CN218958853U - Wind-resistant high-stability photovoltaic power generation equipment - Google Patents

Abstract

The utility model relates to the technical field of environment-friendly energy sources, and provides wind-resistant high-stability photovoltaic power generation equipment which comprises a mounting plate and solar panel bodies, wherein a plurality of solar panel bodies are distributed on the mounting plate, and support rods are further arranged on the mounting plate and are connected with the solar panel bodies through an adjusting mechanism; the adjusting mechanism comprises a containing cavity arranged in the supporting rod, a plurality of equidistant uniformly distributed moving grooves are arranged between the containing cavity and the supporting rod, and an angle adjusting assembly is arranged in each moving groove; the angle adjusting component comprises a first screw rod which is rotatable in the accommodating cavity, the peripheral surface of the first screw rod is connected with a sliding ring through threads, when the moving ring and the sliding block move simultaneously in the face of severe weather, the angle between the solar panel body and the mounting plate is reduced, the height of the solar panel body is reduced to enable the solar panel body to be close to the mounting plate as much as possible, the gravity center of the integral mechanism is reduced, the blocking of the volume of the solar panel body to wind is reduced, and therefore wind resistance is improved.

Description

Wind-resistant high-stability photovoltaic power generation equipment

Technical Field

The utility model relates to the technical field of environment-friendly energy, in particular to wind-resistant high-stability photovoltaic power generation equipment.

Background

A solar cell, also called a "solar chip" or a "photovoltaic cell", is a photovoltaic semiconductor sheet that directly generates electricity using sunlight. The single solar cell cannot be directly used as a power supply. The solar cells are connected in series and parallel and tightly packaged into a component; the solar panel is an assembled part of a plurality of solar cells assembled according to the assembly, and is a core part in a solar power generation system and a most important part in the solar power generation system.

According to retrieval discovery, chinese patent No. CN202123289544.9 discloses a wind-resistant high stability photovoltaic power generation device, including the installation face, the top surface of installation face is annular equidistance and articulates there is the solar panel main part, the surface of solar panel main part articulates there is first articulated elements, the one end that solar panel main part was kept away from to first articulated elements articulates there is the second articulated elements, the one end that first articulated elements was kept away from to the second articulated elements articulates there is the third articulated elements, the one end that second articulated elements was kept away from to the third articulated elements articulates there is the fourth articulated elements.

Aiming at the technology, the inventor believes that the device is formed by the structure of each group of solar panels, and the formed whole is close to the shape of a hemisphere, so that the wind direction is guided, the wind resistance is reduced, the wind resistance and the stability of the solar panels are improved, but the trend of wind is not uniform when the device encounters severe weather such as typhoons, and the wind direction is changeable, so that the device is difficult to guide the wind.

Disclosure of Invention

The utility model provides wind-resistant high-stability photovoltaic power generation equipment, which solves the problem of wind-resistant high-stability photovoltaic power generation equipment in the related technology.

The technical scheme of the utility model is as follows:

the wind-resistant high-stability photovoltaic power generation equipment comprises a mounting plate and solar panel bodies, wherein a plurality of solar panel bodies are distributed on the mounting plate, a supporting rod is further arranged on the mounting plate, and the supporting rod is connected with the solar panel bodies through an adjusting mechanism;

the adjusting mechanism comprises a containing cavity arranged in the supporting rod, a plurality of equidistant uniformly distributed moving grooves are arranged between the containing cavity and the supporting rod, and an angle adjusting assembly is arranged in each moving groove;

the angle adjusting assembly comprises a first screw rod which is rotatable in the accommodating cavity, the peripheral surface of the first screw rod is connected with a sliding ring through threads, the sliding ring can linearly reciprocate along the axis of the first screw rod, the peripheral surface of the sliding ring is rotationally connected to one side of the solar panel body through a connecting rod, and the position adjusting assembly is arranged below the solar panel body;

the position adjusting assembly comprises a second screw rod which can rotate, a sliding block which can reciprocate along the axis of the second screw rod is connected to the outer peripheral surface of the second screw rod in a threaded manner, and the upper surface of the sliding block is rotationally connected below the solar panel body.

Further, adjustment mechanism still includes power component, and power component includes the support frame of fixed connection in the support bar one end of keeping away from the mounting panel, and fixed surface is connected with first motor on the support frame, and the output of first motor passes and offers the through-hole on the support frame and pass through shaft coupling fixedly connected with output shaft one end, and the output shaft other end passes through shaft coupling fixed connection in first lead screw one end, and first lead screw other end is rotated through the bearing and is connected and is being close to mounting panel one end at holding the cavity.

Further, the adjusting mechanism further comprises a plurality of equidistant uniformly distributed movable seats fixedly connected to the peripheral surface of the sliding ring, the movable seats are rotatably connected to one end of the connecting rod through pin shafts, the other end of the connecting rod is rotatably connected with a fixed seat through pin shafts, and the fixed seat is fixedly connected to one side, close to the supporting rod, of the solar panel body.

Further, the position adjusting assembly further comprises rotating seats fixedly connected to two ends of the upper surface of the sliding block, and the rotating seats are rotatably connected with one end, close to the mounting plate, of the solar panel body through pin shafts.

Further, the position adjusting assembly further comprises a driving assembly, the driving assembly comprises a second motor, the output end of the second motor is fixedly connected with one end of a connecting shaft through a coupler, the peripheral surface of the other end of the connecting shaft is connected with a driving bevel gear in a key manner, the driving bevel gear is connected with a driven bevel gear in a transmission manner, and the driven bevel gear is connected with the peripheral surface of one end of a second screw in a key manner.

Further, a plurality of equidistant evenly distributed holding grooves are formed in the mounting plate, position adjusting components are arranged in the holding grooves, two ends in the holding grooves are rotationally connected to two ends of the second screw rod through bearings, and the bottom surfaces of the holding grooves are used for mounting the second motor.

Further, through holes are further formed in the two ends of the sliding block, guide rods are connected in the through holes in a sliding mode, and the two ends of the guide rods are fixedly connected to the two ends of the containing groove.

Further, a plurality of equally spaced drain holes are formed in one end, far away from the support rod, of the accommodating groove.

The working principle and the beneficial effects of the utility model are as follows:

1. in the utility model, when facing severe weather, the movable ring and the sliding block move simultaneously, so that the angle between the solar panel body and the mounting plate is reduced, the height of the solar panel body is reduced to be as close as possible to the mounting plate, the gravity center of the integral mechanism is reduced, the blocking of the volume of the solar panel body to wind is reduced, and the wind resistance is improved.

2. In the utility model, when the solar panel body is in normal use, the second motor is driven to drive the second screw rod to rotate, the second screw rod is driven to rotate to drive the sliding block to move, and the sliding block moves and simultaneously drives the rotating seat at the bottom of the solar panel body to rotate by taking the rotating seat at the upper surface of the sliding block as the circle center, so that the angle of the solar panel body is adjusted, and the angle between the solar panel body and the sun is more suitable.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

FIG. 1 is a perspective view of the overall structure of the present utility model;

FIG. 2 is a schematic perspective view of the adjusting mechanism of the present utility model;

FIG. 3 is a schematic perspective view of an adjustment mechanism according to the present utility model;

fig. 4 is a cross-sectional view of an adjustment mechanism of the present utility model.

In the figure: 1. a mounting plate; 2. a solar panel body; 3. a support rod; 4. an adjusting mechanism; 41. an angle adjustment assembly; 411. a first motor; 412. a support frame; 413. a fixing seat; 414. a connecting rod; 415. a first lead screw; 416. a slip ring; 417. a movable seat; 42. a position adjustment assembly; 421. a second motor; 422. a second lead screw; 423. a receiving groove; 424. a guide rod; 425. a slide block; 426. a drive bevel gear; 427. a driven bevel gear; 43. a drain hole; 44. a receiving cavity; 45. and a moving groove.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

As shown in fig. 1-4, the embodiment provides a wind-resistant high-stability photovoltaic power generation device, which comprises a mounting plate 1 and a solar panel body 2, wherein a plurality of solar panel bodies 2 are distributed on the mounting plate 1, a supporting rod 3 is further arranged on the mounting plate 1, and the supporting rod 3 is connected with the solar panel body 2 through an adjusting mechanism 4;

the adjusting mechanism 4 comprises a containing cavity 44 arranged in the supporting rod 3, a plurality of equidistant and uniformly distributed moving grooves 45 are arranged between the containing cavity 44 and the supporting rod 3, and an angle adjusting component 41 is arranged in the moving grooves 45;

the angle adjusting assembly 41 comprises a first screw rod 415 which is rotatable in the accommodating cavity 44, the outer peripheral surface of the first screw rod 415 is connected with a sliding ring 416 through threads, the sliding ring 416 can linearly reciprocate along the axis of the first screw rod 415, the outer peripheral surface of the sliding ring 416 is rotationally connected to one side of the solar panel body 2 through a connecting rod 414, and the position adjusting assembly 42 is arranged below the solar panel body 2;

the position adjusting assembly 42 comprises a rotatable second screw 422, a sliding block 425 capable of moving back and forth along the axis of the second screw 422 is connected to the outer peripheral surface of the second screw 422 in a threaded mode, and the upper surface of the sliding block 425 is connected below the solar panel body 2 in a rotating mode. Starting the first motor 411, rotating the output end of the first motor 411 to drive the first screw rod 415 to rotate, moving the peripheral surface sliding ring 416 of the first screw rod 415, moving the sliding ring 416 to drive the top end of the solar panel body 2 to move, meanwhile, starting the second motor 421, rotating the output end of the second motor 421 to drive the drive bevel gear 426 to rotate, driving the drive bevel gear 426 to drive the driven bevel gear 427 to rotate through gear engagement, driving the driven bevel gear 427 to drive the second screw rod 422 to rotate, moving the sliding block 425 on the second screw rod 422 along the axis of the second screw rod 422, sliding two sides of the sliding block 425 along the guide rod 424, driving the bottom end of the solar panel body 2 to rotate and move simultaneously by a rotating seat above the sliding block 425, and integrally closing the solar panel body 2 to the mounting plate 1 when the sliding ring 416 descends to the limit position of the first screw rod 415.

The adjusting mechanism 4 further comprises a power component, the power component comprises a supporting frame 412 fixedly connected to one end, far away from the mounting plate 1, of the supporting rod 3, a first motor 411 is fixedly connected to the upper surface of the supporting frame 412, the output end of the first motor 411 penetrates through a through hole formed in the supporting frame 412 and is fixedly connected with one end of an output shaft through a coupler, the other end of the output shaft is fixedly connected to one end of a first screw rod 415 through the coupler, and the other end of the first screw rod 415 is rotatably connected to one end, close to the mounting plate 1, of the accommodating cavity 44 through a bearing. The output end of the first motor 411 rotates to drive the first screw rod 415 to rotate, the peripheral surface of the first screw rod 415 moves with the sliding ring 416, and the sliding ring 416 moves to drive the top end of the solar panel body 2 to move.

The adjusting mechanism 4 further comprises a plurality of equidistant uniformly distributed movable seats 417 fixedly connected to the outer peripheral surface of the sliding ring 416, the movable seats 417 are rotatably connected to one end of the connecting rod 414 through pin shafts, the other end of the connecting rod 414 is rotatably connected with a fixed seat 413 through pin shafts, and the fixed seat 413 is fixedly connected to one side, close to the supporting rod 3, of the solar panel body 2. The connection rod 414 rotates between the moving seat 417 and the fixing seat 413, so that more angles can be obtained when the solar panel body 2 rotates.

The position adjusting assembly 42 further comprises rotating seats fixedly connected to two ends of the upper surface of the sliding block 425, and the rotating seats are rotatably connected with one end, close to the mounting plate 1, of the solar panel body 2 through pin shafts. The rotating seat drives one end of the solar panel body 2 to rotate, so that a better angle between the solar panel body and the sun is obtained.

The position adjusting assembly 42 further comprises a driving assembly, the driving assembly comprises a second motor 421, the output end of the second motor 421 is fixedly connected with one end of a connecting shaft through a coupler, the outer peripheral surface of the other end of the connecting shaft is connected with a driving bevel gear 426 in a key manner, the driving bevel gear 426 is connected with a driven bevel gear 427 in a transmission manner, and the driven bevel gear 427 is connected with the outer peripheral surface of one end of the second screw 422 in a key manner. The output end of the second motor 421 rotates to drive the drive bevel gear 426 to rotate, the drive bevel gear 426 drives the driven bevel gear 427 to rotate through gear engagement, the driven bevel gear 427 drives the second screw 422 to rotate, and the sliding block 425 on the second screw 422 moves along the axis of the second screw 422.

A plurality of equally spaced evenly distributed accommodating grooves 423 are formed in the mounting plate 1, position adjusting assemblies 42 are arranged in the accommodating grooves 423, two ends in the accommodating grooves 423 are rotatably connected to two ends of a second screw rod 422 through bearings, and the bottom surface of the accommodating grooves 423 is used for mounting a second motor 421.

Through holes are further formed in the two ends of the sliding block 425, the guide rods 424 are slidably connected in the through holes, and the two ends of the guide rods 424 are fixedly connected to the two ends of the accommodating groove 423. The slider 425 maintains its balance at both ends by the guide rod 424 when the second screw 422 moves.

The holding groove 423 is far away from the support rod 3 one end and is provided with a plurality of equidistant evenly distributed drain holes 43. The outside discharges the accumulated water dropped into the accommodating groove 423 through the drain hole 43.

In this embodiment, the first motor 411 is started, the output end of the first motor 411 rotates to drive the first screw 415 to rotate, the peripheral surface of the first screw 415 moves with the sliding ring 416, the sliding ring 416 moves to drive the top end of the solar panel body 2 to move, meanwhile, the second motor 421 is started, the output end of the second motor 421 rotates to drive the drive bevel gear 426 to rotate, the drive bevel gear 426 drives the driven bevel gear 427 to rotate through gear engagement, the driven bevel gear 427 drives the second screw 422 to rotate, the sliding block 425 on the second screw 422 moves along the axis of the second screw 422, two sides of the sliding block 425 slide along the guide rod 424, the rotating seat above the sliding block 425 drives the bottom end of the solar panel body 2 to rotate and move simultaneously, and when the sliding ring 416 descends to the limit position of the first screw 415, the solar panel body 2 is integrally close to the mounting plate 1, and resistance of the integral mechanism to the typhoon is reduced.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (8)

1. The wind-resistant high-stability photovoltaic power generation equipment is characterized by comprising a mounting plate (1) and a solar panel body (2), wherein a plurality of solar panel bodies (2) are distributed on the mounting plate (1), a supporting rod (3) is further arranged on the mounting plate (1), and the supporting rod (3) is connected with the solar panel body (2) through an adjusting mechanism (4);

the adjusting mechanism (4) comprises a containing cavity (44) arranged in the supporting rod (3), a plurality of equidistant and uniformly distributed moving grooves (45) are arranged between the containing cavity (44) and the supporting rod (3), and an angle adjusting assembly (41) is arranged in the moving grooves (45);

the angle adjusting assembly (41) comprises a first screw rod (415) which is rotatable in a containing cavity (44), the outer peripheral surface of the first screw rod (415) is connected with a sliding ring (416) through threads, the sliding ring (416) can linearly reciprocate along the axis of the first screw rod (415), the outer peripheral surface of the sliding ring (416) is rotationally connected to one side of the solar panel body (2) through a connecting rod (414), and the position adjusting assembly (42) is arranged below the solar panel body (2);

the position adjusting assembly (42) comprises a second screw rod (422) which is rotatable, a sliding block (425) which can reciprocate along the axis of the second screw rod (422) is connected to the outer peripheral surface of the second screw rod (422) in a threaded mode, and the upper surface of the sliding block (425) is rotatably connected below the solar panel body (2).

2. The wind-resistant high-stability photovoltaic power generation device according to claim 1, wherein the adjusting mechanism (4) further comprises a power assembly, the power assembly comprises a supporting frame (412) fixedly connected to one end of the supporting rod (3) far away from the mounting plate (1), a first motor (411) is fixedly connected to the upper surface of the supporting frame (412), an output end of the first motor (411) penetrates through the supporting frame (412) to be provided with one end of an output shaft fixedly connected with the output shaft through a shaft coupling, the other end of the output shaft is fixedly connected to one end of a first lead screw (415) through the shaft coupling, and the other end of the first lead screw (415) is rotatably connected to one end of the accommodating cavity (44) close to the mounting plate (1) through a bearing.

3. The wind-resistant high-stability photovoltaic power generation device according to claim 2, wherein the adjusting mechanism (4) further comprises a plurality of equidistant uniformly distributed movable seats (417) fixedly connected to the outer peripheral surface of the sliding ring (416), the movable seats (417) are rotatably connected to one end of the connecting rod (414) through pin shafts, the other end of the connecting rod (414) is rotatably connected with a fixing seat (413) through pin shafts, and the fixing seat (413) is fixedly connected to one side, close to the supporting rod (3), of the solar panel body (2).

4. A wind-resistant high-stability photovoltaic power generation device according to claim 3, wherein the position adjusting component (42) further comprises rotating seats fixedly connected to two ends of the upper surface of the sliding block (425), and the rotating seats are rotatably connected with one end, close to the mounting plate (1), of the solar panel body (2) through pin shafts.

5. The wind-resistant high-stability photovoltaic power generation device according to claim 4, wherein the position adjusting assembly (42) further comprises a driving assembly, the driving assembly comprises a second motor (421), an output end of the second motor (421) is fixedly connected with one end of a connecting shaft through a coupling, a driving bevel gear (426) is connected to the other end of the connecting shaft through a peripheral surface key, a driven bevel gear (427) is connected to the driving bevel gear (426) in a driving manner, and the driven bevel gear (427) is connected to the peripheral surface of one end of the second screw (422) through a key.

6. The wind-resistant high-stability photovoltaic power generation device according to claim 5, wherein a plurality of equally-spaced accommodating grooves (423) are formed in the mounting plate (1), the accommodating grooves (423) are internally provided with position adjusting assemblies (42), two ends in the accommodating grooves (423) are rotatably connected to two ends of the second screw rod (422) through bearings, and the bottom surfaces of the accommodating grooves (423) are used for mounting the second motor (421).

7. The wind-resistant high-stability photovoltaic power generation device according to claim 6, wherein through holes are further formed in two ends of the sliding block (425), guide rods (424) are slidably connected in the through holes, and two ends of the guide rods (424) are fixedly connected to two ends of the accommodating groove (423).

8. The wind-resistant high-stability photovoltaic power generation device according to claim 7, wherein a plurality of equally-spaced drain holes (43) are formed in one end, far away from the supporting rod (3), of the accommodating groove (423).

Images