CN211508995U - Shed roof type photovoltaic power generation board for fungus planting - Google Patents

Abstract

The utility model discloses a canopy formula photovoltaic power generation board is planted to fungus class, including first solar cell panel, second solar cell panel, third solar cell panel and mounting panel, first solar cell panel, second solar cell panel, third solar cell panel aligns the setting downwards for the slope, first solar cell panel's bilateral symmetry is provided with the mounting panel, from last first sliding tray that down has set gradually, second sliding tray and third sliding tray on the mounting panel, first solar cell panel, second solar cell panel, the first card wheel of the equal symmetrical fixedly connected with in one end both sides that third solar cell panel inclines downwards. The utility model discloses a be provided with a series of structures and make this device realize accomodating automatically photovoltaic power generation board in the use, avoid blowing and drenching damage to photovoltaic power generation board, improve life, and this device can improve the conversion of light energy.

Description

Shed roof type photovoltaic power generation board for fungus planting

Technical Field

The utility model relates to a plant and specifically be a shed roof formula photovoltaic power generation board is planted to fungus class with photovoltaic power generation board technical field.

Background

Along with the development of science and technology, big-arch shelter planting technique obtains promoting in fungus class planting field gradually, along with the popularization of green energy theory, photovoltaic power generation board is arranged in the power consumption that the big-arch shelter was planted gradually, at present, current planting photovoltaic power generation board for the big-arch shelter all is fixed mounting on the top surface of big-arch shelter, in the bad weather of blowing in the rain, fixed mounting often can cause the damage at the photovoltaic power generation board at big-arch shelter top, short service life, furthermore, current photovoltaic power generation board all is fixed mounting, can't come to carry out angle adjustment to photovoltaic power generation board according to the removal of sun, the conversion rate of light energy is lower, consequently, it is necessary to improve prior art, in order to solve above-mentioned.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a shed roof formula photovoltaic power generation board is planted to fungus to solve the current big-arch shelter that proposes in the above-mentioned background art and plant and can't accomodate with photovoltaic power generation board, long-time wind blows to drench and drenches the damage that causes power generation board easily and current big-arch shelter and plant and use photovoltaic power generation board for fixed mounting, the lower problem of light energy conversion rate.

In order to achieve the above object, the utility model provides a following technical scheme: a fungus planting shed roof type photovoltaic power generation panel comprises a first solar cell panel, a second solar cell panel, a third solar cell panel and mounting plates, wherein the first solar cell panel, the second solar cell panel and the third solar cell panel are arranged in an inclined downward alignment manner, the mounting plates are symmetrically arranged on two sides of the first solar cell panel, a first sliding groove, a second sliding groove and a third sliding groove are sequentially arranged on the mounting plates from top to bottom, the inclined downward ends of the first solar cell panel, the second solar cell panel and the third solar cell panel are symmetrically and fixedly connected with first clamping wheels on two sides, meanwhile, sliding plates are arranged on the center positions of the bottom surfaces of the inclined upward ends of the first solar cell panel, the second solar cell panel and the third solar cell panel, fourth sliding grooves are arranged on the sliding plates, a rotating shaft is arranged on one side below the sliding plates, the two ends of the rotating shaft are symmetrically provided with second clamping wheels, the top surface of one side of the mounting plate is fixedly connected with a rain shelter, a control box is fixedly installed on one side of the inner wall of the rain shelter, a single chip microcomputer is fixedly installed in the center of the inside of the control box, a relay is fixedly installed in the control box on one side of the single chip microcomputer, a current detection module and a wireless signal transmitter are respectively installed in the control box on the other side of the single chip microcomputer, and the single chip microcomputer is respectively and electrically connected with the relay, the current detection module and the wireless signal transmitter through conducting wires; the first clamping wheel at one end of the first solar cell panel is slidably clamped in the first sliding groove, the first clamping wheel at one end of the second solar cell panel is slidably clamped in the second sliding groove, and the first clamping wheel at one end of the third solar cell panel is slidably clamped in the third sliding groove.

Preferably, the second card wheel of first solar cell panel below slides the block in first sliding tray, and the one end of the axis of rotation of first solar cell panel below passes the outside that the second card wheel extended to the mounting panel and the output gomphosis of first motor, the first spacing of fixedly connected with on the first motor, and the both ends of first spacing slip the block in first sliding tray, first motor passes through conducting wire and relay electric connection.

Preferably, the second card wheel of second solar cell panel below slides the block in the second sliding tray, and the one end of the axis of rotation of second solar cell panel below passes the outside that the second card wheel extended to the mounting panel and the output gomphosis of second motor, fixedly connected with second spacing on the second motor, and the both ends of second spacing slip the block in the second sliding tray, the second motor passes through conducting wire and relay electric connection.

Preferably, the second card wheel of third solar cell panel below slides the block in the third sliding tray, and the one end of the axis of rotation of third solar cell panel below passes the outside that the second card wheel extended to the mounting panel and the output gomphosis of third motor, fixedly connected with third spacing on the third motor, and the both ends of third spacing slip the block in the third sliding tray, the third motor passes through conducting wire and relay electric connection.

Preferably, the connecting sleeve is rotatably sleeved outside the center of the rotating shaft, the limiting column is slidably clamped in the fourth sliding groove, and two ends of the limiting column are fixedly connected to the rotating frame.

Preferably, the connecting sleeve and the rotating frame are fixedly connected through an electric telescopic rod, and the electric telescopic rod is electrically connected with the relay through a conducting wire.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) the utility model is provided with the rain shelter, the mounting plate, the first sliding groove, the second sliding groove and the third sliding groove, when in use, when the wind and rain fall or the light energy collection cannot be carried out at night, the staff controls the electric telescopic rod to contract through the single chip microcomputer, under the action of the contraction of the electric telescopic rod, the angles between the first solar cell panel, the second solar cell panel and the third solar cell panel and the horizontal plane are reduced, at the moment, the first solar cell panel, the second solar cell panel and the third solar cell panel are gradually contracted to the lower part of the rain shelter for storage through the arrangement of the first sliding groove, the second sliding groove and the third sliding groove when the rotation of the first motor, the second motor and the third motor is respectively controlled, the photovoltaic power generation panel solves the problems that the existing photovoltaic power generation panel for greenhouse planting cannot be stored, and the power generation panel is easy to damage due to long-time wind, rain and rain;

(2) the utility model discloses a set up the singlechip, current detection module and electric telescopic handle, during the use, first solar cell panel, second solar cell panel and third solar cell panel are respectively in current detection module electric connection, in the in-process that uses, can carry out the real-time supervision of collecting current to the photovoltaic electroplax through the current detection module setting, when the electric current that detects is less than the predetermined value, the monolithic opportunity control electric telescopic handle is flexible, thereby the angle of adjustment photovoltaic electroplax improves daylighting efficiency, it is fixed mounting to have solved current photovoltaic power generation board for the big-arch shelter planting to should set up, the lower problem of light energy conversion rate.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a cross-sectional view of the present invention.

Fig. 3 is a schematic diagram of the internal structure of the middle control box of the present invention.

Fig. 4 is an enlarged view of a portion a in fig. 2 according to the present invention.

The reference numbers in the figures are: 1. a first solar cell panel; 2. a second solar panel; 3. a third solar cell panel; 4. a rain shelter; 5. a first sliding groove; 6. a second sliding groove; 7. a third sliding groove; 8. a first motor; 9. a first limit bracket; 10. mounting a plate; 11. a second motor; 12. a second limiting frame; 13. a third motor; 14. a third limiting frame; 15. a first chucking wheel; 16. a control box; 17. a second chucking wheel; 18. a current detection module; 19. a single chip microcomputer; 20. a wireless signal transmitter; 21. a relay; 22. a sliding plate; 23. a fourth sliding groove; 24. a limiting column; 25. a rotating frame; 26. an electric telescopic rod; 27. connecting sleeves; 28. and rotating the shaft.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides an embodiment: the utility model provides a canopy formula photovoltaic power generation board is planted to fungus class, including first solar cell panel 1, second solar cell panel 2, third solar cell panel 3 and mounting panel 10, first solar cell panel 1, second solar cell panel 2, third solar cell panel 3 aligns the setting downwards for the slope, first solar cell panel 1, second solar cell panel 2, third solar cell panel 3 is parallelly connected the setting, in the in-service use, operating personnel can increase or reduce the quantity of photovoltaic cell panel according to the size of big-arch shelter area, the bilateral symmetry of first solar cell panel 1 is provided with mounting panel 10, from last first sliding tray 5, second sliding tray 6 and the third sliding tray 7 of having set gradually down on mounting panel 10, first sliding tray 5, the setting of second sliding tray 6 and third sliding tray 7 can make first solar cell panel 1, second solar cell panel 2, The third solar cell panel 3 is independently stored, the two sides of the downward inclined end of the first solar cell panel 1, the second solar cell panel 2 and the third solar cell panel 3 are symmetrically and fixedly connected with first clamping wheels 15, meanwhile, the center positions of the bottom surfaces of the upward inclined ends of the first solar cell panel 1, the second solar cell panel 2 and the third solar cell panel 3 are respectively provided with a sliding plate 22, the arrangement of the first clamping wheels 15 can play a role of limiting and guiding the movement of the first solar cell panel 1, the second solar cell panel 2 and the third solar cell panel 3, the sliding plate 22 is provided with a fourth sliding groove 23, the matching arrangement of the sliding plate 22 and the fourth sliding groove 23 can realize the free adjustment of the angle of the first solar cell panel 1, the second solar cell panel 2 and the third solar cell panel 3, one side below the sliding plate 22 is provided with a rotating shaft 28, the two ends of the rotating shaft 28 are symmetrically provided with second clamping wheels 17, the arrangement of the second clamping wheels 17 can play a role of limiting and guiding the movement of the first solar cell panel 1, the second solar cell panel 2 and the third solar cell panel 3, the arrangement of the rotating shaft 28 can realize a transmission role, the top surface of one side of the mounting plate 10 is fixedly connected with a rain shelter 4, meanwhile, one side of the inner wall of the rain shelter 4 is fixedly provided with a control box 16, the arrangement of the rain shelter 4 can facilitate the wind and rain sheltering of the photovoltaic panels, the arrangement of the control box 16 can enable control elements to be in a relatively closed space to play a role of dust prevention and moisture prevention, the central position in the control box 16 is fixedly provided with a single chip microcomputer 19, the control box 16 on one side of the single chip microcomputer 19 is fixedly provided with a relay 21, and the control box 16 on the other side of the single chip microcomputer 19 is respectively provided with a current detection module 18, the current detection module 18 can detect the current amount converted by the photovoltaic panel at any time, the wireless signal emitter 20 is wirelessly connected with a mobile phone terminal, the single chip microcomputer 19 can be remotely controlled through the mobile phone terminal, and the single chip microcomputer 19 is electrically connected with the relay 21, the current detection module 18 and the wireless signal emitter 20 through conducting wires respectively; the first clamping wheels 15 on two sides of the lower end of the first solar cell panel 1, the second solar cell panel 2 and the third solar cell panel 3 are respectively clamped in the first sliding groove 5, the second sliding groove 6 and the third sliding groove 7 in a sliding mode.

Fixed connection's second card wheel 17 slip block is in first sliding tray 5 on the axis of rotation 28 both sides of first solar cell panel 1 below, first card wheel 15 is passed to the one end of axis of rotation 28 and is extended to the outside of first sliding tray 5 and the output gomphosis of first motor 8, the first spacing 9 of outside fixedly connected with of first motor 8, and the both ends slip block of first spacing 9 is in the first sliding tray 5 of first motor 8 both sides, the output and the relay 21 electric connection of first motor 8, under the rotation of first motor 8, can drive axis of rotation 28 and rotate, thereby second card wheel 17 rolls in first sliding tray 5, realize accomodating of first solar cell panel 1. Second calorie of wheel 17 slip block of fixed connection on the axis of rotation 28 both sides of second solar cell panel 2 below is in second sliding tray 6, the outside that second calorie of wheel 17 extended to second sliding tray 6 is passed to the one end of axis of rotation 28 and the output gomphosis of second motor 11, the outside fixedly connected with second spacing 12 of second motor 11, and the both ends slip block of second spacing 12 is in the second sliding tray 6 of second motor 11 both sides, the output and the relay 21 electric connection of second motor 11, under the rotation effect of second motor 11, can drive axis of rotation 28 and rotate, thereby second calorie of wheel 17 rolls in second sliding tray 6, realize accomodating of second solar cell panel 2. Second card wheel 17 sliding block of fixed connection on the axis of rotation 28 both sides of third solar cell panel 3 below is in third sliding tray 7, the outside that second card wheel 17 extended to third sliding tray 7 is passed to the one end of axis of rotation 28 and the output gomphosis of third motor 13, the outside fixedly connected with third spacing 14 of third motor 13, and the both ends sliding block of third spacing 14 is in the third sliding tray 7 of third motor 13 both sides, the output and the relay 21 electric connection of third motor 13, under the rotation effect of third motor 13, can drive axis of rotation 28 and rotate, thereby second card wheel 17 rolls in third sliding tray 7, realize accomodating of third solar cell panel 3.

The outer side of the center position of the rotating shaft 28 is rotatably sleeved with the connecting sleeve 27, one side of the fourth sliding groove 23 is slidably clamped with the limiting column 24, the limiting column 24 is fixedly connected to the inner side of the rotating frame 25, free rotation of the connecting sleeve 27 and the rotating frame 25 can be achieved through the arrangement, and therefore the electric telescopic rod 26 can be contracted. An electric telescopic rod 26 is arranged between the connecting sleeve 27 and the rotating frame 25, one end of the electric telescopic rod 26 is fixedly connected to the rotating frame 25 through a bolt, the other end of the electric telescopic rod 26 is fixedly welded to the outer surface of the connecting sleeve 27, and the input end of the electric telescopic rod 26 is electrically connected with the relay 21.

The working principle is as follows: when the device is used, the device is fixedly installed on the top surface of a greenhouse, through the arrangement of the wireless signal transmitter 20 and the mobile phone in a wireless connection manner, when the device is windy and rainy or cannot collect light energy at night, a worker can operate the single chip microcomputer 19 through the mobile phone to control the electric telescopic rod 26 to contract, under the action of the contraction of the electric telescopic rod 26, the angles between the first solar cell panel 1, the second solar cell panel 2 and the third solar cell panel 3 and the horizontal plane are reduced, at the moment, the rotation of the first motor 8, the second motor 11 and the third motor 13 is respectively controlled, through the arrangement of the first sliding groove 5, the second sliding groove 6 and the third sliding groove 7, the first solar cell panel 1, the second solar cell panel 2 and the third solar cell panel 3 are gradually contracted to the lower part of the rain shelter 4 to be collected, in addition, through the arrangement of the current detection module 18, the real-time monitoring of current collection can be carried out on the photovoltaic cell panels, when the detected current is smaller than the preset value, the single chip microcomputer 19 can control the electric telescopic rod 26 to stretch, so that the lighting efficiency is improved by adjusting the angle of the photovoltaic panel, and meanwhile, a user can adjust the angle of the photovoltaic panel through a mobile phone terminal.

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

Claims (6)

1. The utility model provides a canopy formula photovoltaic power generation board is planted to fungus class, includes first solar cell panel (1), second solar cell panel (2), third solar cell panel (3) and mounting panel (10), its characterized in that: the first solar cell panel (1), the second solar cell panel (2) and the third solar cell panel (3) are arranged in an inclined downward alignment manner, mounting plates (10) are symmetrically arranged on two sides of the first solar cell panel (1), a first sliding groove (5), a second sliding groove (6) and a third sliding groove (7) are sequentially arranged on the mounting plates (10) from top to bottom, first clamping wheels (15) are symmetrically and fixedly connected on two sides of the inclined downward end of each of the first solar cell panel (1), the second solar cell panel (2) and the third solar cell panel (3), sliding plates (22) are respectively arranged on the central positions of the bottom surfaces of the inclined upward ends of the first solar cell panel (1), the second solar cell panel (2) and the third solar cell panel (3), fourth sliding grooves (23) are arranged on the sliding plates (22), a rotating shaft (28) is arranged on one side below the sliding plate (22), second clamping wheels (17) are symmetrically arranged at two ends of the rotating shaft (28), a rain shelter (4) is fixedly connected to the top surface of one side of the mounting plate (10), a control box (16) is fixedly mounted on one side of the inner wall of the rain shelter (4), a single chip microcomputer (19) is fixedly mounted at the inner center position of the control box (16), a relay (21) is fixedly mounted in the control box (16) on one side of the single chip microcomputer (19), a current detection module (18) and a wireless signal emitter (20) are respectively mounted in the control box (16) on the other side of the single chip microcomputer (19), and the single chip microcomputer (19) is respectively and electrically connected with the relay (21), the current detection module (18) and the wireless signal emitter (20) through conducting wires; the first clamping wheel (15) at one end of the first solar cell panel (1) is slidably clamped in the first sliding groove (5), the first clamping wheel (15) at one end of the second solar cell panel (2) is slidably clamped in the second sliding groove (6), and the first clamping wheel (15) at one end of the third solar cell panel (3) is slidably clamped in the third sliding groove (7).

2. The fungus planting shed roof type photovoltaic power generation panel according to claim 1, characterized in that: second card wheel (17) slip block of first solar cell panel (1) below is in first sliding tray (5), and the one end of axis of rotation (28) of first solar cell panel (1) below passes second card wheel (17) and extends to the outside of mounting panel (10) and the output gomphosis of first motor (8), first spacing (9) of fixedly connected with on first motor (8), and the both ends slip block of first spacing (9) is in first sliding tray (5), first motor (8) are through conducting wire and relay (21) electric connection.

3. The fungus planting shed roof type photovoltaic power generation panel according to claim 1, characterized in that: second card wheel (17) slip block of second solar cell panel (2) below is in second sliding tray (6), and the one end of axis of rotation (28) of second solar cell panel (2) below passes second card wheel (17) and extends to the outside of mounting panel (10) and the output gomphosis of second motor (11), fixedly connected with second spacing (12) on second motor (11), and the both ends slip block of second spacing (12) is in second sliding tray (6), second motor (11) are through conducting wire and relay (21) electric connection.

4. The fungus planting shed roof type photovoltaic power generation panel according to claim 1, characterized in that: second card wheel (17) slip block of third solar cell panel (3) below is in third sliding tray (7), and the one end of axis of rotation (28) of third solar cell panel (3) below passes second card wheel (17) and extends to the outside of mounting panel (10) and the output gomphosis of third motor (13), fixedly connected with third spacing (14) on third motor (13), and the both ends slip block of third spacing (14) is in third sliding tray (7), third motor (13) are through conducting wire and relay (21) electric connection.

5. The fungus planting shed roof type photovoltaic power generation panel according to claim 1, characterized in that: the connecting sleeve (27) is rotatably sleeved outside the center position of the rotating shaft (28), the limiting column (24) is slidably clamped in the fourth sliding groove (23), and two ends of the limiting column (24) are fixedly connected in the rotating frame (25).

6. The fungus planting shed roof type photovoltaic power generation panel according to claim 5, wherein: the connecting sleeve (27) and the rotating frame (25) are fixedly connected through an electric telescopic rod (26), and the electric telescopic rod (26) is electrically connected with the relay (21) through a conducting wire.

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