CN218219862U - Intelligent energy-saving control system for daylighting roof - Google Patents

Abstract

The utility model discloses a daylighting top intelligence energy-saving control system relates to daylighting top energy-saving control technical field, and its technical scheme main points are: comprises a sunshade curtain lifting rod, a transverse plate, a first upright post and a second upright post which are oppositely arranged. The top of the transverse plate is provided with a motor and a storage battery, threaded columns are arranged in the rotating grooves of the first upright column and the second upright column, and the top of each threaded column is provided with a second gear; the motor rotates to enable the first gear and the third gear to rotate through the rotating shaft to drive the second gear which is meshed with the first gear to rotate, and the second gear rotates to enable the threaded column to rotate. The threaded column rotates to enable the sunshade curtain lifting rod to move in the vertical direction, and the sunshade curtain lifting rod is provided with a sunshade curtain for shading light. The control panel and temperature sensor, light sensor electric connection enable to carry out automatically regulated according to indoor temperature and light intensity control motor work. Solar energy is converted into electric energy to be stored in the storage battery through the solar panel, the motor is powered to drive the sunshade curtain lifting rod to move up and down, and the sunshade curtain lifting device is green, saves resources and is convenient to use.

Description

Intelligent energy-saving control system for daylighting roof

Technical Field

The utility model relates to a daylighting top energy-saving control technical field, more specifically say, it relates to a daylighting top intelligence energy-saving control system.

Background

Present architectural design tends to diversified, pursues penetrating, bright house environment in-process at people, and the window is done bigger and bigger, and multiaspect wall body, roof are also adopting non-light tight materials such as glass, and the problem of bringing is that noon time minute high temperature has increased the operating pressure of equipment such as air conditioner, and this problem has provided higher requirement to the design of sunshade screen, and massive sunshade screen if manual pulling wastes time and energy.

Therefore, in the daylighting roof, the sunshade curtain is pulled by adopting an electric mode mostly, and the sunshade curtain is pulled under the action of electric energy. Thermal power plants generate electricity through thermal power, so that the environment is polluted, and resources are reduced due to the combustion of coal. Therefore, the electric energy generated by the thermal power plant is used for pulling the sunshade curtain, the electric energy is consumed, and the existing sunshade curtain is inconvenient to use.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a daylighting top intelligence energy-saving control system turns into solar energy through solar panel and stores in the battery, drives the sunshade screen lifter to the motor power supply and reciprocates, green, resources are saved.

The above technical purpose of the present invention can be achieved by the following technical solutions: an intelligent energy-saving control system for a daylighting roof comprises a sunshade curtain lifting rod, a transverse plate, a first upright post and a second upright post, wherein the first upright post and the second upright post are arranged oppositely; the two opposite surfaces of the first upright post and the second upright post are respectively provided with a rotating groove, and the bottoms of the first upright post and the second upright post are respectively provided with a base; threaded columns are arranged in the rotating grooves of the first upright column and the second upright column, the bottoms of the threaded columns are rotatably connected with the base, and the tops of 2 threaded columns penetrate through the top and the bottom of the transverse plate and are provided with second gears; two ends of the sunshade curtain lifting rod are provided with through holes, the sunshade curtain lifting rod is sleeved on the oppositely arranged threaded columns through the through holes, and the sunshade curtain lifting rod is in threaded connection with the threaded columns; vertical plates are arranged on two opposite sides of the top of the transverse plate, and a supporting plate and a partition plate are arranged on the top of the transverse plate in parallel to the vertical plates; the top parts of the partition plate, the support plate and the oppositely arranged vertical plate are connected with a solar panel; the top of the transverse plate is also provided with a motor and a storage battery; the motor is arranged between the vertical plate and the partition plate, and the storage battery is arranged between the vertical plate and the support plate; a rotating seat is arranged on one side surface of the support plate, which is far away from the storage battery, a rotating shaft is arranged at the output end of the motor, and one end of the rotating shaft, which is far away from the motor, is rotationally connected with the rotating seat; a first gear and a third gear are arranged on the rotating shaft, the first gear is meshed with a second gear close to the storage battery, and the third gear is meshed with a second gear close to the motor; the bottom of the transverse plate is provided with a control box, and a control plate is arranged in the control box; the control panel is electrically connected with the motor; the top of the transverse plate is provided with a baffle close to the back and the front.

The utility model discloses further set up to: the relative setting the surface of stand one and stand two is equipped with temperature sensor and light sensor respectively, control panel and temperature sensor, light sensor electric connection.

Through adopting above-mentioned technical scheme, the base is established with the bottom of stand two to the top of stand one and stand two that place relatively and the bottom fixed connection of diaphragm, and the rotation groove is all established with the opposite face of stand two to stand one, rotates the inslot and establishes the screw thread post, and the bottom and the base of screw thread post rotate to be connected, and the diaphragm is run through and establishes fixed gear two at the top of screw thread post. The top of diaphragm is on a parallel with the riser and establishes extension board and baffle, and the top of diaphragm is close to the back and all is equipped with the baffle with the front, and the top of baffle, extension board and the relative riser that sets up is connected jointly and is equipped with solar panel. A motor is arranged between the vertical plate and the partition plate, a storage battery is arranged between the vertical plate and the support plate, and the solar panel stores the converted electric energy in the storage battery. The output end of the motor is provided with a rotating shaft, and one end of the rotating shaft, which is far away from the motor, is rotatably connected with the rotating seat. A first gear and a third gear are arranged on the rotating shaft, and the first gear and the third gear are respectively meshed with a second gear at the top end of the 2 threaded columns. The motor rotates to enable the first gear and the third gear to rotate through the rotating shaft to drive the second gear which is meshed with the first gear to rotate, and the second gear rotates to enable the threaded column to rotate. The both ends of sunshade screen lifter pass through the perforation cover on 2 screw thread posts and with screw thread post threaded connection. The threaded column rotates to enable the sunshade curtain lifting rod to move in the vertical direction, and the sunshade curtain is arranged on the sunshade curtain lifting rod. The control panel can control the work of motor. The surfaces of the first stand column and the second stand column are respectively provided with a temperature sensor and a light sensor, and the control panel is electrically connected with the temperature sensor and the light sensor. The temperature and the light intensity in the room can be automatically adjusted.

To sum up, the utility model discloses following beneficial effect has: solar energy is converted into electric energy through the solar panel and is stored in the storage battery, the motor is powered to drive the sunshade curtain lifting rod to move up and down, and the solar sunshade curtain lifting device is green, saves resources and is convenient to use.

Drawings

FIG. 1 is a schematic front view of an embodiment of the present invention;

fig. 2 is a schematic view of a front sectional structure of the embodiment of the present invention.

In the figure: 1. a first upright post; 2. a second upright post; 3. a base; 4. a sunshade curtain lifter; 5. a light sensor; 6. a temperature sensor; 7. a control box; 8. a transverse plate; 9. a vertical plate; 10. a baffle plate; 11. a solar panel; 12. a sun screen; 13. a rotating groove; 14. a threaded post; 15. a control panel; 16. a storage battery; 17. a support plate; 18. a rotating seat; 19. a first gear; 20. a second gear; 21. a rotating shaft; 22. a motor; 23. a third gear; 24. a separator.

Detailed Description

The present invention will be described in further detail with reference to the accompanying fig. 1-2.

Example (b): an intelligent energy-saving control system for a daylighting roof is shown in figures 1-2 and comprises a sunshade curtain 12, a lifting rod 4, a transverse plate 8, a first upright post 1 and a second upright post 2 which are arranged oppositely, wherein the tops of the first upright post 1 and the second upright post 2 are connected with the bottom of the transverse plate 8; the opposite surfaces of the first upright post 1 and the second upright post 2 are respectively provided with a rotating groove 13, and the bottoms of the first upright post 1 and the second upright post 2 are respectively provided with a base 3; threaded columns 14 are arranged in the rotating grooves 13 of the first upright post 1 and the second upright post 2, the bottoms of the threaded columns 14 are rotatably connected with the base 3, and the tops of the 2 threaded columns 14 penetrate through the top and the bottom of the transverse plate 8 and are provided with second gears 20; two ends of the sunshade curtain 12 lifting rod 4 are provided with through holes, the sunshade curtain 12 lifting rod 4 is sleeved on the oppositely arranged threaded columns 14 through the through holes, and the sunshade curtain 12 lifting rod 4 is in threaded connection with the threaded columns 14; vertical plates 9 are arranged on two opposite sides of the top of the transverse plate 8, and a support plate 17 and a partition plate 24 are arranged on the top of the transverse plate 8 in parallel to the vertical plates 9; the solar panel 11 is connected with the top of the partition plate 24, the support plate 17 and the oppositely arranged vertical plate 9; the top of the transverse plate 8 is also provided with a motor 22 and a storage battery 16; the motor 22 is arranged between the vertical plate 9 and the partition plate 24, and the storage battery 16 is arranged between the vertical plate 9 and the support plate 17; a rotating seat 18 is arranged on one side surface of the support plate 17 departing from the storage battery 16, a rotating shaft 21 is arranged at the output end of the motor 22, and one end of the rotating shaft 21 far away from the motor 22 is rotatably connected with the rotating seat 18; a first gear 19 and a third gear 23 are arranged on the rotating shaft 21, the first gear 19 is meshed with a second gear 20 close to the storage battery 16, and the third gear 23 is meshed with a second gear 20 close to the motor 22; the bottom of the transverse plate 8 is provided with a control box 7, and a control plate 15 is arranged in the control box 7; the surfaces of the first upright post 1 and the second upright post 2 which are oppositely arranged are respectively provided with a temperature sensor 6 and a light sensor 5, and the control board 15 is electrically connected with the temperature sensor 6, the light sensor 5 and the motor 22; baffle plates 10 are arranged on the top, close to the back and the front, of the transverse plate 8.

Through this embodiment, the relative top of stand 1 and stand two 2 of placing and the bottom fixed connection of diaphragm 8, base 3 is established with stand two 2's bottom to stand 1, and rotating groove 13 is all established with stand two 2's opposite face to stand 1, establishes screw thread post 14 in the rotating groove 13, and the bottom and the base 3 of screw thread post 14 rotate to be connected, and diaphragm 8 is run through and fixed two 20 gears are established at the top of screw thread post 14, and screw thread post 14 rotates in the department of running through with diaphragm 8 and is connected. The top of diaphragm 8 is on a parallel with riser 9 and establishes extension board 17 and baffle 24, and the top of diaphragm 8 is close to the back and all is equipped with baffle 10 with the front, and baffle 10, baffle 24, extension board 17 and the relative riser 9's that sets up top are connected jointly and are equipped with solar panel 11. The motor 22 is arranged between the vertical plate 9 and the partition plate 24, the storage battery 16 is arranged between the vertical plate 9 and the support plate 17, and the solar panel 11 stores the converted electric energy in the storage battery 16. The output end of the motor 22 is provided with a rotating shaft 21, and one end of the rotating shaft 21 far away from the motor 22 is rotatably connected with the rotating seat 18. The rotating shaft 21 is provided with a first gear 19 and a third gear 23, and the first gear 19 and the third gear 23 are respectively meshed with a second gear 20 at the top end of the 2 threaded columns 14. The motor 22 rotates to drive the first gear 19 and the third gear 23 to rotate through the rotating shaft 21, so that the second gear 20 which is meshed with the first gear rotates, and the second gear 20 rotates to drive the threaded column 14 to rotate. Two ends of the sunshade curtain 12 lifting rod 4 are sleeved on the 2 threaded columns 14 through the through holes and are in threaded connection with the threaded columns 14. The threaded column 14 rotates to enable the sunshade curtain 12 lifting rod 4 to move in the vertical direction, and the sunshade curtain 12 is arranged on the sunshade curtain 12 lifting rod 4. The control board 15 can control the operation of the motor 22. The surfaces of the first upright post 1 and the second upright post 2 are respectively provided with a temperature sensor 6 and a light sensor 5, and the control panel 15 is electrically connected with the temperature sensor 6 and the light sensor 5. The temperature and the light intensity in the room can be automatically adjusted. Solar energy is converted into electric energy through the solar panel 11 and stored in the storage battery 16, the motor 22 is powered to drive the lifting rod 4 of the sun-shading curtain 12 to move up and down, and the solar energy sun-shading curtain is green, environment-friendly, resource-saving and convenient to use.

The working principle is as follows: the motor 22 rotates to enable the first gear 19 and the third gear 23 to rotate through the rotating shaft 21, the second gear 20 which is meshed with the first gear is driven to rotate, and the second gear 20 rotates to enable the threaded column 14 to rotate. The threaded column 14 rotates to enable the sunshade 12 lifting rod 4 to move in the vertical direction, and the sunshade 12 is arranged on the sunshade 12 lifting rod 4 to shield illumination. The control board 15 is electrically connected with the temperature sensor 6 and the light sensor 5, so that the motor 22 can be controlled to work according to the indoor temperature and the light intensity to carry out automatic adjustment.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (2)

1. An intelligent energy-saving control system for a daylighting roof is characterized in that: the sunshade curtain comprises a sunshade curtain (12), a lifting rod (4), a transverse plate (8) and a first upright post (1) and a second upright post (2) which are arranged oppositely, wherein the tops of the first upright post (1) and the second upright post (2) are connected with the bottom of the transverse plate (8); the opposite surfaces of the first upright post (1) and the second upright post (2) are respectively provided with a rotating groove (13), and the bottoms of the first upright post (1) and the second upright post (2) are respectively provided with a base (3); threaded columns (14) are arranged in the rotating grooves (13) of the first upright post (1) and the second upright post (2), the bottoms of the threaded columns (14) are rotatably connected with the base (3), and the tops of the 2 threaded columns (14) penetrate through the top and the bottom of the transverse plate (8) and are provided with a second gear (20); through holes are formed in two ends of the lifting rod (4) of the sunshade screen (12), the lifting rod (4) of the sunshade screen (12) is sleeved on the threaded columns (14) which are arranged oppositely through the through holes, and the lifting rod (4) of the sunshade screen (12) is in threaded connection with the threaded columns (14); vertical plates (9) are arranged on two opposite sides of the top of the transverse plate (8), and a support plate (17) and a partition plate (24) are arranged on the top of the transverse plate (8) in parallel to the vertical plates (9); the top parts of the partition plate (24), the support plate (17) and the oppositely arranged vertical plate (9) are connected with a solar panel (11) together; the top of the transverse plate (8) is also provided with a motor (22) and a storage battery (16); the motor (22) is arranged between the vertical plate (9) and the partition plate (24), and the storage battery (16) is arranged between the vertical plate (9) and the support plate (17); a rotating seat (18) is arranged on one side surface of the support plate (17) departing from the storage battery (16), a rotating shaft (21) is arranged at the output end of the motor (22), and one end, far away from the motor (22), of the rotating shaft (21) is rotatably connected with the rotating seat (18); a first gear (19) and a third gear (23) are arranged on the rotating shaft (21), the first gear (19) is meshed with a second gear (20) close to the storage battery (16), and the third gear (23) is meshed with the second gear (20) close to the motor (22); a control box (7) is arranged at the bottom of the transverse plate (8), and a control plate (15) is arranged in the control box (7); the control board (15) is electrically connected with the motor (22); the top of the transverse plate (8) is close to the back and the front is provided with a baffle (10).

2. The intelligent energy-saving control system for the daylighting roof of claim 1, which is characterized in that: the relative setting the surface of stand one (1) and stand two (2) is equipped with temperature sensor (6) and light sensor (5) respectively, control panel (15) and temperature sensor (6), light sensor (5) electric connection.

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