CN220857976U - Photovoltaic power generation board installation adjustment mechanism - Google Patents

Abstract

The utility model provides a photovoltaic power generation plate installation and adjustment mechanism, which relates to the technical field of photovoltaic power generation and aims to solve the problem that when the photovoltaic power generation plate is installed through hoisting equipment, the photovoltaic power generation plate is easy to deviate and needs to be adjusted and aligned repeatedly in the process of air stagnation, and the photovoltaic power generation plate installation and adjustment mechanism comprises a linkage structure and a supporting structure; the top of the linkage structure is movably connected with a lifting structure, the linkage structure and the lifting structure are simultaneously and movably connected with a control mechanism, and the control mechanism is simultaneously and movably connected with a turnover structure; the supporting structure is respectively and movably connected with the control mechanism and the turnover structure, and the turnover structure comprises: the supporting shaft is movably connected with the bearing frame, the bearing frame is internally provided with the reserved groove, the lifting rings are respectively and fixedly connected to one side of the bottom of the bearing frame, the bearing frame can store and bear the photovoltaic power generation plate through the reserved groove arranged in the bearing frame, and the photovoltaic power generation plate is prevented from being offset when being installed in a hoisting mode.

Description

Photovoltaic power generation board installation adjustment mechanism

Technical Field

The utility model relates to the technical field of photovoltaic power generation, in particular to a photovoltaic power generation plate installation adjusting mechanism.

Background

Photovoltaic power generation is a technology that uses the photovoltaic effect of a semiconductor interface to directly convert light energy into electrical energy. The photovoltaic power generation panel mainly comprises three parts of a solar panel (assembly), a controller and an inverter, wherein the main parts are composed of electronic components, and the photovoltaic power generation panel needs auxiliary installation through hoisting equipment and the like during installation.

The inventor discovers that when the existing photovoltaic power generation plate installation adjusting mechanism is used, most photovoltaic power generation plates are installed in an auxiliary mode through hoisting equipment during installation, but when the photovoltaic power generation plates are installed through the hoisting equipment, the photovoltaic power generation plates are easy to deviate during air stagnation, the photovoltaic power generation plates need to be installed after being adjusted repeatedly, and the photovoltaic power generation plates are more complicated to install.

Disclosure of Invention

The utility model aims to provide a photovoltaic power generation plate installation adjusting mechanism, which solves the problem that the photovoltaic power generation plate is easy to deviate and needs to be adjusted repeatedly to be aligned when in a dead space during installation through hoisting equipment in the prior art.

The purpose and the efficacy of the installation and adjustment mechanism of the practical photovoltaic power generation plate are achieved by the following specific technical means:

The photovoltaic power generation plate installation adjusting mechanism comprises a linkage structure and a supporting structure; the top of the linkage structure is movably connected with a lifting structure, the linkage structure and the lifting structure are simultaneously and movably connected with a control mechanism, and the control mechanism is simultaneously and movably connected with a turnover structure; the supporting structure is respectively and movably connected with the control mechanism and the turnover structure, and the turnover structure comprises: the device comprises a supporting shaft, a bearing frame, a reserved groove and a hanging ring, wherein the supporting shaft is movably connected with the bearing frame, the reserved groove is arranged in the bearing frame at the same time, and the hanging ring is fixedly connected to one side of the bottom of the bearing frame respectively.

Further, the linkage structure includes: bottom plate, guide bar A, the sliding tray, the link, the carousel, the drive belt, the connecting plate, telescopic link A, sliding bar A, nut A, fixedly connected with four guide bar A of group on the bottom plate, the both sides of bottom plate are equipped with the sliding tray simultaneously, link fixed connection is in one side of bottom plate, the link respectively with telescopic link A, sliding bar A sliding connection, and telescopic link A, sliding bar A fixed connection is in one side of connecting plate, the both ends of connecting plate rotate respectively and are connected with the carousel, carousel while with drive belt swing joint, telescopic link A rotates with nut A simultaneously to be connected, nut A rotates and connects in one side of link, the drive belt adopts hinge structure, its effect is, can control two sets of carousels simultaneously through the drive belt and rotate, be equipped with the screw thread on the telescopic link A, its effect is, when nut A rotates, can control telescopic link A and telescopic link A can also carry out spacingly through connecting plate and sliding bar A.

Further, the lifting structure includes: the utility model provides a universal driving axle, the supporting shoe, connecting block A, the slider, the bracing piece, connecting block B, the connecting axle, the universal driving axle rotates with the supporting shoe to be connected, the supporting shoe is fixed connection at the top of bottom plate simultaneously, the universal driving axle rotates with connecting block A simultaneously, connecting block A's bottom fixedly connected with slider, the slider passes through sliding tray sliding connection in the bottom plate, fixedly connected with connecting axle on connecting block A and the connecting block B, the both ends of bracing piece rotate with the connecting axle respectively to be connected, the one end of connecting axle simultaneously with carousel swing joint, the both ends of universal driving axle are equipped with the screw thread respectively, and the screw thread at control axle both ends is two-way setting, its effect is, when the universal driving axle rotates, can inwards slide by two sets of connecting blocks A of simultaneous control.

Further, the control mechanism includes: the bearing plate, the preformed hole, the motor, the spool, the gag lever post, be equipped with the preformed hole around the bearing plate respectively, the bearing plate passes through preformed hole and guide bar A sliding connection, the inside fixedly connected with motor of bearing plate, spool fixed connection is on the motor, and the spool rotates simultaneously with the bearing plate to be connected, the bearing plate simultaneously with connecting block B fixed connection, the one end fixedly connected with gag lever post of spool, the gag lever post respectively with carousel swing joint, the motor adopts servo motor, its effect is, servo motor can control the speed, the position accuracy is very accurate.

Further, the overturning structure further comprises: the hanging wire, the both ends of hanging wire simultaneously with spool, rings swing joint, back shaft fixed connection is on the loading board, and the reservation groove is echelonment setting, and its effect is, through the reservation groove of echelonment setting, can make the loading frame deposit and bear the weight of photovoltaic electroplax.

Further, the support structure includes: the fixed axle, the spliced pole, slide bar B, the mount, the dwang, nut B, anchor clamps, guide bar B, telescopic link B, the fixed axle is fixed connection respectively on loading board and carriage, the fixed axle simultaneously with the dwang, slide bar B swing joint, dwang and slide bar B sliding connection, the both sides of dwang are fixedly connected with mount respectively, rotate respectively on the mount and be connected with the dwang, fixedly connected with nut B in the dwang, nut B rotates simultaneously with telescopic link B to be connected, telescopic link B and slide bar B are fixed connection respectively in one side of anchor clamps, slide bar B simultaneously with mount sliding connection, anchor clamps laminating simultaneously in slide bar B's both sides, anchor clamps are the arc setting respectively, its effect is, can make the good laminating of anchor clamps to slide bar B's both sides, telescopic link B adopts the screw rod equally.

Compared with the prior structure, the utility model has the following advantages:

1. The linkage structure can control the linkage shaft to rotate simultaneously while the rotating disc and the driving belt rotate on the spool, so that the control mode is simple, and meanwhile, the linkage structure can also switch whether the linkage shaft is linked or not, and the working efficiency of the photovoltaic power generation panel during adjustment can be effectively improved.

2. According to the lifting structure, when the linkage shaft rotates, the two groups of connecting blocks A can be controlled to slide inwards or outwards simultaneously through the linkage shaft, the control mode is simple, meanwhile, the supporting plate can be controlled to lift through the supporting rods, and the installation height of the photovoltaic power generation plate can be effectively adjusted according to different environments.

3. According to the utility model, the setting of the control mechanism can control the spool to rotate through the motor, the lifting wire can be recovered when the spool rotates, the bearing frame is controlled to overturn, and the photovoltaic power generation panel is installed at different angles, so that the applicability of the installation equipment in use is further improved.

4. According to the utility model, the support structure is arranged, the rotating column and the sliding rod B can be limited and fixed through the clamp, and one side of the bearing frame is supported through the rotating column and the sliding rod B, so that the bearing frame is prevented from automatically overturning, and meanwhile, the stability of the photovoltaic power generation panel during installation can be improved.

5. According to the utility model, the overturning structure is arranged, and the bearing frame can store and bear the photovoltaic power generation plate through the reserved groove arranged in the bearing frame, so that the photovoltaic power generation plate is prevented from being deviated when the photovoltaic power generation plate is installed in a hoisting mode, and the working efficiency of the photovoltaic power generation plate in installation can be effectively ensured.

Drawings

FIG. 1 is a schematic top view of the present utility model;

FIG. 2 is a schematic cross-sectional view of the present utility model;

FIG. 3 is a schematic view of a linkage structure according to the present utility model;

FIG. 4 is a schematic view of a lifting structure according to the present utility model;

FIG. 5 is a schematic cross-sectional view of a control mechanism according to the present utility model;

FIG. 6 is a schematic diagram of a flip structure according to the present utility model;

fig. 7 is a schematic structural view of the support structure of the present utility model.

In the figure:

1. A linkage structure; 101. a bottom plate; 102. a guide rod A; 103. a sliding groove; 104. a connecting frame; 105. a turntable; 106. a transmission belt; 107. a connecting plate; 108. a telescopic rod A; 109. a sliding rod A; 110. a nut A;

2. A lifting structure; 201. a linkage shaft; 202. a support block; 203. a connecting block A; 204. a slide block; 205. a support rod; 206. a connecting block B; 207. a connecting shaft;

3. A control mechanism; 301. a carrying plate; 302. a preformed hole; 303. a motor; 304. a spool; 305. a limit rod;

4. A turnover structure; 401. a support shaft; 402. a carrying frame; 403. a reserved groove; 404. a hanging ring; 405. a hanging wire;

5. A support structure; 501. a fixed shaft; 502. rotating the column; 503. a sliding rod B; 504. a fixing frame; 505. a rotating lever; 506. a nut B; 507. a clamp; 508. a guide rod B; 509. and a telescopic rod B.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples.

Referring to fig. 1 to 7, the photovoltaic power generation panel installation adjusting mechanism comprises a linkage structure 1 and a supporting structure 5; the top of the linkage structure 1 is movably connected with a lifting structure 2, the linkage structure 1 and the lifting structure 2 are simultaneously and movably connected with a control mechanism 3, and the control mechanism 3 is simultaneously and movably connected with a turnover structure 4; the supporting structure 5 is movably connected with the control mechanism 3 and the turnover structure 4 respectively, and the turnover structure 4 comprises: the support shaft 401 is movably connected with the bearing frame 402, the bearing frame 402 is internally provided with the reserved groove 403, and the hanging ring 404 is respectively and fixedly connected to one side of the bottom of the bearing frame 402.

As shown in fig. 3, the linkage 1 includes: the bottom plate 101, guide bar A102, sliding tray 103, link 104, carousel 105, drive belt 106, connecting plate 107, telescopic link A108, slide bar A109, nut A110, four guide bars A102 of fixedly connected with on the bottom plate 101, the both sides of bottom plate 101 are equipped with sliding tray 103 simultaneously, link 104 fixed connection is in one side of bottom plate 101, link 104 respectively with telescopic link A108, slide bar A109 sliding connection, and telescopic link A108, slide bar A109 fixed connection is in one side of connecting plate 107, the both ends of connecting plate 107 rotate respectively and are connected with carousel 105, carousel 105 simultaneously with drive belt 106 swing joint, telescopic link A108 simultaneously with nut A110 rotate to be connected in one side of link 104, simultaneously control universal driving shaft 201 rotates when can be rotated with drive belt 106 through carousel 105, control mode is comparatively simple, can also switch when can be linked driving shaft 201 not the linkage, work efficiency when can effectual improvement photovoltaic power generation board adjusts.

As shown in fig. 4, wherein the elevating structure 2 comprises: the universal driving shaft 201, the supporting block 202, the connecting block A203, the sliding block 204, the supporting rod 205, the connecting block B206 and the connecting shaft 207, the universal driving shaft 201 is rotationally connected with the supporting block 202, the supporting block 202 is fixedly connected to the top of the bottom plate 101 at the same time, the universal driving shaft 201 is rotationally connected with the connecting block A203 at the same time, the sliding block 204 is fixedly connected with the sliding block 204 at the bottom of the connecting block A203, the sliding block 204 is slidably connected in the bottom plate 101 through the sliding groove 103, the connecting shaft 207 is fixedly connected to the connecting block A203 and the connecting block B206, two ends of the supporting rod 205 are respectively rotationally connected with the connecting shaft 207, one end of the connecting shaft 207 is movably connected with the turntable 105, when the universal driving shaft 201 rotates, the two groups of connecting blocks A203 can be controlled to simultaneously inwards or outwards slide through the universal driving shaft 201, and the supporting plate 301 can be controlled to lift through the supporting rod 205 at the same time when the control mode is simpler.

As shown in fig. 5, wherein the control mechanism 3 includes: the bearing plate 301, the preformed hole 302, the motor 303, the spool 304, the gag lever post 305, be equipped with the preformed hole 302 around the bearing plate 301 respectively, the bearing plate 301 passes through preformed hole 302 and guide bar A102 sliding connection, the inside fixedly connected with motor 303 of bearing plate 301, spool 304 fixed connection is on motor 303, and spool 304 rotates with bearing plate 301 simultaneously and is connected, bearing plate 301 simultaneously with connecting block B206 fixed connection, spool 304's one end fixedly connected with gag lever post 305, spool 304, gag lever post 305 respectively with carousel 105 swing joint, can control spool 304 through motor 303 and rotate, and spool 304 can retrieve the hanging wire 405 when rotating, and control carrier frame 402 and overturn, and make the photovoltaic power generation board install at different angles, further improvement the suitability when erection equipment uses.

As shown in fig. 6, the flip structure 4 further includes: the hanging wire 405, the both ends of hanging wire 405 simultaneously with spool 304, rings 404 swing joint, back shaft 401 fixed connection is on loading board 301, can make loading board 402 deposit and bear the weight of photovoltaic power generation board through the reservation groove 403 that sets up in the loading board 402, avoid leading to photovoltaic power generation board to take place the skew when installing photovoltaic power generation board through the mode of hoist and mount, work efficiency when can effectually guaranteeing photovoltaic power generation board installation.

As shown in fig. 7, wherein the support structure 5 comprises: the photovoltaic power generation device comprises a fixed shaft 501, a rotating column 502, a sliding rod B503, a fixed frame 504, a rotating rod 505, a nut B506, a clamp 507, a guide rod B508 and a telescopic rod B509, wherein the fixed shaft 501 is fixedly connected to a bearing plate 301 and a bearing frame 402 respectively, the fixed shaft 501 is movably connected with the rotating column 502 and the sliding rod B503 simultaneously, the rotating column 502 is in sliding connection with the sliding rod B503, the fixed frames 504 are fixedly connected to two sides of the rotating column 502 respectively, the rotating rod 505 is respectively connected to the fixed frames 504 in a rotating manner, the nut B506 is fixedly connected to the telescopic rod B509 simultaneously, the telescopic rod B509 is fixedly connected to one side of the clamp 507 respectively, the sliding rod B503 is simultaneously in sliding connection with the fixed frame 504, the clamp 507 is simultaneously attached to two sides of the sliding rod B503, the rotating column 502 and the sliding rod B503 can be limited and fixed through the clamp 507, one side of the bearing frame 402 is supported through the rotating column 502 and the sliding rod B503, and the automatic overturning of the bearing frame 402 is avoided, and meanwhile the stability of the photovoltaic power generation device during installation can be improved.

The working principle of the embodiment is as follows:

In the utility model, firstly, a photovoltaic power generation plate is placed on a bearing frame 402 through a reserved groove 403, then the photovoltaic power generation plate is moved to a designated installation position, then a nut A110 is rotated, a telescopic rod A108 and a connecting plate 107 are controlled to slide to one side, a turntable 105 is respectively connected with a linkage shaft 201 and a spool 304, a motor 303 is started, the linkage shaft 201 and the spool 304 are controlled to rotate simultaneously through the turntable 105 and a transmission belt 106, the height of the photovoltaic power generation plate can be adjusted, meanwhile, a lifting wire 405 can be recovered through the spool 304, the bearing frame 402 is controlled to overturn, a motor 303 can be started, a nut B506 can be rotated firstly, a clamp 507, a guide rod B508 and a telescopic rod B509 are controlled to slide through the nut B506, when the bearing frame 402 is overturned, a rotating column 502 and a sliding rod B503 are enabled to stretch, and after the clamp 507 is attached to the sliding rod B503, the rotating column 502 and the sliding rod B503 can be limited, and the bearing frame 402 can be supported through the rotating column 502 and the sliding rod B503.

Claims (6)

1. Photovoltaic power generation board installation adjustment mechanism, its characterized in that: comprises a linkage structure (1) and a supporting structure (5); the top of the linkage structure (1) is movably connected with a lifting structure (2), the linkage structure (1) and the lifting structure (2) are simultaneously and movably connected with a control mechanism (3), and the control mechanism (3) is simultaneously and movably connected with a turnover structure (4); the supporting structure (5) is respectively movably connected with the control mechanism (3) and the turnover structure (4), and the turnover structure (4) comprises: the device comprises a supporting shaft (401), a bearing frame (402), a reserved groove (403) and a hanging ring (404), wherein the supporting shaft (401) is movably connected with the bearing frame (402), the reserved groove (403) is arranged in the bearing frame (402) at the same time, and the hanging ring (404) is fixedly connected to one side of the bottom of the bearing frame (402) respectively.

2. The photovoltaic panel installation adjustment mechanism of claim 1, wherein: the linkage structure (1) comprises: bottom plate (101), guide bar A (102), sliding tray (103), link (104), carousel (105), drive belt (106), connecting plate (107), telescopic link A (108), slide bar A (109), nut A (110), four guide bar A (102) of fixedly connected with on bottom plate (101), the both sides of bottom plate (101) are equipped with sliding tray (103) simultaneously, link (104) fixed connection is in one side of bottom plate (101), link (104) respectively with telescopic link A (108), slide bar A (109) sliding connection, and telescopic link A (108), slide bar A (109) fixed connection is in one side of connecting plate (107), both ends of connecting plate (107) are rotated respectively and are connected with carousel (105), carousel (105) simultaneously with drive belt (106) swing joint, telescopic link A (108) simultaneously with nut A (110) swivelling joint, nut A (110) swivelling joint is in one side of link (104).

3. The photovoltaic panel installation adjustment mechanism of claim 2, wherein: the lifting structure (2) comprises: the device comprises a linkage shaft (201), a supporting block (202), a connecting block A (203), a sliding block (204), a supporting rod (205), a connecting block B (206) and a connecting shaft (207), wherein the linkage shaft (201) is rotationally connected with the supporting block (202), the supporting block (202) is fixedly connected to the top of a bottom plate (101) at the same time, the linkage shaft (201) is rotationally connected with the connecting block A (203) at the same time, the sliding block (204) is fixedly connected with the bottom of the connecting block A (203) in the bottom plate (101) through a sliding groove (103) in a sliding mode, the connecting block A (203) and the connecting block B (206) are fixedly connected with the connecting shaft (207), two ends of the supporting rod (205) are rotationally connected with the connecting shaft (207) respectively, and one end of the connecting shaft (207) is movably connected with a turntable (105) at the same time.

4. The photovoltaic panel installation adjustment mechanism of claim 2, wherein: the control mechanism (3) includes: the bearing plate (301), preformed hole (302), motor (303), spool (304), gag lever post (305), be equipped with preformed hole (302) around carrier plate (301) respectively, carrier plate (301) are through preformed hole (302) and guide bar A (102) sliding connection, the inside fixedly connected with motor (303) of carrier plate (301), spool (304) fixed connection is on motor (303), and spool (304) are simultaneously with carrier plate (301) swivelling joint, carrier plate (301) simultaneously with connecting block B (206) fixed connection, one end fixedly connected with gag lever post (305) of spool (304), gag lever post (305) respectively with carousel (105) swing joint.

5. The photovoltaic panel installation adjustment mechanism of claim 4, wherein: the flip structure (4) further comprises: the lifting wire (405), both ends of lifting wire (405) are simultaneously with spool (304), rings (404) swing joint, and back shaft (401) fixed connection is on loading board (301).

6. The photovoltaic panel installation adjustment mechanism of claim 4, wherein: the support structure (5) comprises: fixed axle (501), rotating post (502), slide bar B (503), mount (504), rotating rod (505), nut B (506), anchor clamps (507), guide bar B (508), telescopic link B (509), fixed axle (501) are fixed connection respectively on loading board (301) and loading frame (402), fixed axle (501) simultaneously with rotating post (502), slide bar B (503) swing joint, rotating post (502) and slide bar B (503) sliding connection, both sides of rotating post (502) are fixed connection mount (504) respectively, rotate respectively on mount (504) and are connected with rotating rod (505), fixedly connected with nut B (506) in rotating rod (505), nut B (506) simultaneously with telescopic link B (509) rotate to be connected, telescopic link B (509) and slide bar B (503) are fixed connection respectively on one side of anchor clamps (507), slide bar B (503) simultaneously with mount (504) sliding connection, anchor clamps (507) laminating simultaneously in both sides of slide bar B (503).