of the sliding rods (21) through screws, a plurality of tooth blocks (16) are mounted on the side surfaces of the mounting plates (18) through screws, the tooth blocks (16) are inserted into tooth grooves of the gears (14), compression springs (19) are movably sleeved on the surfaces of the sliding rods (21), two ends of each compression spring (19) are mounted on the side surfaces of the mounting plates (18) and the second fixing plate (20) through screws, electromagnets (23) are mounted on the other ends of the sliding rods (21), and the side surfaces of the first fixing plates (17) are mounted with large-size metal blocks (22) through screws, and the large-size distance between the side surfaces of the metal blocks (22) is larger than that the metal blocks (22).

6. The photovoltaic panel stable splicing structure according to claim 4, wherein the bearing (11) is installed on the surface of the supporting plate (7) in a penetrating manner, the transmission shaft (2) is tightly inserted into the inner ring of the bearing (11), the bottom end of the transmission shaft (2) is installed on the surface of the gear (14) through a screw, and the gear (14) and the transmission shaft (2) are coaxially arranged.

7. The photovoltaic panel stable splicing structure according to claim 1, wherein the bottoms of both ends of the two elongated blocks (8) are provided with supporting legs (4) by screws.

8. The photovoltaic panel stable splicing structure according to claim 1, wherein at least three mounting grooves (10) are provided, and the mounting grooves (10) are arranged at equal intervals.

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