CN111021924A - Independently adjustable building photovoltaic panel shutter type curtain wall - Google Patents

Abstract

The invention discloses an independently adjustable shutter type curtain wall of a building photovoltaic panel, wherein each independent single crystal panel base is provided with at least three lifting devices, each lifting device comprises a motor, a driving gear and a first driven gear, the second driven gear, the control lever, first driven gear shaft and second driven gear shaft, the motor is fixed in independent single crystal panel base, the output shaft of motor is fixed with the driving gear, first driven gear fixes on first driven gear shaft, the second driven gear fixes on the second driven gear shaft, the both ends of first driven gear shaft and second driven gear shaft are all installed in independent single crystal panel base through the bearing that corresponds, the rack and the meshing of first driven gear and second driven gear of control lever both sides, driving gear and the meshing of first driven gear, the top of each control lever in every independent single crystal panel base all is connected with single crystal panel through universal hemisphere. The invention has flexible rotation mode and can improve the output power of the photovoltaic cell.

Description

Independently adjustable building photovoltaic panel shutter type curtain wall

Technical Field

The invention relates to the technical field of building photovoltaic panel curtain walls, in particular to an independently adjustable building photovoltaic panel louver type curtain wall.

Background

At present, building photovoltaic tripe curtain can replace traditional glass curtain wall in the in-service use, can reduce the light pollution in city to a certain extent to and make full use of urban space obtains renewable energy such as light energy, can play the function of shading simultaneously. However, the current photovoltaic shutters have the following disadvantages:

1. the rotation mode is limited: current photovoltaic blinds can only be rotated in a single axis, for example along a horizontal axis or along a vertical axis, with little flexibility.

2. The output power of the photovoltaic cell is not high: the output power of the photovoltaic cell is relatively low according to 1) because the rotation is limited so that the photovoltaic panel cannot be always perpendicular to the sunlight.

3. The light transmittance is not high: because building photovoltaic board uses as the function of a curtain, the curtain mainly plays weather proof and blocks the invasion of external environment, has the printing opacity function simultaneously, if installation photovoltaic board curtain will shelter from sunshine, so shutter type building photovoltaic board can appear, building photovoltaic board on the present market divide into two kinds according to the printing opacity function, one kind is the building photovoltaic board that can not contract, can only rely on the unipolar to rotate and realize the printing opacity, this kind of luminousness receives the rotation restriction.

4. The shrink photovoltaic louver is easily damaged: according to 3) still there is building photovoltaic shutter of a printing opacity mode, can receive whole photovoltaic shutter, realize the printing opacity of whole window printing opacity's large tracts of land printing opacity mode, but this kind of shrink mode very easily causes the damage of building photovoltaic shutter connecting portion, and damages the cost higher, is unfavorable for installation and practical application.

5. Lose the partial function of original curtain: according to the above 3) and 4), the louver window can transmit light after being rotated or contracted, but the functions of preventing wind and rain and preventing intrusion of the external environment of the curtain wall are lost, so that the louver window is particularly existed in the current office buildings facing nine nights and five nights, if the louver window is not closed in time after all people leave, the intrusion of the external environment to the indoor space is caused, the life and property safety of the crisis can be seriously influenced, and the louver window is not suitable for the safety aspect.

6. The intelligent control can not be carried out: at present, the photovoltaic curtain wall of a building does not realize intelligent rotation in the aspect of control, and the sun cannot be tracked to the maximum extent, so that the output power of a photovoltaic cell becomes high. While the photovoltaic panel cannot be turned according to personal thoughts using smart devices.

Disclosure of Invention

The invention aims to provide an independently adjustable building photovoltaic panel louver type curtain wall, which is flexible in rotation mode and can improve the output power of a photovoltaic cell.

In order to achieve the purpose, the invention designs an independently adjustable building photovoltaic panel louver type curtain wall, which is characterized in that: the curtain wall comprises a plurality of single crystal panels forming the curtain wall and independent single crystal panel bases corresponding to the plurality of single crystal panels one to one, wherein at least three lifting devices are arranged in each independent single crystal panel base, each lifting device comprises a motor, a driving gear, a first driven gear, a second driven gear, a control rod, a first driven gear shaft and a second driven gear shaft, the motors are fixed in the independent single crystal panel bases, the driving gear is fixed on an output shaft of each motor, the first driven gear is fixed on the first driven gear shaft, the second driven gear is fixed on the second driven gear shaft, two ends of each of the first driven gear shaft and the second driven gear shaft are respectively installed in the independent single crystal panel bases through corresponding bearings, racks are respectively arranged on two sides of the control rod, the rack on one side of the control rod is meshed with the first driven gear, and the rack on the other side of the control rod is meshed with the second, the driving gear is meshed with the first driven gear, and the top of each control rod in each independent single crystal panel base is connected with the bottom of the corresponding single crystal panel through a universal hemisphere.

The intelligent control system further comprises a photosensitive signal receiver, an infrared signal receiver, a radio frequency signal receiver, a rainwater sensing signal receiver, a wind power sensing signal receiver and an intelligent controller used for controlling motors in the lifting devices, wherein signal output ends of the photosensitive signal receiver, the infrared signal receiver, the radio frequency signal receiver, the rainwater sensing signal receiver and the wind power sensing signal receiver are respectively connected with corresponding signal input ends of the intelligent controller.

The intelligent controller is used for controlling each motor in each lifting device according to the infrared control signal to realize the control of the angle of each single crystal panel;

the radio frequency signal receiver is used for receiving a radio frequency control signal of the louver type curtain wall sent by the mobile phone, and the intelligent controller is used for controlling each motor in each lifting device according to the infrared control signal so as to control the angle of each single crystal panel.

The photosensitive signal receiver is used for sensing an illumination signal, the intelligent controller is used for realizing a control function of a sun tracking mode according to the illumination signal, controlling each motor in each lifting device and realizing the control of the angle of each single crystal panel.

The intelligent controller is used for controlling each motor in each lifting device according to the rainfall condition and the preset rain single crystal panel control logic so as to realize the control of the angle of each single crystal panel;

the wind power induction signal receiver is used for inducing outdoor wind power conditions, the intelligent controller is used for controlling each motor in each lifting device according to the outdoor wind power conditions and the control logic of the single crystal panel according to the preset windy weather, and the angle of each single crystal panel is controlled.

The invention has the advantages that:

1. the rotation mode is various: the structure of the invention is convenient for adjusting the angle of the single crystal panel in each direction.

2. The photovoltaic cell output power becomes high: according to the advantage 1, the rotation mode can be specially used for enabling each independent single crystal panel of the photovoltaic shutter to track the sun, the technology can enable each independent single crystal panel of the photovoltaic shutter to be perpendicular to sunlight every day to the maximum extent, the output power of a photovoltaic cell can be greatly improved, and the cell storage energy efficiency is higher.

3. Remote control with a standalone mobile device: the intelligent controller is provided with a photosensitive signal receiver, an infrared signal receiver, a radio frequency signal receiver, a rainwater sensing signal receiver and a wind power sensing signal receiver, the single crystal panel can be automatically adjusted through the intensity of light, the single crystal panel can be adjusted through an infrared remote controller, the single crystal panel can be adjusted through a mobile phone, the single crystal panel can be automatically adjusted through a rainwater sensor, and the single crystal panel can be automatically adjusted through a wind power sensor.

According to the advantage 3, all the rotating modes of the invention are semi-automatic, all the rotating modes are indirect manual contact machines, namely, the moving equipment is used for controlling the rotation of the single crystal panel, so that the damage of the shutter component of the photovoltaic panel caused by manual misoperation can be avoided.

Drawings

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

FIG. 2 is a schematic view of a single crystal panel and a corresponding single crystal panel base according to the present invention;

FIG. 3 is a schematic perspective view of the lifting device of the present invention in one direction;

FIG. 4 is a schematic perspective view of the lifting device of the present invention in another direction;

fig. 5 is a schematic structural diagram of an electric control part in the present invention.

The device comprises a single crystal panel 1, an independent single crystal panel base 2, a lifting device 3, a motor 3.1, a driving gear 3.2, a first driven gear 3.3, a second driven gear 3.4, a control rod 3.5, a first driven gear shaft 3.6, a second driven gear shaft 3.7, a rack 3.8, a limiting block 3.9, a first transmission gear 3.10, a second transmission gear 3.11, a universal hemisphere 4, a photosensitive signal receiver 5, an infrared signal receiver 6, a radio frequency signal receiver 7, a rain sensing signal receiver 8, a wind sensing signal receiver 9 and an intelligent controller 10.

Detailed Description

The invention is described in further detail below with reference to the following figures and specific examples:

the independently adjustable building photovoltaic slat louvered curtain wall as shown in fig. 1-5 comprises a plurality of single crystal panels 1 forming the curtain wall, independent single crystal panel bases 2 corresponding to the plurality of single crystal panels 1 one by one, wherein at least three lifting devices 3 are arranged in each independent single crystal panel base 2, each lifting device 3 comprises a motor 3.1, a driving gear 3.2, a first driven gear 3.3, a second driven gear 3.4, a control rod 3.5, a first driven gear shaft 3.6 and a second driven gear shaft 3.7, the motor 3.1 is fixed in the independent single crystal panel base 2, the driving gear 3.2 is fixed on an output shaft of the motor 3.1, the first driven gear 3.3 is fixed on the first driven gear shaft 3.6, the second driven gear 3.4 is fixed on the second driven gear shaft 3.7, two ends of the first driven gear shaft 3.6 and the second driven gear shaft 3.7 are both installed in the independent single crystal panel bases 2 through corresponding bearings, the two sides of the control rod 3.5 are respectively provided with a rack 3.8, the rack 3.8 on one side of the control rod 3.5 is meshed with the first driven gear 3.3, the rack 3.8 on the other side of the control rod 3.5 is meshed with the second driven gear 3.4, the driving gear 3.2 is meshed with the first driven gear 3.3, and the top of each control rod 3.5 in each independent single crystal panel base 2 is connected with the bottom of the corresponding single crystal panel 1 through a universal hemisphere 4. Each control rod 3.5 can independently move without being influenced by other control rods 3.5, so that the corresponding single crystal panel 1 can be adjusted in angle at multiple angles, the single crystal panel 1 is perpendicular to the solar rays to the maximum extent, and the output power of the photovoltaic cell is maximized.

The single crystal panel uses the semitransparent double-glass solar photovoltaic power generation battery panel component, the light transmittance is higher than that of the original opaque photovoltaic panel, a gap of 25mm is reserved between each two independent single crystal panels, and the daily brightness requirement can be met even under the condition that the photovoltaic shutter is completely closed.

In the above technical scheme, each lifting device 3 further comprises a first transmission gear 3.10 and a second transmission gear 3.11, the first transmission gear 3.10 is fixed on a first driven gear shaft 3.6, the second transmission gear 3.11 is fixed on a second driven gear shaft 3.7, the first transmission gear 3.10 is meshed with the second transmission gear 3.11, the transmission mode effectively avoids the situation that the second driven gear and the rack 3.8 are jammed, and the effect of ensuring the vertical movement of the control rod 3.5 is achieved. The gears are meshed tightly, no delay exists in gear transmission, and if the first transmission gear 3.10 and the second transmission gear 3.11 are not provided, the first driven gear 3.3 only transmits to the second driven gear 3.4 through the control rod 3.5, the phenomenon that meshing is not tight and jamming occurs possibly can occur.

In the technical scheme, the diameter of the first transmission gear 3.10 is larger than that of the first driven gear 3.3, the diameter of the second transmission gear 3.11 is larger than that of the second driven gear 3.4, the first transmission gear 3.10 and the second transmission gear 3.11 have the same size and specification, and the first driven gear 3.3 and the second driven gear 3.4 have the same size and specification, so that the synchronism of power transmission is ensured. The first transmission gear 3.10 and the second transmission gear 3.11 ensure that the first driven gear 3.3 and the second driven gear 3.4 rotate synchronously, so that the control rod 3.5 is operated to ascend or descend.

Among the above-mentioned technical scheme, the bottom and the top of every independent single crystal panel base 2 all are equipped with the through-hole that supplies control lever 3.5 to pass, and the bottom of control lever 3.5 is fixed with stopper 3.9, and stopper 3.9 is used for withstanding the bottom of independent single crystal panel base 2 when control lever 3.5 rises to extreme position, prevents that control lever 3.5 from deviating from.

In the above technical solution, the plurality of single crystal panels 1 of the curtain wall may be single crystal panels of different shapes or single crystal panels of the same shape. The design can meet the requirements of various shapes of curtain walls.

In the above technical scheme, all the flat cables of the single crystal panel 1 are connected to the storage battery through the concentrator.

In the above technical solution, it further includes a photosensitive signal receiver 5, an infrared signal receiver 6, a radio frequency signal receiver 7, a rainwater sensing signal receiver 8, a wind power sensing signal receiver 9, and an intelligent controller 10 for controlling the motors 3.1 in the lifting devices 3, wherein signal output ends of the photosensitive signal receiver 5, the infrared signal receiver 6, the radio frequency signal receiver 7, the rainwater sensing signal receiver 8, and the wind power sensing signal receiver 9 are respectively connected to corresponding signal input ends of the intelligent controller 10.

In the technical scheme, the infrared signal receiver 6 is used for receiving an infrared control signal of an infrared remote controller of the louvered curtain wall, and the intelligent controller 10 is used for controlling each motor 3.1 in each lifting device 3 according to the infrared control signal so as to control the angle of each single crystal panel 1;

the radio frequency signal receiver 7 is used for receiving a radio frequency control signal of a louvered curtain wall sent by a mobile phone, and the intelligent controller 10 is used for controlling each motor 3.1 in each lifting device 3 according to the infrared control signal so as to control the angle of each single crystal panel 1.

In the above technical solution, the photosensitive signal receiver 5 is used for sensing an illumination signal, and the intelligent controller 10 is used for realizing a control function of a sun tracking mode according to the illumination signal, controlling each motor 3.1 in each lifting device 3, and realizing control of the angle of each single crystal panel 1.

In the above technical solution, the rain sensing signal receiver 8 is used for sensing outdoor rainfall conditions, and the intelligent controller 10 is used for controlling each motor 3.1 in each lifting device 3 according to the rainfall conditions and according to preset rainy single crystal panel control logic, so as to control the angle of each single crystal panel 1;

the wind sensing signal receiver 9 is used for sensing outdoor wind conditions, and the intelligent controller 10 is used for controlling the motors 3.1 in the lifting devices 3 according to the outdoor wind conditions and the control logic of the single crystal panel in the preset windy weather so as to control the angle of each single crystal panel 1.

When the photovoltaic cell power generation device works, each motor 3.1 rotates under the control of the intelligent controller 10, the rotation of each motor 3.1 drives the corresponding first driven gear 3.3 to rotate, so that the corresponding first transmission gear 3.10, the second transmission gear 3.11 and the second driven gear 3.4 synchronously rotate, the first driven gear 3.3 and the second driven gear 3.4 rotate, the corresponding control rod 3.5 is driven by the rack 3.8 to realize lifting, the lifting degrees of the control rods 3.5 are possibly different according to the control of the intelligent controller 10, at the moment, the single crystal panels 1 present corresponding angles due to the action of the universal hemisphere 4, each single crystal panel 1 adopts the control mode to independently adjust the angle, the purpose that each single crystal panel 1 is maximally vertical to the sunlight is realized, and the maximization of the output power of the photovoltaic cell is realized.

Details not described in this specification are within the skill of the art that are well known to those skilled in the art.

Claims (10)

1. The utility model provides a building photovoltaic board tripe formula curtain that can independently adjust which characterized in that: the curtain wall comprises a plurality of single crystal panels (1) forming a curtain wall and independent single crystal panel bases (2) corresponding to the plurality of single crystal panels (1) one to one, wherein at least three lifting devices (3) are arranged in each independent single crystal panel base (2), each lifting device (3) comprises a motor (3.1), a driving gear (3.2), a first driven gear (3.3), a second driven gear (3.4), a control rod (3.5), a first driven gear shaft (3.6) and a second driven gear shaft (3.7), the motors (3.1) are fixed in the independent single crystal panel bases (2), the driving gears (3.2) are fixed on output shafts of the motors (3.1), the first driven gears (3.3) are fixed on the first driven gear shafts (3.6), the second driven gears (3.4) are fixed on the second driven gear shafts (3.7), two ends of the first driven gear shafts (3.6) and the second driven gear shafts (3.7) are installed in the single crystal panels (2) of the independent single crystal panels (2) through corresponding bearings The two sides of the control rod (3.5) are respectively provided with a rack (3.8), the rack (3.8) on one side of the control rod (3.5) is meshed with the first driven gear (3.3), the rack (3.8) on the other side of the control rod (3.5) is meshed with the second driven gear (3.4), the driving gear (3.2) is meshed with the first driven gear (3.3), and the top of each control rod (3.5) in each independent single crystal panel base (2) is connected with the bottom of the corresponding single crystal panel (1) through the universal hemisphere (4).

2. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 1 wherein: each lifting device (3) further comprises a first transmission gear (3.10) and a second transmission gear (3.11), the first transmission gear (3.10) is fixed on the first driven gear shaft (3.6), the second transmission gear (3.11) is fixed on the second driven gear shaft (3.7), and the first transmission gear (3.10) is meshed with the second transmission gear (3.11).

3. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 2 wherein: the diameter of the first transmission gear (3.10) is larger than that of the first driven gear (3.3), and the diameter of the second transmission gear (3.11) is larger than that of the second driven gear (3.4).

4. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 1 wherein: the bottom and the top of each independent single crystal panel base (2) are provided with through holes for the control rod (3.5) to pass through, the bottom of the control rod (3.5) is fixed with a limiting block (3.9), and the limiting block (3.9) is used for propping against the bottom of the independent single crystal panel base (2) when the control rod (3.5) rises to a limit position, so that the control rod (3.5) is prevented from being separated.

5. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 1 wherein: the curtain wall is characterized in that the plurality of single crystal panels (1) of the curtain wall are single crystal panels in different shapes or single crystal panels in the same shape.

6. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 1 wherein: the flat cables of all the single crystal panels (1) are connected into the storage battery through the concentrator.

7. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 1 wherein: it still includes photosensitive signal receiver (5), infrared signal receiver (6), radio frequency signal receiver (7), rainwater response signal receiver (8), wind-force response signal receiver (9) and be arranged in carrying out intelligent control ware (10) of controlling motor (3.1) in each elevating gear (3), wherein, photosensitive signal receiver (5), infrared signal receiver (6), radio frequency signal receiver (7), rainwater response signal receiver (8), the signal output part of wind-force response signal receiver (9) connects the signal input part that corresponds of intelligent control ware (10) respectively.

8. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 7 wherein: the infrared signal receiver (6) is used for receiving infrared control signals of the infrared remote controller of the louver curtain wall, and the intelligent controller (10) is used for controlling each motor (3.1) in each lifting device (3) according to the infrared control signals to realize the control of the angle of each single crystal panel (1);

the radio frequency signal receiver (7) is used for receiving a louver type curtain wall radio frequency control signal sent by a mobile phone, and the intelligent controller (10) is used for controlling each motor (3.1) in each lifting device (3) according to an infrared control signal to realize the control of the angle of each single crystal panel (1).

9. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 7 wherein: the photosensitive signal receiver (5) is used for sensing an illumination signal, the intelligent controller (10) is used for realizing a control function of a sun tracking mode according to the illumination signal, controlling each motor (3.1) in each lifting device (3) and realizing the control of the angle of each single crystal panel (1).

10. The independently adjustable building photovoltaic paneled louvered curtain wall of claim 7 wherein: the rain sensing signal receiver (8) is used for sensing outdoor rainfall conditions, and the intelligent controller (10) is used for controlling each motor (3.1) in each lifting device (3) according to the rainfall conditions and preset rain single crystal panel control logics to realize the control of the angle of each single crystal panel (1);

the wind power induction signal receiver (9) is used for inducing outdoor wind power conditions, the intelligent controller (10) is used for controlling each motor (3.1) in each lifting device (3) according to the outdoor wind power conditions and the control logic of the single crystal panel in the preset windy weather, and the angle of each single crystal panel (1) is controlled.

Images