CN220978596U - Lighting, ventilating, sun-shading and energy-saving device applied to intelligent skylight - Google Patents

Abstract

The utility model discloses a lighting, ventilating and sun-shading energy-saving device applied to an intelligent skylight, which relates to the technical field of intelligent equipment and comprises a device main body, wherein the device main body comprises a processor, a photovoltaic panel, a lighting shade and a water blocking eave, the processor is arranged on one side of the device main body, a humidity sensor and a signal receiver are arranged on one side of the processor, the driving motor is driven to rotate through the rotation of a driving motor, so that the driving motor can drive a worm to rotate, further, a worm wheel can drive the photovoltaic panel to rotate, the photovoltaic panels can enable gaps between the photovoltaic panels to be closed through rotation, further, a lighting channel in the device main body can be closed through the photovoltaic panel, thereby playing a role of sun-shading, and the device can collect solar energy while sun-shading, so that the solar energy is converted into electric energy to be stored in a storage battery for maintaining the normal operation of the skylight, thereby being favorable for reducing the power supply to the device indoors and playing an energy-saving effect.

Description

Lighting, ventilating, sun-shading and energy-saving device applied to intelligent skylight

Technical Field

The utility model relates to the technical field of intelligent equipment, in particular to a lighting, ventilating, sun-shading and energy-saving device applied to an intelligent skylight.

Background

The skylight is arranged at the top of a building generally and used for lighting and ventilation, the skylight is more and more intelligent along with scientific development, automatic switching can be performed according to an external temperature sensor, through retrieval, the patent with Chinese patent grant number CN111945964B discloses an intelligent skylight based on the industrial Internet of things, although the intelligent skylight based on the industrial Internet of things can be opened to the skylight through the Internet of things, the opening direction of the skylight can be selected according to the outdoor wind direction, so that the outdoor wind can be blown into a workshop better, the cooling effect on the workshop temperature is improved, but the effect of sunshade cannot be performed when the sunlight illumination is strong, and then indoor heating is easy to be caused, meanwhile, the device needs to be connected with an indoor power supply, more electric energy is required to be consumed for maintaining the operation of the skylight, and meanwhile, the skylight lighting effect is poor when the sun is in the morning and the afternoon illumination angle is low.

Disclosure of utility model

Aiming at the defects of the prior art, the utility model provides the lighting, ventilation and sun-shading energy-saving device applied to the intelligent skylight, which solves the problems that the existing skylight cannot play a role in sun-shading when the sun illumination is strong, so that the indoor temperature rise is easy to cause, the device needs to be communicated with an indoor power supply, more electric energy is required to be consumed for maintaining the operation of the skylight, and the lighting effect of the skylight is poor when the sun illumination angle is low in the morning and afternoon.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: be applied to intelligent skylight daylighting ventilation sunshade economizer, including the device main part, the device main part includes treater, photovoltaic board, ring light and manger plate eaves, device main part one side treater, thereby humidity transducer and signal receiver are installed to treater one side, thereby make driving motor carry out remote switch through signal receiver, the battery is installed to treater one side, and treater and battery all are equipped with waterproof case, device main part internally mounted has the photovoltaic board, and photovoltaic board one end and the inboard rotation of device main part are connected, the outside cover of photovoltaic board other end is equipped with the worm wheel, the worm wheel is connected with the worm meshing, and worm one end cover is outside in driving motor output, and driving motor and treater electric connection, device main part top is equipped with the ring light.

Preferably, the light collecting cover is transparent glass, and the top of the light collecting cover is conical, and four sides of the light collecting cover are of slope-shaped structures, so that light can be refracted into a room through the light collecting cover when the illumination angle is low, lighting is further provided for the room, indoor lighting power consumption is reduced, and energy is saved.

Preferably, the photovoltaic board is equidistant form setting each other, and the section of photovoltaic board both ends is parallelogram shape, aluminum foil membrane is pasted on photovoltaic board bottom surface, is domatic form through photovoltaic board both ends and is favorable to making the photovoltaic board rotate and can avoid the gap light leak between each other of photovoltaic board when sunshade each other.

Preferably, the four-end top of device main part bottom inlays and is equipped with electric telescopic handle, electric telescopic handle top flexible end is connected with the light collecting cover, through humidity transducer monitoring air humidity, and the device can descend the light collecting cover through electric telescopic handle when rainy season and close, and then prevents that the rainwater from getting into indoor, can drive the light collecting cover through electric telescopic handle when fine day and rise, and outside air current passes through the clearance entering inside between light collecting cover bottom and the device main part, and then through the photovoltaic board water conservancy diversion of opening into indoor.

Preferably, the outside glue joint of daylighting cover bottom has the manger plate eaves, and the manger plate eaves is transparent glass material, and manger plate eaves top is domatic form to be favorable to avoiding the rainwater to infiltrate indoor from the clearance between daylighting cover and the device main part.

The utility model provides a lighting, ventilating, sun-shading and energy-saving device applied to an intelligent skylight. The beneficial effects are as follows:

(1) This be applied to intelligent skylight daylighting ventilation sunshade economizer, when solar light is stronger, through driving motor's rotation, thereby make driving motor can drive the worm and rotate, worm rotates and can drive a plurality of worm wheels and rotate, and then make the worm wheel can drive the photovoltaic board and rotate, the photovoltaic board makes the clearance between each other can be closed through rotating, and then make the inside daylighting passageway of device main part can close through the photovoltaic board, thereby play the effect of sunshade, and the device can collect solar energy when carrying out the sunshade, thereby convert solar energy into electric energy storage to the battery, be used for maintaining this skylight normal operating, thereby be favorable to reducing indoor power supply to the device, play energy-conserving effect.

(2) This be applied to intelligent skylight daylighting ventilation sunshade economizer, when this skylight daylighting effect was relatively poor when the sun was earlier and the afternoon irradiation angle was lower, when solar ray can not penetrate into indoor through the skylight, solar ray can shine the skylight top domatic, and then the light is favorable to the lower light of illumination angle to light can equally be lighted and shine into indoor through the top domatic refraction, makes the photovoltaic board collect solar energy that solar panel can be better in the morning and afternoon through the cooperation photovoltaic board simultaneously.

Therefore, the problem that the existing skylight cannot play a role in shading when sunlight is strong, and then indoor heating is easy to occur, meanwhile, the device needs to be connected with an indoor power supply, more electric energy is needed to be consumed for maintaining the operation of the skylight, and meanwhile, the skylight lighting effect is poor when the sunlight is low in the morning and afternoon.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of the worm wheel and worm structure of the present utility model;

FIG. 3 is a schematic side view of the present utility model;

FIG. 4 is a schematic diagram showing the connection of the electric telescopic rod and the lighting shade;

Fig. 5 is a schematic view of a photovoltaic panel structure of the present utility model.

In the figure, 1, a device main body; 2. a processor; 4. a storage battery; 5. a driving motor; 6. a worm; 7. a worm wheel; 8. a photovoltaic panel; 9. an electric telescopic rod; 10. a lighting cover; 11. a water retaining eave; 12. a humidity sensor; 13. a signal receiver.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled 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

Referring to fig. 1-5, the device body 1 comprises a device body 1, the device body 1 comprises a processor 2, a photovoltaic panel 8, a lighting cover 10 and a water blocking eave 11, the processor 2 is arranged on one side of the device body 1, a humidity sensor 12 and a signal receiver 13 are arranged on one side of the processor 2, a driving motor 5 can be remotely switched through the signal receiver 13, a storage battery 4 is arranged on one side of the processor 2, the photovoltaic panel 8 is arranged in the device body 1, one end of the photovoltaic panel 8 is rotationally connected with the inner side of the device body 1, a worm wheel 7 is sleeved outside the other end of the photovoltaic panel 8, the worm wheel 7 is meshed with a worm 6, one end of the worm 6 is sleeved outside the output end of the driving motor 5, the driving motor 5 is electrically connected with the processor 2, the lighting cover 10 is arranged above the device body 1, when sunlight is strong, through the rotation of the driving motor 5, the driving motor 5 can drive the worm 6 to rotate, the worm 6 can drive the worm gears 7 to rotate while rotating, the worm gears 7 can drive the photovoltaic panels 8 to rotate, the photovoltaic panels 8 can close gaps among the photovoltaic panels through rotation, the lighting channel inside the device main body 1 can be closed through the photovoltaic panels 8, thereby playing a sunshade effect, the device can collect solar energy while sunshade, thereby converting the solar energy into electric energy to be stored in the storage battery 4 for maintaining the normal operation of the skylight, thereby being beneficial to reducing the power supply of the device indoors, playing the energy-saving effect, thereby solving the problems that the existing skylight cannot play a sunshade effect when sunlight is strong, and thus easily causing indoor heating, meanwhile, the skylight needs to be connected with an indoor power supply, and more electric energy is consumed for maintaining the skylight to operate.

Example 2

The lighting cover 10 is transparent glass, and the top of the lighting cover 10 is in a cone shape, and four sides of the lighting cover are in slope structures, so that light can be refracted into a room through the lighting cover 10 when the illumination angle is low, lighting is further provided for the room, and indoor lamplight power consumption is reduced, so that energy is saved.

Example 3

The equidistant form setting of being each other of photovoltaic board 8, and the parallelogram shape is personally submitted to photovoltaic board 8 both ends cross-section, and aluminium foil membrane is pasted on photovoltaic board 8 bottom surface, is domatic form through photovoltaic board 8 both ends and is favorable to making photovoltaic board 8 rotate and can avoid the gap light leak between each other of photovoltaic board 8 when sunshade, when being favorable to making photovoltaic board 8 open indoor daylighting through the aluminium foil membrane of photovoltaic board 8 bottom, can reduce photovoltaic board 8 back to the absorption of light through the aluminium foil membrane, improves indoor daylighting effect.

Example 4

The four-end top in device main part 1 bottom inlays and is equipped with electric telescopic handle 9, electric telescopic handle 9 top flexible end is connected with light collecting cover 10, monitor air humidity through humidity transducer 12, light collecting cover 10 bottom outside glue joint has manger plate eaves 11, and manger plate eaves 11 is transparent glass material, manger plate eaves 11 top is domatic form, the device can descend light collecting cover 10 through electric telescopic handle 9 when rainy season and close, and then prevent that the rainwater from getting into the room, thereby be favorable to avoiding the rainwater to permeate into indoor from the clearance between light collecting cover 10 and the device main part 1 through manger plate eaves 11, can drive light collecting cover 10 through electric telescopic handle 9 when fine day and rise, outside air current gets into inside through the clearance between light collecting cover 10 bottom and the device main part 1, and then flow into indoor through the photovoltaic board 8 water conservancy diversion of opening, thereby ventilate.

Working principle: when the sun light is strong, the driving motor 5 can drive the worm 6 to rotate through the rotation of the driving motor 5, the worm 6 can drive the worm gears 7 to rotate while rotating, the worm gears 7 can drive the photovoltaic panels 8 to rotate, the photovoltaic panels 8 can close gaps between the photovoltaic panels through rotation, the lighting channels inside the device main body 1 can be closed through the photovoltaic panels 8, so that the sun shading effect is achieved, the device can collect solar energy while sun shading, so that the solar energy is converted into electric energy to be stored in the storage battery 4 for maintaining the normal operation of the sun light, thereby being beneficial to reducing the power supply of the device indoors, playing the energy-saving effect, further solving the problem that the existing sun light can not play the role of sun shading when the sun light is strong, and then arouse indoor intensification easily, need switch on with indoor power simultaneously, maintain the operation of this skylight and need consume the problem of more electric energy, monitor air humidity through humidity transducer 12, the light cover 10 bottom outside has glued manger plate eaves 11, and manger plate eaves 11 is transparent glass material, manger plate eaves 11 top is domatic form, the device can descend light cover 10 through electric telescopic handle 9 when rainy season and close, and then prevent that the rainwater from getting into indoor, thereby be favorable to avoiding the rainwater to permeate into indoor from the clearance between light cover 10 and the device main part 1 through manger plate eaves 11, can drive light cover 10 through electric telescopic handle 9 when sunny day and rise, outside air current gets into inside through the clearance between light cover 10 bottom and the device main part 1, and then flow guide into indoor through the photovoltaic board 8 of opening, thereby ventilate.

The utility model relates to a device main body 1; 2. a processor; 4. a storage battery; 5. a driving motor; 6. a worm; 7. a worm wheel; 8. a photovoltaic panel; 9. an electric telescopic rod; 10. a lighting cover; 11. a water retaining eave; 12. a humidity sensor; 13. the signal receiver is a common standard component or a component known to a person skilled in the art, and the structure and the principle of the signal receiver are known to the person skilled in the art through technical manuals or through routine experimental methods.

While the fundamental and principal features of the utility model and advantages of the utility model have been shown and described, it will be apparent to those skilled in the art that the utility model is not limited to the details of the foregoing exemplary embodiments, but may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (5)

1. Be applied to intelligent skylight daylighting ventilation sunshade economizer, including device main part (1), its characterized in that: the device comprises a device body (1), wherein the device body (1) comprises a processor (2), a photovoltaic panel (8), a lighting cover (10) and a water retaining eave (11), the processor (2) is installed on one side of the device body (1), a humidity sensor (12) and a signal receiver (13) are installed on one side of the processor (2), a storage battery (4) is installed on one side of the processor (2), the photovoltaic panel (8) is installed in the device body (1), one end of the photovoltaic panel (8) is rotationally connected with the inner side of the device body (1), a worm wheel (7) is sleeved outside the other end of the photovoltaic panel (8), the worm wheel (7) is meshed with a worm (6), one end of the worm (6) is sleeved outside the output end of a driving motor (5), the driving motor (5) is electrically connected with the processor (2), and the lighting cover (10) is arranged above the device body (1).

2. The lighting, ventilating and sun-shading energy-saving device applied to the intelligent skylight as claimed in claim 1, wherein: the daylighting cover (10) is transparent glass, and the top of the daylighting cover (10) is cone-shaped, and four sides are slope-shaped structures.

3. The lighting, ventilating and sun-shading energy-saving device applied to the intelligent skylight as claimed in claim 1, wherein: the photovoltaic panels (8) are arranged at equal intervals, the sections at the two ends of the photovoltaic panels (8) are in a parallelogram shape, and aluminum foil films are adhered to the bottom surfaces of the photovoltaic panels (8).

4. The lighting, ventilating and sun-shading energy-saving device applied to the intelligent skylight as claimed in claim 1, wherein: an electric telescopic rod (9) is embedded at the top of four ends of the bottom of the device main body (1), and the telescopic end at the top of the electric telescopic rod (9) is connected with a lighting cover (10).

5. The lighting, ventilating and sun-shading energy-saving device applied to the intelligent skylight as claimed in claim 1, wherein: the outer side of the bottom of the daylighting shade (10) is glued with a water retaining eave (11), the water retaining eave (11) is made of transparent glass, and the top of the water retaining eave (11) is in a slope shape.