CN212645895U

CN212645895U - Illumination intensity detection device for greenhouse

Info

Publication number: CN212645895U
Application number: CN202021145736.5U
Authority: CN
Inventors: 朱广唱; 丁芳芳; 朱广园; 洪逸波
Original assignee: Zhejiang Qimei Ecological Agriculture Co ltd
Current assignee: Zhejiang Qimei Ecological Agriculture Co ltd
Priority date: 2020-06-18
Filing date: 2020-06-18
Publication date: 2021-03-02
Anticipated expiration: 2030-06-18

Abstract

The utility model discloses an illumination intensity detection device for big-arch shelter, including the big-arch shelter main part, illumination intensity tester and displacement device, the last movable plate that is provided with of displacement device, movable plate one and big-arch shelter main part inner wall sliding fit, cavity one has been seted up on the lateral wall of big-arch shelter main part, cavity one internal fixation has motor one, be fixed with belt pulley one on the output shaft of motor one, the arc wall has been seted up on a cavity diapire, conveyer groove one has been seted up on the cavity lateral wall, be provided with in the arc wall with arc wall sliding fit's slide bar, the overcoat has belt pulley two with slide bar normal running fit on the slide bar, belt pulley one and belt pulley two pass belt and are connected, the overcoat has microscler frame on the slide bar, cavity one internal fixation has the cylinder, the piston rod and the microscler frame fixed connection of cylinder.

Description

Illumination intensity detection device for greenhouse

Technical Field

The utility model relates to a plant detects technical field, in particular to illumination intensity detection device for big-arch shelter.

Background

The greenhouse originally is special equipment for vegetable production, and the application of the greenhouse is more extensive along with the development of production. The current greenhouse is used for pot flower and cut flower cultivation; fruit tree production is used for cultivating grapes, strawberries, watermelons, melons, peaches, oranges and the like; the forestry production is used for forest seedling culture, ornamental tree culture and the like; the breeding industry is used for silkworm breeding, chicken breeding, cattle breeding, pig breeding, fish breeding, fry breeding and the like.

In the big-arch shelter, in order to provide the suitable illumination intensity of plant, generally can detect the illumination intensity in the big-arch shelter, convenient regulation, but present illumination detector is fixed mostly, can't remove easily, can't detect the illumination intensity of different places.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a light intensity detection device for big-arch shelter has the effect that each department detected in the big-arch shelter.

The above technical purpose of the present invention can be achieved by the following technical solutions:

a lighting intensity detection device for a greenhouse comprises a greenhouse main body, a lighting intensity tester placed in the greenhouse main body and used for detecting lighting intensity, and a displacement device arranged in the greenhouse main body and used for moving the lighting intensity tester, wherein a first movable plate is arranged on the displacement device and is in sliding fit with the inner wall of the greenhouse main body, a first cavity is formed in the side wall of the greenhouse main body, a first motor is fixed in the first cavity, a first belt pulley is fixed on an output shaft of the first motor, an arc-shaped groove is formed in the bottom wall of the first cavity, a first transmission groove is formed in the side wall of the first cavity, a slide bar in sliding fit with the arc-shaped groove is arranged in the arc-shaped groove, a second belt pulley in rotating fit with the slide bar is sleeved outside the slide bar, the first belt pulley and the second belt pulley are connected through a first belt, and a long frame is, the utility model discloses a lighting device, including cavity one, transfer trough one, bearing groove one.

By adopting the technical scheme, when the illumination intensity in the greenhouse is detected, when the illumination intensity tester moves along the first movable plate, the air cylinder is started, the piston rod of the air cylinder extends out to drive the long frame to move, the long frame moves to drive the slide rod to move along the arc-shaped groove, the slide rod moves to drive the belt pulley second to move until the belt pulley second and the belt pulley first are in the same straight line, the belt pulley first is in contact with the belt pulley fifth at the moment, the air cylinder is closed, the motor I is started, the output shaft of the motor I rotates to drive the belt pulley first to rotate, the belt pulley first rotates to drive the belt pulley first to transmit, the belt pulley fifth rotates to drive the belt pulley fifth to rotate, the belt pulley fifth rotates to drive the supporting rod first to rotate, the supporting rod rotates to drive the bevel gear first to rotate, the bevel gear rotates to drive the threaded rod first to rotate, the threaded rod rotates to drive the, the displacement device drives the illumination intensity tester to move in other directions.

Preferably, the displacement device comprises a second motor, a second threaded rod and a third motor, a first chute is formed in the ground in the greenhouse main body, the second motor is fixed in the first chute, the second threaded rod is fixedly connected with an output shaft of the second motor, a second moving plate in sliding fit with one side wall of the chute is arranged in the first chute, the second moving plate is in threaded fit with the second threaded rod, a second cavity is formed in the second moving plate, the third motor is fixed in the greenhouse main body, a telescopic rod is fixed on the output shaft of the third motor, a T-shaped limiting groove is formed in the side wall of the second cavity, a limiting rod is placed in the T-shaped limiting groove, one end, away from the third motor, of the telescopic rod is fixedly connected with the limiting rod, a third belt pulley is fixed on the telescopic rod, a second support rod is fixed in the second cavity, and a fourth belt, a second belt is arranged between the third belt pulley and the fourth belt pulley, the third belt pulley and the fourth belt pulley are connected through the second belt, a second sliding groove is formed in the side wall of the second cavity, a sliding block in sliding fit with the second sliding groove is arranged in the second sliding groove, one end of the sliding block is fixedly connected with the second belt, and the other end of the sliding block is fixed with the first movable plate.

By adopting the technical scheme, when the illumination intensity tester is driven to move along the first direction of the sliding groove, the second motor is started, the output shaft of the second motor rotates to drive the second threaded rod to rotate, the second threaded rod rotates to drive the second movable plate to move, the second movable plate moves to drive the first movable plate to move, the telescopic rod is lengthened or shortened while the second movable plate moves, the first movable plate moves to drive the illumination intensity tester to move along the first direction of the sliding groove, when the illumination intensity tester is driven to move in the vertical direction, the third motor is started, the output shaft of the third motor rotates to drive the third belt pulley to rotate, the third belt pulley rotates to drive the second belt to convey, the second belt conveys to drive the sliding block to move, the first movable plate moves to drive the illumination intensity tester to move in the vertical direction, and the effect of driving the illumination intensity tester to move towards the two directions is.

Preferably, a row of laser transmitters are fixed on the inner wall of the greenhouse main body, a row of laser receivers are fixed on one side, close to the laser transmitters, of the first movable plate, the laser transmitters are matched with the laser receivers, and the laser receivers are electrically connected with the motor.

By adopting the technical scheme, the laser receiver moves along with the first moving plate, when the laser receiver receives laser emitted by the laser emitter, the laser receiver sends a signal to the third motor, and the third motor is closed, so that the effect of preventing the moving plate from moving downwards too low is achieved.

Preferably, a control panel is fixed in the greenhouse main body.

By adopting the technical scheme, the control panel plays a role in controlling the first motor, the second motor, the third motor and the cylinder.

Preferably, the second motor and the third motor are sleeved with the first protective shell, and the first protective shell is fixed with the ground in the greenhouse main body.

By adopting the technical scheme, the first protective shell plays a role in protecting the second motor and the third motor.

Preferably, the cylinder is externally sleeved with a second protective shell fixedly connected with the inner wall of the first cavity.

By adopting the technical scheme, the second protective shell plays a role in protecting the cylinder.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment;

FIG. 2 is a schematic view for showing five parts of a driving pulley;

FIG. 3 is a schematic diagram for showing the structure of the horizontal moving part of the displacement device;

fig. 4 is a schematic structural view for showing a vertically moving part of the displacement device.

Reference numerals: 1. a greenhouse main body; 2. an illumination intensity tester; 3. a displacement device; 4. moving a first plate; 5. a first cavity; 6. a first motor; 7. a first belt pulley; 8. an arc-shaped slot; 9. a first conveying groove; 10. a slide bar; 11. a second belt pulley; 12. an elongated frame; 13. a cylinder; 14. placing the first groove; 15. a second conveying groove; 16. a first support rod; 17. a fifth belt pulley; 18. a first bevel gear; 19. a first threaded rod; 20. a second bevel gear; 21. a slider; 22. a second motor; 23. a second threaded rod; 24. a third motor; 25. a first sliding chute; 26. moving a second plate; 27. a second cavity; 28. a telescopic rod; 29. a T-shaped limiting groove; 30. a limiting rod; 31. a third belt pulley; 32. a second supporting rod; 33. a belt pulley IV; 34. a second belt; 35. a second chute; 36. a slider; 37. a laser transmitter; 38. a laser receiver; 39. a control panel; 40. a first protective shell; 41. and a second protective shell.

Detailed Description

The following is only the preferred embodiment of the present invention, the protection scope is not limited to this embodiment, and all technical solutions belonging to the idea of the present invention should belong to the protection scope of the present invention. It should also be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and such modifications and decorations should also be regarded as the protection scope of the present invention.

Referring to fig. 1 to 4, an illumination intensity detection device for a greenhouse comprises a greenhouse main body 1, an illumination intensity tester 2 placed in the greenhouse main body 1 and used for detecting illumination intensity, and a displacement device 3 arranged in the greenhouse main body 1 and used for moving the illumination intensity tester 2, wherein a first movable plate 4 is arranged on the displacement device 3, the first movable plate 4 is in sliding fit with the inner wall of the greenhouse main body 1, the displacement device 3 comprises a second motor 22, a second threaded rod 23 and a third motor 24, a first sliding groove 25 is formed in the ground in the greenhouse main body 1, the second motor 22 is fixed in the first sliding groove 25, the second threaded rod 23 is fixedly connected with an output shaft of the second motor 22, a second movable plate 26 in sliding fit with the side wall of the first sliding groove 25 is arranged in the first sliding groove 25, the second movable plate 26 is in threaded fit with the second threaded rod 23, and when the illumination intensity tester 2 is driven to move along the direction of the first sliding groove 25, pressing the control panel 39 to start the second motor 22, rotating an output shaft of the second motor 22 to drive the second threaded rod 23 to rotate, rotating the second threaded rod 23 to drive the second moving plate 26 to move, moving the second moving plate 26 to drive the first moving plate 4 to move, moving the first moving plate 4 to drive the illumination intensity tester 2 to move along the first sliding groove 25, forming a second cavity 27 on the second moving plate 26, fixing the third motor 24 in the greenhouse main body 1, fixing a telescopic rod 28 on an output shaft of the third motor 24, forming a T-shaped limiting groove 29 on the side wall of the second cavity 27, placing a limiting rod 30 in the T-shaped limiting groove 29, fixedly connecting one end of the telescopic rod 28, far away from the third motor 24, with the limiting rod 30, fixing a third belt pulley 31 on the telescopic rod 28, starting the third motor 24 when driving the illumination intensity tester 2 to move in the vertical direction, rotating an output shaft of the third motor 24, a second support rod 32 is fixed in the second cavity 27, a fourth belt pulley 33 is fixed on the second support rod 32, a second belt 34 is arranged between the third belt pulley 31 and the fourth belt pulley 33, the third belt pulley 31 and the fourth belt pulley 33 are connected through the second belt 34, a second sliding groove 35 is formed in the side wall of the second cavity 27, a sliding block 36 in sliding fit with the second sliding groove 35 is arranged in the second sliding groove 35, one end of the sliding block 36 is fixedly connected with the second belt 34, the other end of the sliding block 36 is fixed with a first moving plate 4, the third belt pulley 31 rotates to drive the second belt 34 to transmit, the second belt 34 transmits to drive the sliding block 36 to move, the sliding block 36 moves to drive the first moving plate 4 to move, and the first moving plate 4 moves.

As shown in fig. 4, when the first moving plate 4 moves up and down, the first moving plate may move too low to touch plants in the greenhouse and limit the plants, a row of laser emitters 37 is fixed on the inner wall of the greenhouse main body 1, a row of laser receivers 38 is fixed on one side of the first moving plate 4 close to the laser emitters 37, the laser emitters 37 are matched with the laser receivers 38, the laser receivers 38 are electrically connected with the third motor 24, the laser receivers 38 move along with the first moving plate 4, when the laser receivers 38 receive laser light emitted by the laser emitters 37, it is indicated that the first moving plate 4 moves too low, the laser receivers 38 send signals to the third motor 24, and the third motor 24 is turned off, so that the first moving plate 4 is prevented from moving too low downward.

As shown in fig. 2 and 3, when the illumination intensity tester 2 is to be driven to move along the first moving plate 4, a first cavity 5 is formed on the side wall of the greenhouse main body 1, a first motor 6 is fixed in the first cavity 5, a first belt pulley 7 is fixed on an output shaft of the first motor 6, an arc-shaped groove 8 is formed on the bottom wall of the first cavity 5, a first transmission groove 9 is formed on the side wall of the first cavity 5, a slide bar 10 in sliding fit with the arc-shaped groove 8 is arranged in the arc-shaped groove 8, a second belt pulley 11 in rotating fit with the slide bar 10 is sleeved outside the slide bar 10, the first belt pulley 7 and the second belt pulley 11 are connected through the first belt, a long frame 12 is sleeved outside the slide bar 10, a cylinder 13 is fixed in the first cavity 5, a piston rod of the cylinder 13 is fixedly connected with the long frame 12, the cylinder 13 is started by pressing down the control panel 39, the piston rod of the cylinder 13 extends, the sliding rod 10 moves to drive the belt pulley II 11 to move until the belt pulley II 11 and the belt pulley I7 are in the same straight line, the first moving plate 4 is provided with a first placing groove 14, one side of the first placing groove 14 is provided with a second conveying groove 15, the first placing groove 14 is internally provided with a first supporting rod 16 which is in rotating fit with the side wall of the first placing groove 14, the first supporting rod 16 is fixedly provided with a fifth belt pulley 17 and a first bevel gear 18, the first motor 6 is started by pressing the control panel 39, the output shaft of the first motor 6 rotates to drive the, the belt pulley five 17 rotates to drive the supporting rod one 16 to rotate, the supporting rod one 16 rotates to drive the bevel gear one 18 to rotate, a threaded rod one 19 in threaded fit with the placing groove one 14 is arranged in the placing groove one 14, a bevel gear two 20 meshed with the bevel gear one 18 is fixed on the threaded rod one 19, the bevel gear one 18 rotates to drive the bevel gear two 20 to rotate, the bevel gear two 20 rotates to drive the threaded rod one 19 to rotate, a sliding block 21 in sliding fit with the placing groove one 14 is placed in the placing groove one 14, the sliding block 21 is in threaded fit with the threaded rod one 19, the illumination intensity tester 2 is fixed on the sliding block 21, the threaded rod one 19 rotates to drive the sliding block 21 to move, the sliding block 21 moves to drive the illumination intensity tester 2 to move along the moving plate one 4, and the effect that the illumination.

As shown in fig. 1, a first protective shell 40 is sleeved outside the second motor 22 and the third motor 24, the first protective shell 40 is fixed with the ground in the greenhouse main body 1, and the first protective shell 40 plays a role in protecting the second motor 22 and the third motor 24.

As shown in FIG. 2, the cylinder 13 is sleeved with a second protective shell 41 fixedly connected with the inner wall of the first cavity 5, and the second protective shell 41 plays a role in protecting the cylinder 13.

Claims

1. A lighting intensity detection device for a greenhouse comprises a greenhouse main body (1) and a lighting intensity tester (2) which is arranged in the greenhouse main body (1) and used for detecting lighting intensity, and is characterized by further comprising a displacement device (3) which is arranged in the greenhouse main body (1) and used for moving the lighting intensity tester (2), wherein a first movable plate (4) is arranged on the displacement device (3), the first movable plate (4) is in sliding fit with the inner wall of the greenhouse main body (1), a first cavity (5) is formed in the side wall of the greenhouse main body (1), a first motor (6) is fixed in the first cavity (5), a first belt pulley (7) is fixed on an output shaft of the first motor (6), an arc-shaped groove (8) is formed in the bottom wall of the first cavity (5), a first conveying groove (9) is formed in the side wall of the first cavity (5), a sliding rod (10) which is in sliding fit with the arc-shaped groove (8) is arranged in the arc-shaped, the novel gear transmission mechanism is characterized in that a second belt pulley (11) in running fit with the sliding rod (10) is sleeved outside the sliding rod (10), the first belt pulley (7) is connected with the second belt pulley (11) through a first belt, a long frame (12) is sleeved outside the sliding rod (10), an air cylinder (13) is fixed in the cavity I (5), a piston rod of the air cylinder (13) is fixedly connected with the long frame (12), a first moving plate (4) is provided with a first placing groove (14), one side of the first placing groove (14) is provided with a second conveying groove (15), a first support rod (16) in running fit with the side wall of the first placing groove (14) is arranged in the first placing groove (14), a fifth belt pulley (17) and a first bevel gear (18) are fixed on the first support rod (16), a first threaded rod (19) in running fit with the first placing groove (14) is arranged in the first placing groove (14), and a second bevel gear (20) meshed with the first bevel gear (18) is fixed on the, a sliding block (21) in sliding fit with the first placing groove (14) is placed in the first placing groove (14), the sliding block (21) is in threaded fit with the first threaded rod (19), and the illumination intensity tester (2) is fixed on the sliding block (21).

2. The illumination intensity detection device for the greenhouse as claimed in claim 1, wherein the displacement device (3) comprises a second motor (22), a second threaded rod (23) and a third motor (24), a first sliding groove (25) is formed in the ground in the greenhouse main body (1), the second motor (22) is fixed in the first sliding groove (25), the second threaded rod (23) is fixedly connected with an output shaft of the second motor (22), a second moving plate (26) in sliding fit with the side wall of the first sliding groove (25) is arranged in the first sliding groove (25), the second moving plate (26) is in threaded fit with the second threaded rod (23), a second cavity (27) is formed in the second moving plate (26), the third motor (24) is fixed in the greenhouse main body (1), a telescopic rod (28) is fixed on the output shaft of the third motor (24), and a T-shaped limit groove (29) is formed in the side wall of the second cavity (27), a limiting rod (30) is placed in the T-shaped limiting groove (29), one end of the telescopic rod (28) far away from the motor III (24) is fixedly connected with the limiting rod (30), a belt pulley III (31) is fixed on the telescopic rod (28), a supporting rod II (32) is fixed in the cavity II (27), a belt pulley four (33) is fixed on the support rod two (32), a belt two (34) is arranged between the belt pulley three (31) and the belt pulley four (33), the third belt pulley (31) is connected with the fourth belt pulley (33) through a second belt (34), a second sliding groove (35) is formed in the side wall of the second cavity (27), a sliding block (36) in sliding fit with the second sliding groove (35) is arranged in the second sliding groove (35), one end of the sliding block (36) is fixedly connected with the second belt (34), and the other end of the sliding block (36) is fixed with the first moving plate (4).

3. The illumination intensity detection device for the greenhouse as claimed in claim 1, wherein a row of laser emitters (37) is fixed on the inner wall of the greenhouse main body (1), a row of laser receivers (38) is fixed on one side of the first moving plate (4) close to the laser emitters (37), the laser emitters (37) are matched with the laser receivers (38), and the laser receivers (38) are electrically connected with the motor III (24).

4. The illumination intensity detection device for the greenhouse as claimed in claim 1, wherein a control panel (39) is fixed in the greenhouse main body (1).

5. The illumination intensity detection device for the greenhouse as claimed in claim 2, wherein a first protection shell (40) is sleeved outside the second motor (22) and the third motor (24), and the first protection shell (40) is fixed with the ground in the greenhouse main body (1).

6. The illumination intensity detection device for the greenhouse as claimed in claim 1, wherein a second protection shell (41) fixedly connected with the inner wall of the first cavity (5) is sleeved outside the cylinder (13).