CN213272448U

CN213272448U - Wind energy and light energy complementary energy-saving corridor lighting device

Info

Publication number: CN213272448U
Application number: CN202022665784.3U
Authority: CN
Inventors: 朱海健; 徐晓智; 张洁; 蔡志旭
Original assignee: Nanjing Jinhai Design Engineering Co ltd
Current assignee: Nanjing Jinhai Design Engineering Co ltd
Priority date: 2020-11-17
Filing date: 2020-11-17
Publication date: 2021-05-25
Anticipated expiration: 2030-11-17

Abstract

The utility model discloses a wind energy and light energy complementary energy-saving corridor lighting device, which relates to a corridor lighting device and aims to solve the problems that in the prior art, when sunlight is weak or even disappears, a solar photovoltaic battery component can not continuously generate electric quantity, the power supply of a lighting lamp is reduced, and the brightness of the lighting lamp is weakened or even extinguished; the technical scheme is characterized by comprising an illuminating lamp arranged in a corridor, a storage battery arranged outside the corridor and used for supplying power to the illuminating lamp, and a wind energy conversion piece and a light energy conversion piece which are respectively arranged outside the corridor; when the sunlight passes through the light energy conversion piece, the sunlight is converted into electric energy and supplies power to the storage battery, when the illuminating lamp works, the storage battery supplies power to the illuminating lamp, and wind energy is converted into the electric energy and supplies power to the storage battery through the wind energy conversion assembly, so that the possibility of reducing the electric quantity in the storage battery is reduced when the sunlight is insufficient, and the possibility of weakening or even extinguishing the light of the illuminating lamp is reduced.

Description

Wind energy and light energy complementary energy-saving corridor lighting device

Technical Field

The utility model relates to a corridor lighting device especially relates to a complementary energy-saving corridor lighting device of wind energy light energy.

Background

In commercial or civil high-rise buildings in large and medium cities, illuminating lamps are generally arranged in corridors to facilitate people to walk.

The Chinese patent with the publication number of CN201297552Y discloses a solar corridor lamp, which comprises a lighting lamp and is characterized in that the lighting lamp is connected with a power box, the power box is connected with a solar photovoltaic cell module, a solar special controller and a valve-controlled fully-sealed maintenance-free lead-acid storage battery are arranged in the power box, and the solar special controller is connected with the valve-controlled fully-sealed maintenance-free lead-acid storage battery.

The above prior art solutions have the following drawbacks: above-mentioned light is in the use, needs solar energy to continuously shine solar photovoltaic cell module, thereby solar photovoltaic cell module produces the electric quantity and is the light power supply, but when solar ray is more weak disappears even, the light lasts work, but solar photovoltaic cell module can not continuously produce the electric quantity, and the power supply volume of light reduces, leads to the luminance of light to weaken even extinguish, influences the normal use of light.

SUMMERY OF THE UTILITY MODEL

To the deficiency that prior art exists, the utility model aims at providing a complementary energy-saving corridor lighting device of wind energy light energy, its advantage lies in reducing the possibility that the power supply volume of light weakens to the luminance that reduces the light weakens the possibility of extinguishing even.

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

the energy-saving corridor lighting device with the complementation of wind energy and light energy comprises a lighting lamp arranged in a corridor, a storage battery arranged outside the corridor and used for supplying power to the lighting lamp, a wind energy conversion piece and a light energy conversion piece, wherein the wind energy conversion piece and the light energy conversion piece are respectively arranged outside the corridor and used for converting wind energy into electric energy of the storage battery, the light energy conversion piece is used for converting light energy into the electric energy of the storage battery, and the storage battery is connected with the lighting lamp through a power transmission wire.

Through adopting above-mentioned technical scheme, when solar ray passes through the light energy conversion spare, the light energy conversion spare converts light energy into the electric energy, thereby to the battery power supply, the light is at the during operation, the battery passes through the power transmission line and supplies power to the light, wind energy converts the subassembly into the electric energy through wind energy, to the battery power supply, when light is not enough with this reduction, the light lasts work and consumes the power, lead to the possibility that electric quantity reduces in the battery, thereby reduce the possibility that the light weakens or even extinguishes.

Furthermore, the wind energy conversion part comprises a wind driven generator arranged on the outer top wall of the building, a rotating shaft arranged on the wind driven generator and a plurality of fixing plates arranged on the rotating shaft, the fixing plates are uniformly distributed along the circumferential direction of the rotating shaft, arc-shaped plates are arranged on the side faces of the fixing plates and arranged along the axial direction of the rotating shaft, and a power transmission line connected with a storage battery is arranged on the wind driven generator.

Through adopting above-mentioned technical scheme, when the arc was blown to wind, the arc drove the fixed plate and rotates, and the arc drives the rotation axis and rotates, thereby the rotation axis starts aerogenerator, and the electric energy that aerogenerator produced passes through the transmission line and transmits to the battery to this accomplishes wind energy smoothly and to electric energy conversion and to the battery power supply.

Furthermore, be equipped with fixed cover on aerogenerator's the side, the rotation axis is located in the fixed cover, the internal diameter of fixed cover is greater than the diameter of rotation axis, the fixed plate is located the rotation axis is kept away from aerogenerator's one side, the arc is located outside the fixed cover, the arc is close to aerogenerator's one side with the lateral wall of fixed cover rotates and is connected.

Through adopting above-mentioned technical scheme, the arc is when rotating, and fixed cover restricts the home range of arc to reduce the arc and take place skew possibility at the rotation in-process, thereby improve the installation stability of arc.

Furthermore, one side of the arc plate, which is far away from the fixed sleeve, is provided with a windward plate, and the windward plate extends towards one side which is far away from the fixed sleeve.

By adopting the technical scheme, the windward plate increases the contact area of the arc-shaped plate and the wind, so that the possibility that the arc-shaped plate is driven by the wind power is improved.

Furthermore, a spherical concave surface is arranged on the side surface of the windward plate.

By adopting the technical scheme, the spherical concave surface increases the contact area between the windward plate and wind power, and further improves the possibility that the windward plate is driven by the wind power to rotate.

Furthermore, a plurality of floating balls are arranged on the circumferential wall of the windward plate and are uniformly distributed along the circumferential direction of the windward plate.

By adopting the technical scheme, when the floating ball is blown by wind power, the floating ball pulls the windward plate to rotate, and the rotating force of the windward plate is further improved.

Furthermore, a protection plate is arranged on the outer side wall of the wind driven generator, a protection net cover covers the top wall of the protection plate, and the protection net cover covers the windward plate.

Through adopting above-mentioned technical scheme, the debris in the air are detained to the protection screen panel, and debris are attached to on the windward plate or damage the possibility of floater.

Furthermore, the light energy conversion part comprises a solar cell module arranged on the outer side wall of the building and a conducting wire arranged on the solar cell module, and one end, far away from the solar cell module, of the conducting wire is fixedly connected with the storage battery.

Through adopting above-mentioned technical scheme, when light shines on solar module, solar module turns into the electric energy with solar energy, and the rethread conducting wire carries the electric quantity to the battery to this accomplishes solar energy transformation electric energy smoothly.

Furthermore, a rotating motor is arranged on the outer side wall of the building, a transmission shaft is arranged on a motor shaft of the rotating motor, and the solar cell module is fixedly connected to the end wall of the transmission shaft;

the solar cell module is characterized in that a temperature sensor is arranged in the solar cell module, a control box is arranged on the bottom wall of the solar cell module, and the rotating motor is connected with the temperature sensor and the control box.

Through adopting above-mentioned technical scheme, when the skew takes place for the sun, shine and change at the light intensity on solar module surface, thereby lead to solar module surface temperature to produce local difference, temperature sensor monitors the temperature on solar module surface in real time, when the temperature of solar module one side is on the high side, temperature sensor transmits signal to the control box, thereby the control box transmits signal to the rotation motor start-up rotation motor, the rotation motor drives the transmission shaft and rotates, the transmission shaft drives solar module and rotates, thereby adjustment solar module orientation, be favorable to improving the light intensity who shines solar module surface.

To sum up, the utility model discloses following beneficial effect has:

1. the light energy conversion part converts light energy into electric energy to supply power to the storage battery, the storage battery supplies power to the illuminating lamp, the illuminating lamp illuminates a corridor, the wind energy conversion device converts wind energy into electric energy to supply power to the storage battery, and when light rays are weak or even disappear, the wind energy conversion part continuously converts the wind energy into the electric energy to continuously supply power to the storage battery, so that the possibility of reducing the electric quantity of the storage battery is reduced, and the possibility of weakening or even extinguishing the light rays of the illuminating lamp is reduced;

2. the spherical concave surface increases the surface area of the windward plate, so that the contact area of the windward plate and air is increased, and the possibility that the windward plate is pushed to rotate by wind power is increased;

3. the impurity in the protection casing air reduces the impurity and attaches to windward plate surface or the possibility of damaging the floater.

Drawings

Fig. 1 is a schematic structural diagram of the embodiment.

Fig. 2 is a partial structure view of fig. 1 taken along the direction of a-a.

Fig. 3 is an enlarged view of a portion B in fig. 2.

Fig. 4 is an enlarged view of the portion C in fig. 2.

Fig. 5 is an enlarged view of a portion D in fig. 4.

In the figure: 1. a building; 11. a corridor; 12. an illuminating lamp; 13. a storage battery; 131. a power transmission line; 2. a wind energy conversion member; 21. a wind power generator; 22. a rotating shaft; 23. a fixing plate; 24. an arc-shaped plate; 25. a power transmission line; 26. fixing a sleeve; 27. a windward plate; 271. a spherical concave surface; 272. a floating ball; 28. a protection plate; 281. a protective mesh enclosure; 3. a light energy conversion member; 31. a solar cell module; 32. a conductive wire; 33. rotating the motor; 34. a drive shaft; 36. a temperature sensor; 37. a control box; 38. and (4) conducting wires.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example (b):

referring to fig. 1, the wind energy and light energy complementary energy-saving corridor lighting device comprises a lighting lamp 12, a storage battery 13, a wind energy conversion part 2 for converting wind energy into electric energy of the storage battery 13, and a light energy conversion part 3 for converting solar light energy into electric energy of the storage battery 13.

Referring to fig. 2, a power transmission wire 131 is arranged on the storage battery 13, one end of the power transmission wire 131, which is far away from the storage battery 13, is connected with the illuminating lamp 12, the illuminating lamp 12 is fixedly connected to the top wall of the corridor 11, the storage battery 13 is arranged on the outer top wall of the building 1, and the wind energy conversion part 2 and the light energy conversion part 3 are both arranged on the outer side surface of the building 1; light 12 is in the work engineering, the electric quantity of battery 13 is through sending electric wire 131 to light 12 power supply, light energy conversion piece 3 converts light energy into the electric energy again and supplies power to battery 13, wind energy conversion piece 2 converts wind energy into the electric energy and supplies power to battery 13, when sunshine weakens, light 12 lasts the electric energy in the work consumption battery 13, wind energy conversion piece 2 continues to convert the wind energy, thereby reduce the possibility that the electric quantity in the battery 13 reduces, and then reduce the possibility that the light of light 12 weakens or even extinguishes.

Referring to fig. 2, the light energy conversion member 3 includes a solar cell module 31 disposed on an outer wall of the building 1, and the solar cell module is connected to the battery 13 through a conductive wire 32.

Referring to fig. 2, a rotating motor 33 is arranged on the outer side wall of the building 1, a transmission shaft 34 is arranged on the end wall of a motor shaft of the rotating motor 33, and the solar cell module 31 is fixedly connected to one end, far away from the rotating motor 33, of the transmission shaft 34.

Referring to fig. 3, a temperature sensor 36 for monitoring the temperature of the top wall of the solar cell module 31 is provided, the temperature sensor 36 is a temperature sensor 36 with a model number PT100, a control box 37 is provided on the bottom wall of the solar cell module 31, and the temperature sensor 36 and the rotating motor 33 are both connected with the control box 37 through a lead 38.

Referring to fig. 3, a shielding sleeve 39 is sleeved outside the rotating motor 33, a connecting sleeve 391 penetrates through the side wall of the shielding sleeve 39, and the transmission shaft 34, the conductive wire 32 and the conductive wire 38 are all located in the connecting sleeve 391; when solar rays irradiate on the top wall of the solar cell module 31, the solar cell module 31 converts light energy into electric energy, the electric energy is supplied to the storage battery 13 through the electric lead 32, when the sun deflects, the intensity of the rays irradiating on the top wall of the solar cell module 31 is different, so that the temperature of local areas of the top wall of the solar cell module 31 is different, the temperature sensor 36 detects the temperature on the top wall of the solar cell module 31 and transmits information to the control box 37 through guidance, the control box 37 rotates the motor 33 through the guided air, the rotating motor 33 is started to drive the transmission shaft 34 to rotate, the transmission shaft 34 adjusts the orientation of the solar cell module 31, and the intensity of the rays irradiating on the top wall of the solar cell module is improved; the blocking sleeve 39 prevents outdoor rainwater from directly contacting the rotary motor 33, and reduces the possibility of rainwater eroding the rotary motor 33.

Referring to fig. 4, the wind energy conversion device 2 includes a wind power generator 21, a rotating shaft 22 and a plurality of fixing plates 23, the wind power generator 21 is disposed on an outer top wall of the building 1, the rotating shaft 22 is fixedly connected to a motor shaft end wall of the wind power generator 21, the rotating shaft 22 is disposed along a height direction of the building 1, the fixing plates 23 are welded on one side of the rotating shaft 22 far away from the wind power generator 21, the fixing plates 23 are disposed along a radial direction of the rotating shaft 22, the number of the fixing plates 23 is four, the four fixing plates 23 are uniformly distributed along a circumferential direction of the rotating shaft 22, the wind power generator 21 is connected with the storage battery 13.

Referring to fig. 4, an arc plate 24 is provided on the bottom wall of the fixing plate 23, the arc plate 24 is disposed along the axial direction of the rotating shaft 22, and the arc plate 24 extends to a side close to the wind power generator 21.

Referring to fig. 4 and 5, a fixing sleeve 26 is disposed on an outer side wall of the rotating shaft 22, an end wall of the fixing sleeve 26 is fixedly connected with a top wall of the wind driven generator 21, one side of the arc plate 24 close to the wind driven generator 21 is rotatably connected with the outer side wall of the fixing sleeve 26 through a bearing, and a rotating space 261 for the rotating shaft 22 to rotate is disposed between an inner side wall of the fixing sleeve 26 and the rotating shaft 22.

Referring to fig. 4, a windward plate 27 is disposed on one side of the arc plate 24 away from the fixing plate 23, the windward plate 27 is disposed along the length direction of the arc plate 24, and a spherical concave surface 271 is disposed on the side surface of the windward plate 27.

Referring to fig. 4, a plurality of floating balls 272 are disposed on the circumferential wall of the windward plate 27, the floating balls 271 are made of aerogel, and the plurality of floating balls 272 are uniformly distributed along the circumferential direction of the windward plate 27.

Referring to fig. 4, a protection plate 28 is disposed on a top wall of the wind turbine 21, the rotating shaft 22 passes through the protection plate 28 and is rotatably connected with the protection plate 28, a protection mesh 281 is disposed on the top wall of the protection plate 28, and the protection mesh 281 covers the windward plate 27; when air flows, the floating ball 272 and the spherical concave surface 271 are pushed, so that the windward plate 27 is driven to rotate, the windward plate 27 drives the arc-shaped plate 24 to rotate, the arc-shaped plate 24 drives the fixing plate 23 to rotate, the fixing plate 23 drives the rotating shaft 22 to rotate, the rotating shaft 22 smoothly starts the wind driven generator 21, electric quantity generated by the wind driven generator 21 is transmitted into the storage battery 13 through the power transmission line 25, and power supply to the storage battery 13 is completed; the fixing sleeve 26 is matched with the arc-shaped plate 24 in the direction, so that the mounting stability of the arc-shaped plate 24 is improved, and the possibility of shaking of the arc-shaped plate 24 in the rotating process is reduced; the protective mesh cover 281 retains impurities in the air, and reduces the possibility that the impurities are attached to the windward plate 27 or damage the floating ball 272.

The implementation principle of the above embodiment is as follows: the light energy conversion part 3 converts light energy into electric energy and supplies power to the storage battery 13, when the illuminating lamp 12 works, the storage battery 13 supplies power to the illuminating lamp 12, the wind energy conversion part 2 converts wind energy into electric energy and supplies power to the storage battery 13, when light is weakened or even disappears, the electric quantity in the storage battery 13 is consumed in the continuous working process of the illuminating lamp 12, the wind energy conversion part 2 continues to supply power to the storage battery 13, thereby the possibility of reducing the electric quantity of the storage battery 13 is reduced, and further the possibility of weakening or even extinguishing the light of the illuminating lamp 12 is reduced.

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

1. The utility model provides a complementary energy-saving corridor lighting device of wind energy light energy, includes light (12) of setting in corridor (11), its characterized in that: the solar energy storage building is characterized by further comprising a storage battery (13) arranged on the outer top wall of the building (1), a wind energy conversion piece (2) and a light energy conversion piece (3), wherein the wind energy conversion piece (2) is arranged on the outer side face of the building (1) and used for converting wind energy into electric energy of the storage battery (13), the light energy conversion piece (3) is used for converting light energy into the electric energy of the storage battery (13), and the storage battery (13) is connected with an illuminating lamp (12) through a power transmission wire (131.

2. The wind energy and light energy complementary energy-saving corridor lighting device according to claim 1, wherein: the wind energy conversion part (2) comprises a wind driven generator (21) arranged on the outer top wall of the building (1), a rotating shaft (22) arranged on the wind driven generator (21) and a plurality of fixing plates (23) arranged on the rotating shaft (22), wherein the fixing plates (23) are uniformly distributed along the circumferential direction of the rotating shaft (22), an arc-shaped plate (24) is arranged on the side surface of each fixing plate (23), the arc-shaped plate (24) is arranged along the axial direction of the rotating shaft (22), and a power transmission line (25) connected with a storage battery (13) is arranged on the wind driven generator (21).

3. The wind energy and light energy complementary energy-saving corridor lighting device according to claim 2, wherein: be equipped with fixed cover (26) on the side of aerogenerator (21), the internal diameter of fixed cover (26) is greater than the diameter of rotation axis (22), rotation axis (22) are located in fixed cover (26), fixed plate (23) are located rotation axis (22) are kept away from aerogenerator's one side, arc (24) are located outside fixed cover (26), arc (24) are close to aerogenerator (21) one side with the lateral wall of fixed cover (26) rotates and is connected.

4. The wind energy and light energy complementary energy-saving corridor lighting device according to claim 2, wherein: the side of the arc-shaped plate (24) far away from the fixed sleeve (26) is provided with a windward plate (27), and the windward plate (27) extends towards the side far away from the fixed sleeve (26).

5. The wind energy and light energy complementary energy-saving corridor lighting device according to claim 4, wherein: the side surface of the windward plate (27) is provided with a spherical concave surface (271).

6. The wind energy and light energy complementary energy-saving corridor lighting device according to claim 4, wherein: the peripheral wall of the windward plate (27) is provided with a plurality of floating balls (272), and the floating balls (272) are uniformly distributed along the circumferential direction of the windward plate (27).

7. The wind energy and light energy complementary energy-saving corridor lighting device according to claim 4, wherein: the wind driven generator is characterized in that a protection plate (28) is arranged on the outer side wall of the wind driven generator (21), a protection net cover (281) covers the top wall of the protection plate (28), and the protection net cover (281) covers the windward plate (27).

8. The wind energy and light energy complementary energy-saving corridor lighting device according to claim 1, wherein: the light energy conversion piece (3) comprises a solar cell module (31) arranged on the outer side wall of the building (1) and a conducting wire (32) arranged on the solar cell module (31), wherein one end, far away from the solar cell module (31), of the conducting wire (32) is fixedly connected with the storage battery (13).

9. The wind energy and light energy complementary energy-saving corridor lighting device according to claim 8, wherein: a rotating motor (33) is arranged on the outer side wall of the building (1), a transmission shaft (34) is arranged on a motor shaft of the rotating motor (33), and the solar cell module (31) is fixedly connected to the end wall of the transmission shaft (34);

be equipped with temperature sensor (36) in solar module (31), be equipped with control box (37) on the diapire of solar module (31), rotate motor (33) with temperature sensor (36) all with control box (37) are connected.