KR20230052817A - Rollable photovoltaic blind - Google Patents

Abstract

The present invention relates to a rollable solar blind that is suitable for preventing the curling of panel ends of a solar panel during repeated winding or unwinding of the solar panel. The rollable solar blind, according to the present invention, comprises: a solar module that is made of a sheet shape in appearance, has a plurality of solar cells, and is wound and unwound in one direction in the sheet shape; a secondary cell weight unit located at one end of the solar module at a right angle to the one direction of the sheet shape at the bottom of the solar module; and a rotation motor unit located at the other end of the solar module so as to be perpendicular to the one direction of the sheet shape at the top of the solar module. The solar module is electrically connected to the secondary cell weight unit and the rotation motor unit, and the rotation motor unit moves the secondary cell weight unit up and down with respect to the rotation motor unit while winding and unwinding the solar module.

Description

Rollable solar blind {ROLLABLE PHOTOVOLTAIC BLIND}

The present invention is located inside a building, exposed to sunlight, and generates DC current from a plurality of solar cells in a solar module while winding or unwinding the solar module, and uses the DC current to generate power to an electric load inside the building. It is about a rollable solar blind that supplies.

In general, a fabric blind opens and closes an opening of a building electrically according to a user's need to irradiate sunlight into the building through the opening of the building or block sunlight. Therefore, when the opening of the building is opened, the blind irradiates the interior of the building with sunlight to brighten the interior of the building, and when the opening of the building is closed, the blind blocks sunlight inside the building. Do not expose the inside of the

Here, the fabric blind requires a complicated wire related to external power supply to open and close the opening of the building by electric power, and the fabric in the fabric blind shows rapid aging over time. The complicated wires restrict users of fabric blinds from installing the fabric blinds inside the building, and the rapid aging of the fabric causes the user of the fabric blinds to gradually lose the initial aesthetic sense of the interior of the fabric blinds inside the building.

As an alternative to this, recently, the fabric blinds are being replaced by solar blinds. The solar blind is manufactured by including a plurality of solar cells. Here, the solar cell is a CIGS (Cu (copper) -In (indium) -Ga (gallium) -Se (selenium)) thin film as a light absorption layer on a flexible substrate (eg, stainless steel, plastic, ultra-thin glass, etc.) have The solar cell is utilized as a power source for buildings, automobiles, and wearable devices by additionally securing lightness, flexibility, and bending characteristics while maintaining high-efficiency photoelectric conversion characteristics.

Considering FIGS. 1 and 2 , the solar blind 30 according to the prior art is located inside a building and has a solar panel 10 and a motor accommodating part 20 . The solar panel 10 has a plurality of solar cells 8 . The motor accommodating part 20 receives DC current from the plurality of solar cells 8 and consumes power to the motor (not shown) while driving the motor along one direction D1. is repeatedly wound or unwound.

At this time, since the solar panel 10 is made of a harder material than fabric blinds in the plurality of solar cells 8, it is bent and rolled along the other direction D2 at the panel end 4. The panel end 4 covers some of the plurality of solar cells 8 in shade, preventing DC current from being produced from some of the solar cells 8, and consequently making some of the solar cells 8 a load that consumes power. Worse, it burns some solar cells (8).

In addition, when the plurality of solar cells 8 occupies a large occupied area in the solar panel 10, the motor accommodating part 20 consumes only a part of the direct current generated from the plurality of solar cells 8. Therefore, the building needs to install a storage battery for storing the remaining DC current in the power grid. The storage battery requires modifications to the initial design of the power grid in the building. On the other hand, the solar blind 30 is the title of the invention in Korean Patent Registration No. 10-1573058, "Electric Blind Using Photovoltaic Power Generation" and the name of the invention in Korean Patent Registration No. 10-1440588. A solar power generation unit for windows and a solar roll blind having the same is similarly disclosed as a prior art.

Korean Registered Patent Publication No. 10-1573058 Korean Registered Patent Publication No. 10-1440588

The present invention has been made to solve the conventional problems, and prevents the curling of the panel end of the solar panel during repeated winding or unwinding of the solar panel based on the motor accommodating part, and the initial design of the power grid in the building Its purpose is to provide a rollable solar blind suitable for continuous maintenance.

The rollable solar blind according to the present invention is made of a sheet shape when viewed from the outside, has a plurality of solar cells, and is wound and unwound along one direction in the sheet shape. optical module; A storage weight unit positioned at one end of the photovoltaic module so as to be perpendicular to the one direction of the sheet shape at the bottom of the photovoltaic module; and a rotation motor unit located at the other end of the solar module so as to be perpendicular to the one direction of the sheet shape on the top of the solar module, wherein the solar module is electrically connected to the storage weight unit and the rotation motor unit. The rotational motor unit is characterized in that the power storage weight unit is vertically moved with respect to the rotational motor unit while winding and unwinding the photovoltaic module.

The photovoltaic module is located inside the building and exposed to the outside of the building, and receives sunlight from the outside of the building to the individual solar cells to generate a first DC current.

The photovoltaic module has first and second circuit lines on one side of individual solar cells in the plurality of solar cells, and third and fourth circuit lines on the other side of individual solar cells in the plurality of solar cells. can have

When the photovoltaic module is located inside a building and irradiates individual solar cells with sunlight from the outside of the building to generate a first DC current, the first and second circuit lines are connected to the photovoltaic module. and the storage weight unit are electrically connected, and while forming a first potential difference at one side of the storage weight unit, the first DC current of the photovoltaic module may be supplied to the storage weight unit.

When the photovoltaic module supplies a first DC current to the storage weight unit through the first and second circuit lines, the third and fourth circuit lines electrically electrically connect the storage weight unit and the rotation motor unit. , and while forming a second potential difference on the other side of the storage weight unit, a second DC current may be supplied from the storage weight unit to the rotation motor part.

The plurality of solar cells are arranged along a matrix M * N (where the variable M or N is a positive integer greater than or equal to 1) in a two-dimensional plane, and are individually placed on the light absorbing layer CIGS (CuInGaSe; copper-indium-gallium-selenium). ) may include a thin film.

When the photovoltaic module has first and second circuit lines on one side of the individual solar cells and third and fourth circuit lines on the other side of the individual solar cells around the plurality of solar cells, the storage weight While accommodating a plurality of rechargeable batteries in a series or parallel connection state, the unit electrically electrically connects the high potential part of the first power supply plate near the outermost rechargeable battery on one side and the low potential part of the second power supply plate near the outermost rechargeable battery on the other side. The first and second circuit lines are electrically connected to the high potential part of the first power source plate near the outermost rechargeable battery on one side and the low potential part of the second power source plate near the outermost rechargeable battery on the other side, respectively. It may include a battery housing passing through the third and fourth circuit lines.

The battery housing may have a housing cover disposed at an end of the battery housing to replace the plurality of rechargeable batteries when the battery housing is opened or to shield the plurality of rechargeable batteries from the outside when the battery housing is closed. .

The rotating motor unit may include a fixing rod positioned along the other end of the photovoltaic module in contact with the other end of the photovoltaic module; A bobbin made of a cylinder and accommodating the fixing rod in a predetermined area around the cylinder and interlocking the fixing rod with the rotation of the cylinder to wind the solar module around the cylinder or release the solar module from the cylinder ( bobbin); a motor member having a diameter smaller than that of the bobbin and coupled to an inner wall of the bobbin to rotate the bobbin; and an exterior cover spanning the inside of the building while surrounding the bobbin.

The fixed rod forms an elliptical shape when viewed from the cut surface of the fixed rod, and is surrounded by the photovoltaic module when viewed from the cut surface of the fixed rod or positioned along the long axis of the ellipse in the elliptical shape of the fixed rod An end of the photovoltaic module may be fixed to one surface.

The bobbin may include a cylindrical body for winding or unwinding the photovoltaic module; a plurality of fitting protrusions positioned along an inner circumferential surface of the cylindrical body and engaged with the motor member; and one fitting groove body that is bent from an outer circumferential surface of the cylindrical body toward the inner circumferential surface to accommodate the fixing rod, and the cylindrical body may be rotated while the motor member is driven.

When the bobbin has a cylindrical body and a plurality of fitting protrusions and one fitting groove along the inner circumferential surface of the cylindrical body, the motor member may include a motor fixed to the cylindrical body; and a tubular rotation transmission body formed integrally with the rotating shaft of the motor and positioned along the inner circumferential surface of the cylindrical body to be coupled with the plurality of fitting protrusions and the one fitting groove body.

The rotation transmission body is engaged with the plurality of fitting protrusions and the one fitting groove body through a plurality of grooves or holes on the outer circumferential surface of the rotation transmission body, and is interlocked with the rotation of the rotation shaft of the motor to The cylinder can be rotated.

When the bobbin has a cylindrical body, and a plurality of fitting protrusions and one fitting groove on the cylindrical body, the exterior cover may be positioned along the length direction of the cylindrical body to cover the cylindrical body.

The rotational motor part spans the interior of a building as one, and the photovoltaic module electrically connects the storage weight unit and the rotation motor part through third and fourth circuit lines, and the rotation is performed by the storage weight unit. When suspended from the motor unit, the rotary motor unit may be electrically connected to the power grid of the building.

The rotary motor unit may have a convex-shaped connector at one end of an exterior cover in the rotary motor unit, and electrically connect the third and fourth circuit lines to the power grid of the building through the connector.

The rotary motor unit receives a second DC current from the storage weight unit through the third and fourth circuit lines to drive a motor in a motor member of the rotation motor unit, and the photovoltaic module rotates the rotation shaft of the motor. It is possible to wind or unwind the photovoltaic module by interlocking.

The power grid receives a second DC current from the storage weight unit to the inverter through the third and fourth circuit lines, converts the second DC current into an AC current in the inverter, and based on the AC current, the building It is possible to supply power to the electric load located inside the.

The photovoltaic module, the storage weight unit, and the rotation motor unit are formed as one unit and are repeatedly located based on the unit inside the building, and the third and fourth circuit lines of the photovoltaic module and the rotation The motor unit is electrically connected to each other through the fifth and sixth circuit lines, and when the photovoltaic module is suspended from the rotation motor unit by the storage weight unit, the plurality of rotation motor units are electrically connected to the power grid of the building. It can be.

The plurality of rotation motor units have a convex-shaped connector at one end of the individual rotation motor unit and a concave socket at the other end, and one rotation motor unit is selected from two neighboring rotation motor units among the plurality of rotation motor units. The aspect of electrically connecting the two neighboring rotation motor units by inserting the connection hole of another rotation motor unit into the socket hole, and located at the outermost part through the connection hole of the rotation motor unit located at the outermost part of the plurality of rotation motor units. The third and fourth circuit lines of the optical module and the fifth and sixth circuit lines of the outermost rotary motor unit may be electrically connected to the power grid of the building.

The individual rotation motor unit receives a second DC current from the individual storage weight unit through the third and fourth circuit lines of the individual solar module to drive the motor in the motor member of the individual rotation motor unit, and the rotation axis of the motor By interlocking the individual photovoltaic modules with rotation, the individual photovoltaic modules may be wound or unwound.

The power grid receives a second direct current supplied to the inverter from the individual storage weight unit through the third and fourth circuit lines of the individual photovoltaic module, converts the second direct current into an alternating current in the inverter, and converts the alternating current into an alternating current Based on this, power can be supplied to the electric load located inside the building.

The rollable solar blind according to the present invention,

A solar module and a storage weight unit that are sequentially positioned from the rotary motor unit under the rotation motor unit and the rotation motor unit that are electrically connected to each other by being spanned or spanned in plurality inside the building, and the solar module While electrically connecting the solar cells, the storage weight unit and the rotating motor to the power grid of the building through circuit lines,

The rechargeable batteries of the storage weighing unit are electrically connected to the solar cells of the photovoltaic module to store the first DC current generated from the solar cells in the rechargeable batteries, and a motor is provided in the rotating motor unit so that the motor is removed from the storage weighing unit. Since the second DC current is supplied to and the solar module is wound or unwound while the motor consumes power based on the second DC current,

Based on the rotating motor part, when the solar panel is repeatedly wound or unwound, the weight of the storage weight unit is used to prevent the end of the solar panel from being rolled up, and the first DC current generated from the solar cells in the solar module By storing in the storage weight unit, the initial design of the power grid can be maintained continuously without installing a separate storage battery in the power grid in the building.

1 and 2 are images showing a rollable solar blind according to the prior art.
3 is an image showing the coupling relationship between the rotation motor unit, the solar module, and the storage weight unit when the rollable solar blind according to the first embodiment of the present invention has one rotation motor unit.
Figure 4 is a cross-sectional view showing a partially enlarged storage weight unit in the rollable solar blind of Figure 3.
5 is a schematic diagram showing a partially enlarged rotary motor in the rollable solar blind of FIG. 3 .
Figure 6 is an image showing the electrical connection relationship between the rotary motor unit, the solar module and the storage weight unit to the power grid of the building in the rollable solar blind of FIG.
7 and 8 are images showing the coupling relationship between the rotation motor unit, the solar module, and the storage weight unit when the rollable solar blind has a plurality of rotation motor units according to a second embodiment of the present invention.
9 is an image showing the electrical connection relationship between the rollable solar blind of FIG. 3 or 8 and the power grid of the building.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention which follows refers to the accompanying drawings which illustrate, by way of example, specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable any person skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention in relation to one embodiment. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all equivalents as claimed by those claims. Similar reference numerals in the drawings indicate the same or similar functions in various aspects, and the length, area, thickness, and the like may be exaggerated for convenience.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily practice the present invention.

3 is an image showing the coupling relationship between the rotation motor unit, the solar module, and the storage weight unit when the rollable solar blind according to the first embodiment of the present invention has one rotation motor unit.

4 is a partially enlarged cross-sectional view of a storage weight unit in the rollable solar blind of FIG. 3 , and FIG. 5 is a schematic diagram showing a partially enlarged rotational motor in the rollable solar blind of FIG. 3 .

In addition, FIG. 6 is an image showing the electrical connection relationship between the rotational motor unit, the solar module, and the storage weight unit to the power grid of the building in the rollable solar blind of FIG. 3, and FIG. 9 is the rollable solar blind of FIG. 3 It is an image showing the electrical connection relationship between the building and the power grid of the building.

3 to 6 and 9, the rollable solar blind 154 according to the present invention includes a solar module 50, a power storage weight unit 70, and a rotation motor unit 144 includes When viewed schematically, the photovoltaic module 50, in FIGS. 3, 5, and 6, is made of a sheet shape when viewed from the outside and has a plurality of solar cells 45, and has a sheet shape in one direction. It is wound (捲取) and unwound (捲出) along.

The storage weight unit 70, in FIGS. 3, 5, and 6, is positioned at one end of the photovoltaic module 50 so as to be perpendicular to one direction of the sheet shape at the bottom of the photovoltaic module 50. The rotary motor unit 144 is located at the other end of the solar module 50 so as to be perpendicular to one direction of the sheet shape at the top of the solar module 50 in FIGS. 3 and 5 and 6 .

Here, the photovoltaic module 50 is electrically connected to the storage weight unit 70 and the rotation motor unit 144 in FIG. 6 . Considering FIGS. 3 and 5 and 6 , the rotary motor unit 144 vertically moves the storage weight unit 70 with respect to the rotation motor unit 144 while winding and unwinding the photovoltaic module 50 . let it

In more detail, considering FIGS. 6 and 9 , the photovoltaic module 50 is located inside the building (168 in FIG. 9) and exposed to the outside of the building 168, and the building 168 The individual solar cells 45 are irradiated with sunlight S from the outside to generate a first direct current.

In FIG. 6 , the photovoltaic module 50 has first and second circuit lines L1 and L2 on one side of the individual solar cells 45 in the plurality of solar cells 45, and a plurality of solar cells. At (45), third and fourth circuit lines (L3, L4) are provided on the other side of the individual solar cell (45).

6 and 9, when the photovoltaic module 50 is located inside a building and irradiates individual solar cells with sunlight from the outside of the building to generate a first DC current, the first DC current is generated. 4 and 6, the first and second circuit lines L1 and L2 electrically connect the photovoltaic module 50 and the storage weight unit 70, and are provided on one side of the storage weight unit 70. The first DC current of the photovoltaic module 50 is supplied to the storage weight unit 70 while forming a 1 potential difference.

When the photovoltaic module 50 supplies a first DC current to the storage weighing unit 70 through the first and second circuit lines L1 and L2 in FIG. 6, the third and fourth circuits In FIGS. 4 and 6, the lines L3 and L4 electrically connect the storage weight unit 70 and the rotary motor 144, and form a second potential difference on the other side of the storage weight unit 70. A second DC current is supplied from the storage weight unit 70 to the rotation motor unit 144.

3 and 6, the plurality of solar cells 45 are arranged along a matrix M * N (where the variable M or N is a positive integer greater than or equal to 1) in a two-dimensional plane, and individually light absorbing layers Including a CIGS (CuInGaSe; copper-indium-gallium-selenium) thin film.

The photovoltaic module 50, in FIGS. 4 and 6, first and second circuit lines (L1, L2) and individual solar cells on one side of the individual solar cells 45 around the plurality of solar cells 45 When having the third and fourth circuit lines L3 and L4 on the other side of the battery 45, the storage weight unit 70, in FIG. 4, accommodates a plurality of rechargeable batteries 65 in series connection. do. Alternatively, although not shown in the drawing, the storage weight unit 70 may accommodate a plurality of rechargeable batteries 65 in a parallel connection state, or accommodate a plurality of rechargeable batteries 65 in a series and parallel connection state. You may.

In addition, the storage weight unit 70, in FIG. 4, the high potential ((+) electrode) of the first power plate 61 near the outermost rechargeable battery 65 on one side and the outermost rechargeable battery 65 on the other side The first and second circuit lines L1 and L2 electrically connected to the low potential part ((-) electrode) of the second power plate 63 at close proximity, and the first and second circuit lines L1 and L2 near the outermost rechargeable battery 65 on one side. Third and third electrically connected to the high potential (+) electrode of the power source plate 61 and the low potential (-) electrode of the second power source plate 63 close to the outermost rechargeable battery 65 on the other side, respectively. It includes a battery housing 69 through which 4 circuit lines L3 and L4 pass.

The battery housing 69, in FIG. 4, is located at the end of the battery housing 69 to replace a plurality of rechargeable batteries 65 when the battery housing 69 is opened or when the battery housing 69 is closed. It has a housing cover 67 that shields the rechargeable battery 65 from the outside.

The rotary motor unit 144, in FIG. 5, includes a fixed bar 80, a bobbin 100, a motor member 120, and an exterior cover 134. The fixing bar 80, in FIG. 5, is positioned along the other end of the solar module 50 in contact with the other end of the solar module 50. The motor member 120 is made of a cylinder, accommodates the fixing rod 80 in a predetermined area around the cylinder, and winds the solar module 50 around the cylinder by interlocking the fixing rod 80 with the rotation of the cylinder. Unscrew the solar module from the

The motor member 120, in FIG. 5, has a smaller diameter than the bobbin 100 and is coupled to the inner wall of the bobbin 100 to rotate the bobbin 100. The exterior cover 134, in FIG. 5, covers the bobbin 100 and spans the inside of the building.

Specifically, the fixing bar 80, in FIG. 5, forms an elliptical shape when viewed from the cut surface of the fixing bar 50, and is surrounded by the photovoltaic module 50 when viewed from the cut surface of the fixing bar 50. The end of the photovoltaic module 50 is fixed to one surface positioned along the long axis of the ellipse in the shape of an ellipse or fixed bar 50.

The bobbin 100, in FIG. 5, is positioned along the inner circumferential surface of a cylindrical body 93 that winds or unwinds the solar module 50 and is coupled to the motor member 120. It includes a plurality of fitting protrusions 96 and one fitting groove 99 that is bent from the outer circumferential surface of the cylindrical body 93 toward the inner circumferential surface to accommodate the fixing rod 80. The cylindrical body 93 rotates while driving the motor member 120 .

When the bobbin 100, in FIG. 5, has a cylindrical body 93, and a plurality of fitting protrusions 96 and one fitting groove 99 along the inner circumferential surface of the cylindrical body 93, the motor member ( 120) is formed integrally with the motor 113 fixed to the cylindrical body 93 and the rotating shaft 116 of the motor 113 in FIG. (96) and a tubular rotation transmission body 119 coupled to one fitting groove 99.

The rotation transmission body 119 is coupled with a plurality of fitting protrusions 96 and one fitting groove 99 through a plurality of grooves or holes on the outer circumferential surface of the rotation transmission body 119, and a motor ( 113 rotates the cylindrical body 93 in conjunction with the rotation of the rotation shaft 116. When the bobbin 100, in FIG. 5, has a cylindrical body 93, and a plurality of fitting protrusions 96 and one fitting groove 99 on the cylindrical body 93, the exterior cover 134 5, it is located along the longitudinal direction of the cylindrical body 93 and wraps around the cylindrical body 93.

In FIGS. 3, 6, and 9, the rotary motor unit 144 spans the inside of the building 168 as one, and the photovoltaic module 50 is connected to the third and fourth circuit lines L3. , L4) to electrically connect the storage weight unit 70 and the rotation motor unit 144, and when suspended from the rotation motor unit 144 by the storage weight unit 70, the rotation motor unit 144 is electrically connected to power grid 164 of building 168 in FIGS. 6 and 9 .

5 and 6 and 9, the rotation motor unit 144 has a convex-shaped connection port 131 at one end of the exterior cover 134 in the rotation motor unit 144, and the connection port 131 Through this, the third and fourth circuit lines L3 and L4 are electrically connected to the power grid 164 of the building 168.

In addition, considering FIGS. 4 to 6 , the rotary motor unit 144 is supplied with a second DC current from the electric storage weighing unit 70 through the third and fourth circuit lines L3 and L4 to rotate the motor. The motor 113 is driven in the motor member 120 of the unit 144, and the solar module 50 is interlocked with the rotation of the rotating shaft 116 of the motor 113 to wind or unwind the solar module 50. give.

Considering FIGS. 6 and 9 , the power grid 164 receives the second DC current from the storage weighing unit 70 to the inverter 162 through the third and fourth circuit lines L3 and L4, and the inverter In 162, the second DC current is converted into an AC current, and power is supplied to the electric load 166 located inside the building 168 based on the AC current.

7 and 8 are images showing the coupling relationship between the rotation motor unit, the solar module, and the storage weight unit when the rollable solar blind according to the second embodiment of the present invention has a plurality of rotation motor units, and FIG. 9 is It is an image showing the electrical connection relationship between the rollable solar blind of FIG. 8 and the power grid of the building.

In this case, FIGS. 7 and 8 use the same reference numerals for the same members as those in FIGS. 3 to 6 whenever possible.

Referring to FIGS. 7 and 8 and again to FIG. 9 , the rollable solar blind 158 has a structure similar to that of the rollable solar blind 154 of FIG. 3 , but the rollable solar blind 158 The number of rotation motor units 148 of ) is different from the number of rotation motor units 144 of the rollable solar blind 154 of FIG. 3 inside the building 168 when considering FIG. 8 .

That is, in the rollable solar blind 158, the solar module 50, the storage weight unit 70, and the rotation motor unit 148, considering FIGS. 8 and 9, are made of one unit. It is repeatedly located on the basis of one unit inside the building 168, and considering FIGS. 7 and 8, the third and fourth circuit lines L3 and L4 of the solar module 50 and the rotation motor The fifth and sixth circuit lines L5 and L6 of the unit 148 are electrically connected to each other, and the photovoltaic module 50, as shown in FIG. 7, rotates the motor unit by the storage weight unit 70 ( When suspended from 148 , the plurality of rotary motor units 148 , considering FIGS. 8 and 9 , are electrically connected to a power grid 164 of the building 168 .

Considering FIGS. 7 and 8 , the plurality of rotary motor units 148 have a convex shape connector 131 at one end of the exterior cover 1380 and a concave shape at the other end of the individual rotation motor unit 148. has a socket sphere 132, and one rotation motor unit is connected to the socket sphere 132 of one rotation motor unit 148 in two neighboring rotation motor units 148 among a plurality of rotation motor units 148 The connector 131 of (148) is inserted to electrically connect the two adjacent rotation motor units 148, and the connection port of the rotation motor unit 148 located at the outermost part of the plurality of rotation motor units 148 ( 131) through the third and fourth circuit lines (L3, L4) of the solar module 50 located on the outermost and fifth and sixth circuit lines (L5) of the rotary motor unit 138 located on the outermost , L6) is electrically connected to the power grid 164 of the building 168.

Considering FIGS. 7 and 8 , the individual rotation motor unit 148 is removed from the individual power storage weight unit 70 through the third and fourth circuit lines L3 and L4 of the individual solar module 50. 2 Receive DC current to drive the motor (see 113 in FIG. 5) in the motor member (see 120 in FIG. 5) of the individual rotation motor unit 148, and drive the rotation shaft (see 116 in FIG. 5) of the motor 113. The individual solar modules 50 are interlocked with the rotation of the yaw) to wind or unwind the individual solar modules 50.

The power grid 164, considering FIGS. 8 and 9, the inverter 162 from the individual storage weight unit 70 through the third and fourth circuit lines L3 and L4 of the individual solar module 50 The inverter 162 receives the second DC current, converts the second DC current into AC current, and supplies power to the electric load 166 located inside the building 168 based on the AC current.

45; solar cell, 50; Solar modules
63; battery housing, 70; storage weight unit
131; access port, 134; exterior cover
144; rotation motor unit, 154; rollable solar blinds
162; inverter, 164; power grid
L1-L4; circuit line

Claims (22)

A photovoltaic module that is externally formed in a sheet shape, has a plurality of solar cells, and is wound and unwound along one direction in the sheet shape;
A storage weight unit positioned at one end of the photovoltaic module so as to be perpendicular to the one direction of the sheet shape at the bottom of the photovoltaic module; and
And a rotation motor located at the other end of the photovoltaic module so as to be perpendicular to the one direction of the sheet shape from the top of the photovoltaic module,
The solar module,
Electrically connected to the storage weight unit and the rotation motor unit,
The rotary motor unit,
A rollable solar blind that moves the storage weight unit up and down with respect to the rotary motor unit while winding and unwinding the solar module.
According to claim 1,
The solar module,
A rollable solar blind that is located inside a building and exposed to the outside of the building, and generates a first direct current by receiving sunlight from the outside of the building to individual solar cells.
According to claim 1,
The solar module,
In the plurality of solar cells, first and second circuit lines are provided on one side of each individual solar cell,
A rollable solar blind having third and fourth circuit lines on the other side of each individual solar cell in the plurality of solar cells.
According to claim 3,
the solar module,
When located inside the building and irradiated with sunlight from the outside of the building to the individual solar cells to generate a first direct current,
The first and second circuit lines,
Electrically connecting the photovoltaic module and the storage weight unit,
A rollable solar blind that supplies the first DC current of the solar module to the storage weight unit while forming a first potential difference at one side of the storage weight unit.
According to claim 3,
the solar module,
When supplying a first direct current to the storage weight unit through the first and second circuit lines,
The third and fourth circuit lines,
Electrically connecting the storage weight unit and the rotation motor unit,
While forming a second potential difference to the other side of the storage weight unit, the rollable solar blind supplies a second direct current to the rotation motor unit from the storage weight unit.
According to claim 1,
The plurality of solar cells,
Arranged along a matrix M * N in a two-dimensional plane (provided that the variable M or N is a positive integer greater than or equal to 1),
A rollable solar blind comprising a CIGS (CuInGaSe; copper-indium-gallium-selenium) thin film on an individual light absorbing layer.
According to claim 1,
the solar module,
When having first and second circuit lines on one side of the individual solar cells and third and fourth circuit lines on the other side of the individual solar cells around the plurality of solar cells,
The storage weight unit,
While accommodating a plurality of rechargeable batteries in a series or parallel connection state,
The first and second circuit lines electrically connected to the high potential part of the first power source plate near the outermost rechargeable battery on one side and the low potential part of the second power source plate near the outermost rechargeable battery on the other side, respectively, and the outermost charge on the one side A battery housing passing through the third and fourth circuit lines electrically connected to the high potential portion of the first power source plate near the battery and the low potential portion of the second power source plate near the other outermost rechargeable battery, respectively , rollable solar blinds.
According to claim 7,
The battery housing,
A rollable solar blind having a housing cover positioned at an end of the battery housing to replace the plurality of rechargeable batteries when the battery housing is opened or to shield the plurality of rechargeable batteries from the outside when the battery housing is closed.
According to claim 1,
The rotary motor unit,
a fixing rod positioned along the other end of the photovoltaic module in contact with the other end of the photovoltaic module;
A bobbin made of a cylinder and accommodating the fixing rod in a predetermined area around the cylinder and interlocking the fixing rod with the rotation of the cylinder to wind the solar module around the cylinder or release the solar module from the cylinder ( bobbin);
a motor member having a diameter smaller than that of the bobbin and coupled to an inner wall of the bobbin to rotate the bobbin; and
A rollable solar blind comprising an exterior cover spanning the inside of a building while surrounding the bobbin.
According to claim 9,
The fixed bar,
Forming an elliptical shape when viewed from the cut surface of the fixing rod,
A rollable solar blind fixing an end of the solar module to a surface surrounded by the solar module as viewed from the cut plane of the fixing rod or located along the long axis of the ellipse in the elliptical shape of the fixing rod. .
According to claim 9,
The bobbin,
a cylindrical body for winding or unwinding the photovoltaic module;
a plurality of fitting protrusions positioned along an inner circumferential surface of the cylindrical body and engaged with the motor member; and
It includes one fitting groove that is bent from the outer circumferential surface of the cylindrical body toward the inner circumferential surface to accommodate the fixing rod,
The cylindrical body,
A rollable solar blind that rotates during driving of the motor member.
According to claim 9,
the bobbin,
When having a cylindrical body and a plurality of fitting protrusions and one fitting groove along the inner circumferential surface of the cylindrical body,
The motor member,
a motor fixed to the cylindrical body; and
A rollable solar blind comprising a tubular rotation transmission body integrally formed with the rotation shaft of the motor and positioned along the inner circumferential surface of the cylindrical body to engage the plurality of fitting protrusions and the one fitting groove body.
According to claim 12,
The rotating transmission body,
Coupled with the plurality of fitting protrusions and the one fitting groove body through a plurality of grooves or holes on the outer circumferential surface of the rotation transmission body,
A rollable solar blind that rotates the cylindrical body in conjunction with the rotation of the rotation shaft of the motor.
According to claim 9,
the bobbin,
A cylindrical body, and when the cylindrical body has a plurality of fitting protrusions and one fitting groove body,
The exterior cover,
A rollable solar blind that is positioned along the length direction of the cylindrical body and surrounds the cylindrical body.
According to claim 1,
The rotary motor part,
It spans the interior of the building as one,
the solar module,
Electrically connecting the storage weight unit and the rotary motor through third and fourth circuit lines,
When suspended from the rotary motor unit by the storage weight unit,
The rotary motor unit,
Rollable solar blinds that are electrically connected to the building's power grid.
According to claim 15,
The rotary motor unit,
The rotary motor unit has a convex-shaped connector at one end of the exterior cover,
Electrically connecting the third and fourth circuit lines to the power grid of the building through the connection port, the rollable solar blind.
According to claim 15,
The rotary motor unit,
Receiving a second DC current from the storage weight unit through the third and fourth circuit lines to drive a motor in the motor member of the rotary motor unit,
A rollable solar blind that winds or unwinds the solar module by interlocking the solar module with the rotation of the rotating shaft of the motor.
According to claim 15,
The power grid,
A second DC current is supplied to the inverter from the storage weight unit through the third and fourth circuit lines, the inverter converts the second DC current into an AC current, and based on the AC current, the inside of the building A rollable solar blind that supplies power to the electrical load it is placed on.
According to claim 1,
The photovoltaic module, the storage weight unit and the rotating motor unit,
It consists of one unit and is repeatedly located inside the building based on the unit,
Electrically connected to each other through the third and fourth circuit lines of the photovoltaic module and the fifth and sixth circuit lines of the rotary motor unit,
the solar module,
When suspended from the rotary motor unit by the storage weight unit,
A plurality of rotary motors
Rollable solar blinds that are electrically connected to the building's power grid.
According to claim 19,
The plurality of rotary motor units,
It has a convex-shaped connector at one end of the individual rotation motor unit and a concave socket at the other end,
Electrically connecting the two adjacent rotation motor units by inserting a connection hole of another rotation motor unit into a socket sphere of one rotation motor unit in two neighboring rotation motor units among the plurality of rotation motor units,
The third and fourth circuit lines of the photovoltaic module located at the outermost part through the connection hole of the rotary motor unit located at the outermost part of the plurality of rotation motor units and the fifth and sixth circuit lines of the rotation motor unit located at the outermost part electrically connected to the power grid of the building, rollable solar blinds.
According to claim 19,
The individual rotation motor unit,
Receiving a second DC current from the individual storage weight unit through the third and fourth circuit lines of the individual photovoltaic module to drive the motor in the motor member of the individual rotation motor unit,
A rollable solar blind that winds or unwinds the individual solar modules by interlocking the individual solar modules with the rotation of the rotating shaft of the motor.
According to claim 19,
The power grid,
The second DC current is supplied to the inverter from the individual storage weight unit through the third and fourth circuit lines of the individual photovoltaic module, the inverter converts the second DC current into an AC current, and the building based on the AC current Rollable solar blinds that supply power to an electrical load located inside the.

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