KR102059992B1 - Rotating PV Module for Indoor Installation - Google Patents

Abstract

The present invention relates to a rotatable photovoltaic module for indoor installation, and more particularly, by installing a plurality of photovoltaic cells in a polygonal shape, and rotating and allowing photovoltaic power generation to occur, the solar cell of higher efficiency in a small area The present invention relates to a rotatable solar power module for indoor installation that can be installed on a balcony or balcony of a house. An object of the present invention is to provide a rotatable solar power module for indoor installation that is installed indoors, easy to maintain and repair, increase the efficiency of photovoltaic power generation per same area, and easy to store and use energy.

Description

Rotating PV Module for Indoor Installation

The present invention relates to a rotatable photovoltaic module for indoor installation, and more particularly, by installing a plurality of photovoltaic cells in a polygonal shape, and rotating and allowing photovoltaic power generation to occur, the solar cell of higher efficiency in a small area The present invention relates to a rotatable solar power module for indoor installation that can be installed on a balcony or balcony of a house.

The present invention relates to a rotatable photovoltaic module for indoor installation, and more particularly, by installing a plurality of photovoltaic cells in a polygonal shape, and rotating and allowing photovoltaic power generation to occur, the solar cell of higher efficiency in a small area The present invention relates to a rotatable solar power module for indoor installation that can be installed on a balcony or balcony of a house.

Patent Registration No. 10-1104770 (Registration date 2012.01.04.)

The present invention has been made to solve the above problems, the object of the present invention is installed indoors, easy to maintain and repair, increase the efficiency of photovoltaic power generation per the same area, for indoor installation easy to store and use energy The present invention provides a rotary solar power module.

According to an embodiment of the present invention, the indoor solar power generation module of the present invention is a solar power generation module, which is formed in the left and right longitudinal direction, one side of which is connected to the first rotating shaft, the first rotating shaft, the motor unit And a polygonal photovoltaic power generation unit formed of at least one photovoltaic cell having a predetermined length and rotating along the rotation of the first rotational shaft, the center being formed at the center of the photovoltaic power generation unit. Connected to a photovoltaic unit to rotate the photovoltaic unit, a second rotating shaft connected to an auxiliary motor unit on one side, a support unit supporting the first rotating shaft, and storing energy generated by the photovoltaic unit, A control unit for controlling the operation of the power generation unit, a transparent cover connected to the support unit and protecting the first rotating shaft and the solar power generation unit from the outside It includes an opening, the solar power generation unit, one side is connected to the longitudinal outer peripheral surface of the first rotation shaft, the other side is connected to both ends of the second rotation shaft and one side connecting portion and one side in the longitudinal direction of the second rotation shaft It is connected to the outer circumferential surface, and the other side is characterized in that it comprises a biaxial connection portion connected to the solar cell.

delete

In addition, the photovoltaic cell may further include a light collecting part attached to the surface of the photovoltaic cell.

In addition, the light collecting part may be formed of a plurality of Fresnel lenses or a plurality of convex lenses formed on one transparent surface.

In addition, the photovoltaic unit may further comprise a cooling hole to allow the outside air to enter the solar cell to cool the photovoltaic unit.

In addition, the support portion has one side connected to one side of the first rotation shaft, the vertical support portion for supporting the first rotation shaft and the other side of the first rotation shaft is connected, characterized in that it comprises a horizontal support portion seated on the ground can do.

The control unit may include a power control unit controlling power of the motor unit connected to one side of the first rotation shaft and an auxiliary boter unit connected to one side of the second rotation shaft, and storing electrical energy generated by the solar power generation unit. It may be characterized in that it comprises a battery unit and an output unit for outputting the power stored in the battery unit to be used to the outside.

The control unit may receive a control signal from an external device, calculate current motor and battery information calculated in a predetermined algorithm, and control the power of the motor by a control signal received from an external device.

The indoor photovoltaic solar module may further include a remote control means connected to a network with the control unit using a preset wireless communication network to input a control signal to the control unit at a long distance. It may be characterized in that for transmitting and receiving data using the remote control means and the wireless communication network.

In addition, the cover portion may be attached to the outer surface of the cover portion, it may be characterized in that it further comprises a light collecting member for condensing sunlight.

In addition, the light collecting member may include a plurality of Fresnel lenses or a plurality of convex lenses formed on one transparent surface.

Rotation type solar power module for indoor installation of the present invention by the configuration as described above is to install a plurality of solar cells in a polygonal shape, it is possible to rotate and evenly generate the solar cells, and to focus on the cooling effect through rotation This can prevent the solar cell life from decreasing.

In addition, through the cover portion provided in the rotatable solar power generation module for indoor installation, it is possible to prevent contamination of the module by external foreign substances or increase the safety of the user.

In addition, the amount of power generation can be checked in real time indoors or outdoors, and the control signal can be transmitted from the outside to control the power of the motor unit, and the home appliance can be connected to the module using the stored electric energy to operate the user. Module management and energy use is convenient.

1 is an overall perspective view of a conventional solar housing condensing structure
Figure 2 is a front view of a rotary solar power module for indoor installation of the present invention
Figure 3 is an enlarged view of the rotatable photovoltaic module solar power generation unit for indoor installation of the present invention
4 is a right side view of a rotatable photovoltaic module for indoor installation according to an embodiment of the present invention.
5 is a configuration of a rotary solar power module control unit for indoor installation according to an embodiment of the present invention
Figure 6 is an exemplary view of a remote control solar power module remote control means for indoor installation according to an embodiment of the present invention

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be variations.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings. The accompanying drawings are only examples to illustrate the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the forms of the accompanying drawings.

2 to 4, the indoor solar cell module 100 of the present invention is installed in the solar power generation module, the left and right longitudinal direction is formed, one side of the first rotating shaft 300 connected to the motor unit, Is installed on the outer peripheral surface of the rotary shaft, formed in the polygonal photovoltaic power generation unit 400 of the at least one photovoltaic cell 410 formed in the longitudinal direction, the center of the solar power generation unit 400, the rotation axis And a support part which is connected to the solar power generation unit 400 to rotate the solar power generation unit 400 and one side supports the second rotation shaft 420 and the first rotation shaft 300 connected to the auxiliary motor unit. 200, a control unit 600 for storing energy generated by the photovoltaic unit 400, and controlling the operation of the photovoltaic unit 400, connected to the support unit 200, and the first unit. Protect the rotating shaft 300 and the solar power generation unit 400 from the outside It is configured to include a cover portion 500 of the transparent.

At this time, although not shown at one end of the first rotary shaft 300, a motor portion for transmitting a rotational force to the first rotary shaft 300 is formed. The motor unit may be directly connected to the shaft by the first rotation shaft 300 to transmit power, and is inherent in the support portion 200 to indirectly transmit rotational force to the first rotation shaft 300 through a gear or a belt. can do. At this time, it is preferable that the motor unit maintains a fixed speed or rotates within a predetermined range according to the specification of the motor unit. When the motor unit rotates at a high speed, the power generation efficiency of the photovoltaic unit 400 may be lowered, so that the rotational speed of the motor unit is preferably maintained at 20 RPM or less. In addition, the motor unit is preferably electrically connected to the control unit 600 by a circuit or wireless.

Referring to FIG. 2, the photovoltaic unit 400 of the rotatable photovoltaic module 100 for indoor installation according to an embodiment of the present invention is a conventional solar cell 410 that converts sunlight into electrical energy. Alternatively, a plurality of photovoltaic modules, such as solar panels, are preferably connected to each other. The solar power generation unit 400 rotates the rotational force by the motor unit about the first rotation shaft 300.

In addition, the solar power generation unit 400 has one side connected to the longitudinal outer peripheral surface of the first rotation shaft 300, the other side is connected to both ends of the second rotation shaft 420, one-axis connecting portion 301 and One side may be connected to the longitudinal outer circumferential surface of the second rotation shaft 420, the other side may be configured to include a biaxial connection portion 411 is connected to the solar cell 410.

The solar power generation unit 400 may be radially installed around the first rotation shaft 300 through the one-axis connecting portion 301, and may be rotated along the rotation of the first rotation shaft 300. In such a configuration, the photovoltaic unit 400 may have more photovoltaic cells 410 installed in the same area, thereby increasing photovoltaic power generation efficiency and having a cooling effect through rotation. The life of the optical cell 410 can be maintained longer.

In addition, the one-axis connecting portion 301 is connected to both ends of the second rotating shaft 420, the second rotating shaft 420 is not fixed to the one-axis connecting portion 301, the second rotating shaft 420 ) Is preferably connected to allow rotation. For example, a hole is formed at the other side of the one-axis connecting portion 301 connected to the second rotation shaft 420, and both sides of the second rotation shaft 420 are formed at the other side of the one-axis connecting portion 301. It is loosely inserted in the member, the member having a diameter larger than the hole formed on the other side of the one-axis connecting portion 301 is coupled to both ends of the second rotary shaft 420, the second rotary shaft 420 and the one shaft The connection of the connection unit 301 can be prevented from being released.

The solar cell 410 may be fixed to the second rotation axis 420 through the biaxial connection part 411, and the solar cell 410 may have a polygonal angle about the second rotation axis 420. Can be formed. The photovoltaic cell 410 is not limited to the hexagonal shape shown in FIG. 2, and may be configured in more various shapes, such as four-angle and eight-angle.

In addition, the two-axis connecting portion 411 is fixed to the longitudinal outer peripheral surface of the second rotary shaft 420, the solar cell 410 along the rotation of the second rotary shaft 420 the second rotary shaft 420 It is preferable to be connected so that it can rotate about. At this time, the auxiliary motor unit may be mounted on any one side or the other side of the second rotation shaft 420 to rotate the second rotation shaft 420. The auxiliary motor unit may be directly coupled to the second rotation shaft 420 to transmit power. At this time, it is preferable that the auxiliary motor unit maintains a fixed speed or rotates within a predetermined range according to the specification of the auxiliary motor unit. When the auxiliary motor unit rotates at a high speed, the power generation efficiency of the photovoltaic unit 400 may be reduced, so that the rotational speed of the motor unit is preferably maintained at 20 RPM or less. In addition, the auxiliary motor unit is preferably electrically connected to the control unit 600 in a circuit or wireless.

In addition, the support part 200 of the rotatable photovoltaic module 100 for indoor installation according to an embodiment of the present invention includes the first rotation shaft 300 and the photovoltaic unit 400. The rotatable photovoltaic module 100 for installation is configured to be seated on the ground, and the support part 200 has one side connected to one side of the first rotation shaft 300 to connect the first rotation shaft 300. The other side of the vertical support portion 210 and the first rotating shaft 300 to support is connected, it may be characterized in that it comprises a horizontal support portion 220 which is seated on the ground. One side of the first rotation shaft 300 is connected to one side of the vertical support portion 210 to maintain the rotation of the first rotation shaft 300 in a stable manner, and inside the vertical support portion 210. A circuit connecting the motor unit connected to the first rotating shaft 300 and the control unit 600 and a circuit connecting the auxiliary botter unit of the second rotating shaft 420 and the control unit 600 may be stored. .

In addition, the cover 500 of the rotatable photovoltaic module 100 for indoor installation according to an embodiment of the present invention, the first rotating shaft 300 and the photovoltaic unit 400 from an external material It can protect and is a means of protecting a user from the rotatable solar power module 100 for indoor installation of this invention. The cover 500 is preferably made of transparent glass or transparent plastic so that sunlight can be transmitted to the photovoltaic unit 400.

In addition, the cover part 500 may be attached to the outer surface of the cover part 500, as shown in FIG. 2, may further comprise a light collecting member 510 for condensing sunlight. In this case, the light condensing 510 may be formed by forming a plurality of Fresnel lenses or a plurality of convex lenses on one transparent surface. The light collecting member 510 may be installed such that the convex surface of the lens faces the outer surface direction of the cover part 500 and the flat surface of the lens faces the cover part 500 direction. Through the light collecting member 510 as described above, sunlight is collected into the cover part 500 to increase power generation efficiency through sunlight.

Referring to FIG. 3, the solar cell 410 of the rotatable solar power module 100 for indoor installation according to an embodiment of the present invention includes a light collecting part 430 attached to the surface of the solar cell 410. It may be characterized in that it further comprises. In this case, the light collecting part 430 may be formed by forming a plurality of Fresnel lenses or a plurality of convex lenses on one transparent surface. The condenser 430 may be installed such that the convex surface of the lens faces the outer surface of the photovoltaic unit 400 and the flat surface of the lens faces the photovoltaic unit 400. Through the light collecting unit 430 as described above, the solar light is concentrated on the solar power generating unit 400, thereby increasing power generation efficiency through solar light.

In addition, the photovoltaic unit 400 of the rotatable photovoltaic module 100 for indoor installation according to an embodiment of the present invention enters outside air into the photovoltaic cell 410 and the photovoltaic unit 400 It may be characterized in that it further comprises a cooling hole 440 to cool. The photovoltaic unit 400 is preferably configured in a shape that is blocked so that the inside can not be seen from the outside in safety and aesthetics, as shown in FIG. 3 of the photovoltaic unit 400 through the cooling hole 440. Outside and inside the air may move to prevent overheating of the photovoltaic unit 400, it is possible to prevent a decrease in life due to overheating of the photovoltaic cell 410.

Referring to FIG. 4, the photovoltaic unit 400 of the rotatable photovoltaic module 100 for indoor installation according to an embodiment of the present invention has two rows or along the longitudinal direction of the first rotation shaft 300. According to the length of the first rotating shaft 300 may be made of more than that. At this time, it is apparent that the one-axis connecting portion 301 is also formed for the connection between the first rotation shaft and the photovoltaic unit 400 according to the number of columns of the photovoltaic unit 400.

In addition, the control unit 600 of the rotatable photovoltaic module 100 for indoor installation according to an embodiment of the present invention is the motor unit and the second rotating shaft (connected to one side of the first rotating shaft 300 ( The power control unit 610 for controlling the power of the auxiliary motor unit connected to one side of the 420, the battery unit 620 and the battery unit 620 for storing the electrical energy generated by the solar power generation unit 400 It may be characterized in that it comprises an output unit 630 for outputting the power stored in the outside to be used. The power control unit 610 and the battery unit 620 will be described in detail with reference to FIG. 5. The photovoltaic unit 400 may be generated through the output unit 630, and the electrical energy stored in the battery unit 620 may be used as an energy source for operation of electronic products used in homes. The output unit 630 may be configured to be connected to a wire provided in the control unit 600 to connect a cord used indoors to insert an external plug. The output unit 630 may vary in voltage, frequency, shape, size, and connector type according to national standards.

Referring to FIG. 5, the control unit 600 of the rotatable photovoltaic module 100 for indoor installation according to an embodiment of the present invention includes the power control unit 610, the battery unit 620, and the output unit. 630, a communication unit 640, and a display unit 650 may be configured.

The power control unit 610 may control power of the motor unit and the auxiliary motor unit to control free rotation and forced rotation of the first rotation shaft 300 and the second rotation shaft 420, and the battery unit 620 is a configuration for storing the electrical energy generated through the condensing of the photovoltaic unit 400.

In addition, the control unit 600 may be connected to the motor unit and the auxiliary motor unit by wireless or wired through the communication means unit 640 to transmit and receive signals, and may receive a control signal transmitted from the outside. In addition, information about the rotational speed of the motor unit and the auxiliary motor unit and the amount of charge of the battery unit 620 may be transmitted to an external control unit. The user of the indoor installation rotary solar power module 100 through the communication means unit 640 can check the operating state of the indoor solar power solar module 100 for installation, the power control unit By transmitting a signal to 610 to control the power of the motor unit and the auxiliary motor unit, efficient power use is possible.

 In addition, the control unit 600 may display the rotational speed of the motor unit and the auxiliary motor unit and the battery charge amount of the battery unit 620 through the display unit 650 on the screen. The user of the indoor installation of the rotary solar power module 100 through the display unit 650 can check the operating state of the indoor installation of the rotary solar power module 100, the power control unit ( By transmitting a signal to 610 to control power of the motor unit and the auxiliary motor unit, efficient power use is possible. At this time, the user in the room may transmit a signal to the power control unit 610 through a button or screen touch.

Furthermore, the control unit 600 of the rotatable solar power module 100 for indoor installation according to an embodiment of the present invention is electrically connected to the sunlight detector 700 provided outside to receive a signal. The sunlight detector 700 may be used by a conventional solar sensor. The sunlight detector 700 detects the presence of sunlight, and when sunlight is detected by the sunlight detector 700, sends a signal to the power control unit 610 to turn on the power of the motor unit and the auxiliary motor unit, When sunlight is not detected, power may be sent to the power control unit 610 to cut off power of the motor unit and the auxiliary motor unit. Thus, when there is sunlight, by rotating the first rotation axis 300 and the second rotation axis 420, so that the solar cell 410 can see the sunlight evenly, the sun by the concentration of sunlight The overheating of the optical cell 410 can be prevented, and there is also a cooling effect by the rotation of the first rotating shaft 300. In addition, when sunlight is not detected by the sunlight detector 700, by sending a signal to the power control unit 610 to turn off the power of the tab portion and the auxiliary motor unit, it is possible to prevent power waste.

Referring to FIG. 6, the control unit 600 of the rotatable photovoltaic module 100 for indoor installation according to an embodiment of the present invention receives the control signal from the outside and calculates the current to the preset algorithm. The motor unit, the auxiliary motor unit and the battery unit 620 may be calculated and the power of the motor may be controlled by a control signal input from the outside. At this time, as shown in Figure 6, the rotatable photovoltaic module 100 for indoor installation may be configured to further include a remote control means (800).

The remote control means 800 may be preset and perform wireless control through an application screen through FIG. 6.

The remote control unit 800 is rotated by the motor unit and the upper limb auxiliary motor unit, as shown in FIG. Information such as speed and battery level of the battery unit may be checked in real time. At this time, the remote control means 800 may additionally receive the presence or absence of sunlight information through the sunlight sensor 700 to display on the screen.

In detail, the remote control means 800 may be networked with the control unit 600 using a preset wireless communication network, and the wireless communication network set in the remote control means 800 may include Bluetooth, Wifi, LTE, It is preferable to set to 4G, 5G, or the like.

The remote control means 800 means a terminal that can install an application for controlling the indoor solar cell module 100 for installation, remotely control the indoor solar cell module 100 for installation remotely A signal may be input, and the indoor photovoltaic solar module 100 may receive the remote control signal from the remote control means 800 to control power of the motor unit and the auxiliary motor unit.

The present invention is not limited to the above-described embodiments, and the scope of application is not limited, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

100: rotating solar power module for indoor installation
200: support portion 210: vertical support portion
220: horizontal support
300: first rotating shaft 301: 1-axis connecting portion
400: solar power generation unit 410: solar cell
411: two-axis connecting portion 420: second axis of rotation
430: light collecting unit 440: cooling hole
500: cover portion 510: light collecting member
600: control unit 610: power control unit
620: battery unit 630: output unit
640: communication unit 650: display unit
700: Sunlight Detector
800: remote control means

Claims (11)

In the solar power module,
A first rotation shaft formed in a left and right longitudinal direction and connected to one side of the motor unit;
A polygonal photovoltaic power generation unit installed around the first rotation shaft and rotating along the rotation of the first rotation shaft, and having at least one solar cell having a predetermined length;
A second rotation shaft formed at the center of the solar power generation unit, connected to the first rotation shaft and the solar power generation unit to rotate the solar power generation unit, and one side connected to the auxiliary motor unit;
A support part supporting the first rotation shaft;
A control unit for storing energy generated by the solar power generation unit and controlling the operation of the solar power generation unit;
And a transparent cover part connected to the support part and protecting the first rotation shaft and the solar power generation part from the outside.
The solar power generation unit,
A one-axis connecting portion having one side connected to a longitudinal outer circumferential surface of the first rotating shaft and the other side connected to both ends of the second rotating shaft; And a biaxial connection part having one side connected to the longitudinal outer circumferential surface of the second rotation shaft and the other side connected to the solar cell.
delete The method of claim 1, wherein the solar cell,
A light collecting part attached to a surface of the solar cell;
Rotary solar power module for indoor installation, characterized in that further comprises.
The method of claim 3, wherein the light collecting unit,
A rotating solar module for indoor installation, characterized in that a plurality of Fresnel lenses or a plurality of convex lenses are formed on one transparent surface.
The method of claim 1, wherein the solar power generation unit,
Cooling hole to allow the outside air to enter the solar cell to cool the photovoltaic unit;
Rotary solar power module for indoor installation, characterized in that further comprises a.
The method of claim 1, wherein the support portion,
A vertical support part having one side connected to one side of the first rotation shaft to support the first rotation shaft; And
A horizontal support part connected to the other side of the first rotation shaft and seated on the ground;
Rotating solar power module for indoor installation, characterized in that comprises a.
The method of claim 1, wherein the control unit,
A power control unit controlling power of the motor unit connected to one side of the first rotation shaft and the auxiliary boter unit connected to one side of the second rotation shaft;
A battery unit storing electrical energy generated by the solar power generation unit; And
An output unit configured to output the power stored in the battery unit to the outside and be used;
Rotating solar power module for indoor installation, characterized in that comprises a.
The method of claim 7, wherein the control unit,
Receiving a control signal from an external device, calculating current information of the motor unit, the auxiliary motor unit, and the battery unit calculated by a predetermined algorithm, and controlling the power of the motor by a control signal received from the outside; Rotary solar power module for indoor installation.
According to claim 8, The indoor photovoltaic solar module for installation,
Remote control means connected to the control unit by using a preset wireless communication network to input a control signal to the control unit at a long distance;
It is configured to include more
The control unit rotates solar PV module for indoor installation, characterized in that for transmitting and receiving data using the remote control means and the wireless communication network.
The method of claim 1, wherein the cover portion,
A light collecting member attached to an outer surface of the cover part to collect sunlight;
Rotary solar power module for indoor installation, characterized in that further comprises.
The method of claim 10, wherein the light collecting member,
A rotating solar module for indoor installation, characterized in that a plurality of Fresnel lenses or a plurality of convex lenses are formed on one transparent surface.

Images