KR20220168374A - Project type window system - Google Patents

Abstract

The present invention relates to a window system that improves airtightness between tilted solar panels. The project window system according to the present invention comprises: a window frame (10); a project frame (20) whose upper end is hinged to the upper end of the window frame (10) and whose lower end is opened and closed in a project manner by moving away from or approaching the window frame (10); a louver frame (30) provided inside the project frame (20); and a solar panel (40) consisting of a solar cell (41) and a solar cell frame (42) supporting the solar cell (41). The thickness of both ends (A) forming the width of the solar cell frame (42) is formed to be thinner than the thickness of the solar panel (40). A slit (42-5) and a protrusion (42-6) are formed at both ends (A) so that when the solar panel (40) is closed, the adjacent protrusion (42-6) of the solar panel (40) is inserted into the slit (42-5) of the solar panel (40).

Description

Project window system {PROJECT TYPE WINDOW SYSTEM}

The present invention relates to a window that is opened and closed in a project method, and more particularly, to a window system with improved airtightness between tilted solar panels.

As greenhouse gas reduction becomes a major issue around the world, measures to reduce greenhouse gas are emerging one after another. One of these measures is to install solar panels on buildings or to include solar panels on parts of buildings in order to reduce the use of fossil energy. It can be divided into building integrated photovoltaic system (building integrated photovoltaic system).

However, in the case of BIPV, since it must serve as a building material for a building while performing a power generation function, there is a problem that it must be customized according to the installation environment. .

In order to solve this problem, the present inventor invented a window for a photovoltaic power generation system in which the solar panel is tilted while the window is opened and closed in a project method, so that it can be affected as little as possible by the irradiation angle or shade of sunlight, and 'Patent Document 1 ' has a patent.

1 shows a conventional project opening and closing type BIPV system, which includes a first frame 1 installed on an external window frame of a building and a second frame coupled to the first frame 1 ( 3) and a solar cell module 5 composed of a plurality of solar panels and installed inside the second frame 3, the second frame 3 performs opening and closing of the project method, and the solar cell module The solar panel at (5) is tilted to maximize power production efficiency.

Conventional project opening/closing type BIPV systems have a problem in that the solar panel is composed of only solar cells and a frame supporting the cells, and thus, when the solar panel is closed, watertightness and external air blocking effect are poor.

KR 10-1922890 B1 (2018. 11. 22.)

The present invention has been made to solve the above problems, the problem to be solved by the present invention is to provide a project window system with excellent watertightness and external air blocking performance.

A project window system according to the present invention includes a window frame; A project frame whose upper end is hinged to the upper end of the window frame and whose lower end is opened and closed in a project manner as it moves away from or approaches the window frame; A project window system composed of a solar panel composed of a louver frame provided inside the project frame and a solar cell and a solar cell frame supporting the solar cell, wherein the thickness of both ends constituting the width of the solar cell frame is It is formed thinner than the thickness of the solar panel, and slits and protrusions are formed at both ends, respectively, so that when the solar panel is closed, the protrusions of the adjacent solar panels are inserted into the slits of the solar panel. do.

The project window system according to the present invention has high airtightness because the slit and the protrusion are fitted and sealed between the solar panels when the solar panels are closed.

1 is a conventional project opening and closing method BIPV system
Figure 2 is a perspective view of a project window system according to the present invention
3 is a combined structure of a project frame, a louver frame and a solar panel
Figure 4 is a schematic diagram showing a form in which wires are wired as a whole in the present invention
5 is a coupling structure of a louver frame and a solar panel
6 is an operating state diagram of a louver frame and a solar panel
7 is a coupling structure in which a solar cell frame is coupled to a louver frame
8 is a form in which a solar cell frame is coupled to a louver frame
9 is another embodiment of a louver frame
10 is an operating state diagram of another embodiment of a louver frame and a solar panel
11 is an exploded perspective view of a solar panel
12 is a cross-sectional view of a solar cell frame
13 is a cross-sectional view when the solar panel is tilted and closed
14 is an embodiment in which an index rubber is inserted into a solar cell frame

Hereinafter, a project window system according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view of a project window system according to the present invention, the project window system according to the present invention includes a window frame 10, a project frame 20 that is opened and closed in a project manner with respect to the window frame 10, and a project frame 20 ) Consisting of a louver frame 30 provided on the inside and a solar panel 40 coupled to and tilted to the louver frame 30, a project cylinder for opening and closing the project frame 20 with respect to the window frame 10 50 and a tilt cylinder 60 for tilting the solar panel may be further provided.

The window frame 10 is a component that forms the outermost part of the project window system according to the present invention and is installed in a building so that the project window system according to the present invention can function as a window. A threshold 11 protruding to the inside of the window frame 10 is provided so that when the project frame 20 is closed, watertightness and external air blocking are possible.

The project frame 20 is a component that opens and closes in a project manner as its upper end is hinged to the upper end of the window frame 10 and its lower end moves away from or close to the window frame 10 .

3 is a partially exploded perspective view showing a combined structure of a project frame, a louver frame and a solar panel, the project frame 20 is an upper cover forming a quadrangular frame so that the louver frame 30 can be provided inside ( 21), a side cover 22, a lower cover (not shown), a duct 23 coupled to the outside of the side cover 22 to be a moving passage of wires, and a project frame 20 coupled to the upper cover 21 It consists of a hinge bar 24 that enables rotation, and wire holes 25 are formed in the upper cover 21, the side cover 22, the duct 23, and the hinge bar 24. Due to this structure, the project window system according to the present invention passes the wires connected to the solar panel 40 through the duct 23, the side cover 22, the top cover 21, and the hinge bar 24 to the external device. It is possible to wire through the hole 25, and transmit the power generated by the solar panel 40 to the outside of the project window system according to the present invention, for example, an inverter or a power storage device.

4 is a schematic diagram showing a form in which wires are wired as a whole in the present invention. Considering an inverter voltage of several tens of V, a plurality of solar panels 40 outputting a voltage of several V should be connected in series by wires (W). . In addition, both ends of the wire (W) connected in series must be connected to an external device. Due to the nature of project operation of the project frame 20, the distance between the project frame 20 and the window frame 10 increases. Since the wiring becomes difficult and the electric wire (W) has a problem of being caught between the window frame 10 and the project frame 20, in the configuration as in the present invention, the electric wire (W) is the project frame 20 is the window frame 10 ).

5 shows a coupling structure between a louver frame and a solar panel, FIG. 6 is an operating state diagram of a louver frame and a solar panel, and FIG. 7 shows a coupling structure in which a solar cell frame is coupled to a louver frame, Figure 8 is the combined form {because it is coupled to the louver frame 30 is the solar cell frame 42, Figs. 7 and 8 show a solar cell frame instead of a solar panel. The solar cell frame 42 is a component of the solar panel 40}. The louver frame 30 is a component provided inside the project frame 20 to enable the solar panel 40 to be tilted, and the louver frame includes a support plate 31, a panel holder 32, a socket 33, a tilt Consists of a strip (34).

The support plate 31 is a plate-shaped component that is formed long in the height direction of the project frame 20, and the tilt hole 31-1 is located at a position corresponding to the axis on which the solar panel 40 is tilted. 40), and is provided one by one on both sides of the solar panel 40. The reason why the tilt hole 31-1 is required is that the solar panel 40 can be rotated in the louver frame 30 only when the rotating shaft provided in the solar panel 40 comes out of the support plate 31.

The panel holder 32 is a component that fixes and holds the solar panel 40 on the inside of the support plate 31, and has a tilt axis 32-1 on the opposite side where the solar panel 40 is gripped. A wire hole 32-2 is formed in the center of the shaft 32-1. When the panel holder 32 is cross-sectionally viewed in the direction of gripping the solar panel 40, one end 32-3 is open, and the other end 32-4 is partially open with a locking jaw 32-5 formed thereon. It has a shape, and a bolt hole 32-6 is formed at one end 32-3 that is open. This is to facilitate coupling and separation of the solar panel 40 and will be described again later.

The socket 33 is coupled to the tilt axis 32-1 of the panel holder 32 from the outside of the support plate 31, so that the solar panel 40 is tiltably supported on the louver frame 30. At the same time, a wire hole 33-1 is formed in the center, so that the solar panel 40 and the electric wire W provided in the project frame 20 and the like can be electrically connected through the socket 33. The reason why the wire (W) needs to be connected through the socket 33 located on the rotating shaft of the solar panel 40 is the same as the case described in FIG. 4 above as an example. The socket 33 is provided with one or more protrusions 33-2.

In the tilt strip 34, a hole 34-1 is formed at a position corresponding to the protrusion 33-2 of the socket 33 so that the protrusion 33-2 provided on the socket 33 is vertically installed, that is, the project frame. It is a component that connects in the height direction of (20). Therefore, the tilt strip 34 is provided on both sides of the solar panel 40 by the number of protrusions 33-2 formed on the socket 33. The socket 33 may have one protrusion 33-2 and one tilt strip 34, but if the frictional force for the tilt movement is different for each solar panel 40, the solar panel 40 Difficult to tilt smoothly. Therefore, it is preferable to include two protrusions 33-2 on the socket 33 and two tilt strips 34 so as to be tilted as if a mating force is applied. The tilt strip 34 is not fixed to the protrusion 33-2 but is provided in a state of being rotatably fitted with respect to the protrusion 33-2. Accordingly, the solar panel 40 may be tilted simultaneously by moving the tilt strip 34 up and down.

However, when the tilt strip 34 is provided with two per side of the louver frame 30, since the electric wire W passes between the tilt strips 34, the solar panel 40 is completely open or completely closed {socket ( Depending on the formation position of the protrusion 33-2 in 33), the wire may be caught when it is opened or the wire may be caught when it is closed}, as shown in FIG. 6 (b), the wire (W ) may cause problems. 9 is another embodiment of the louver frame, in which two concave portions 34-2 are formed on opposite surfaces of a pair of tilt strips 34, respectively. In FIG. 9, the concave portion has a semicircular shape, and as shown in FIG. 10, the concave portion 34-2 of the tilt strip 34 facing the solar panel 40 is tilted so as to surround the wire W and function like a wire hole. will do Accordingly, it is possible to prevent the wires from being pinched, which occurs in the configurations of FIGS. 5 and 6, and accordingly, concerns about failures such as disconnection and electric leakage are significantly reduced.

11 is an exploded perspective view of a solar panel (for convenience of description, the panel holder 32 is shown together). The solar panel 40 is composed of a solar cell 41 and a solar cell frame 42 supporting the solar cell 41, and the solar cell 41 is connected to the solar cell frame 42 with a wire (W). A connector 43 is provided to do so.

Both ends (A) forming the width of the solar cell frame 42 are formed with a thickness thinner than the thickness of the solar panel 40, preferably 1/2, so that the cross section of the end is as if a flat plate was slightly bent. The reason for this is that when the solar panel 40 is completely closed by tilting, both ends of the adjacent solar panels overlap so that the closed solar panel surface is close to the plane.

As shown in FIG. 12, a plurality of solar cell frames 42, preferably three or more, are separately configured. This is related to manufacturing problems and ease of change in solar cell panel specifications. First, looking at the manufacturing problem, when manufacturing the solar cell frame 42 by extrusion, when the width of the solar cell panel is large, the extrusion cross-sectional area of the solar cell frame 42 is widened, so equipment having a high extrusion force must be used. Such equipment is difficult to obtain, and even if obtained, it is expensive. In order to use general extrusion equipment, the extrusion cross-sectional area cannot be increased. In this case, the solar cell frame 42 can be made thin (not the entire thickness of the solar cell frame 42, but the thickness of the thin plate forming the solar cell frame 42). There is a problem that the solar cell frame 42 is easily crushed by an external force or has poor durability because there is only one (because the thickness of the thin plate must be reduced in order to increase the width while maintaining the extruded cross-sectional area). If the solar cell frame 42 is separately configured into a plurality of pieces as shown in FIG. 12, each of the separately configured parts 42-1, 42-2, and 42-3 can be extruded with general extrusion equipment, so that the solar cell frame 42 You don't have to sacrifice strength and durability. The ease of changing the solar cell panel specifications means that even if the width of the solar cell 41 is changed to 10 cm, 15 cm, 20 cm, etc., only the separated central portion 42-2 can be changed. That is, when manufacturing products having different widths of the solar cell 41, there is no need to prepare an extrusion mold for each width of the solar cell 41, and only three or more separate extrusion molds of the middle part 42-2 are separately manufactured. The extrusion molds on both sides (42-1, 42-3) separated from each other can be used as they are, so it is easy to respond even if the solar cell panel specifications are changed. The rib 42-4 is formed in the central portion 42-2 of the solar cell frame 42 to help prevent deformation against external force.

It is preferable that the connector 43 is disposed so that the terminal side faces the outside of the solar panel 40 in the longitudinal direction, that is, the panel holder 32 . This is to easily separate the solar panel 40 from inside the building. If the terminal of the connector 43 faces the inside of the solar panel 40 in the longitudinal direction, the wire W connected to the connector 43 is the shortest route. It is connected to the outside through the low panel holder 32, and therefore, when trying to separate the solar panel 40 from the panel holder 32, there is no margin in the length of the electric wire W, so the solar panel 40 can be easily moved indoors. (In the direction of the arrow in FIG. 9) it cannot be pulled out. On the other hand, in the case of the configuration shown in FIG. 11, the solar panel 40 is removed from the panel holder 32 because the wire W is inside while forming a certain degree of curvature to connect the wire W to the connector 43. When trying to make a curvature and go inside (about B in FIG. 11), there is room, so maintenance such as solar cell 41 or connector 43 replacement is possible by separating the solar panel from the room.

It will be described with reference to FIGS. 7 and 8 again. The solar cell frame 42 is slide-inserted through the open end 32-3 of the panel holder 32, and is supported by the hook 32-5 of the other end 32-4 of the panel holder 32. Thereafter, the solar cell frame 42 is coupled to the panel holder 32 at the other end 32-4 of the panel holder 32 by means of fastening means. If the fastening means is a bolt 35, a bolt hole 32-6 is formed in the panel holder 32, and the solar cell frame 42 is coupled to the panel holder 32 through the bolt hole 32-6. In the present invention, the reason why the holding jaw 32-5 is formed by partially opening the other end 32-4 of the panel holder 32 is related to the ease of separation and coupling of the solar panel 40 described above. Since the project window system according to the present invention is difficult to separate once installed in a building, it is often repaired or replaced by separating only the solar panel 40. Therefore, it is necessary to be able to easily take out the solar panel 40 from indoors. If bolts are coupled at both sides of the panel holder 32 (outdoor side and indoor side when tilted open), it is very difficult to loosen the outdoor side bolts. On the other hand, as shown in FIG. 7, if the outdoor side is supported by the locking jaw 32-5 and the indoor side is fixed with bolts 35, etc., only the indoor bolt 35 is loosened and the solar panel 40 can be easily pulled out into the interior.

13 is a cross-sectional view when the solar panel is tilted and closed. When completely closed, the solar cell frames 42 of the adjacent photovoltaic panels 40 come into contact with slits 42-5 at both ends A forming the width of the solar cell frame 42 so that watertightness and external air disconnection are possible. ) and the protrusion 42-6 are formed so that the protrusion 42-6 is inserted into the slit 42-5 of the adjacent solar panel 40. 14 shows an embodiment in which an index rubber is inserted into a solar cell frame, and gripping parts 42-7 are formed along the length at both ends (A) of the solar cell frame 42, and the gripping parts ( If a long water stop rubber 44 is inserted into 42-7) so that the water stop rubber 44 is compressed to each other when adjacent solar cell frames 42 come into contact with each other, a higher watertightness and external air isolation effect can be seen.

The project cylinder 50 is installed between the window frame 10 and the project frame 20 so that the project frame 20 can open and close the project with respect to the window frame 10.

The tilt cylinder 60 is installed between the project frame 20 and the louver frame 30 so that the solar panel 40 connected to the louver frame 30 can tilt open and close with respect to the project frame 20.

10 window frame 11 threshold
20 Project frame 21 Top cover
22 side cover 23 duct
24 Hinge bar 25, 32-2, 33-1 wire hole
30 Louver frame 31 Support plate
31-1 Tilt Hole 32 Panel Holder
32-1 Tilt Axis 32-3 One End of Panel Hold
32-4 Other end of panel hold 32-5 Jaw
32-6 bolt hole 33 socket
33-2 projection 34 tilt strip
34-1 hole 35 volt
40 solar panel 41 solar cell
42 Solar cell frame 43 Connector
50 project cylinder 60 tilt cylinder

Claims (2)

window frame 10;
A project frame (20) whose upper end is hinged to the upper end of the window frame (10) and whose lower end is opened and closed in a project manner while moving away from or closer to the window frame (10);
A louver frame 30 provided inside the project frame 20 and
A project window system composed of a solar panel 40 composed of a solar cell 41 and a solar cell frame 42 supporting the solar cell 41,
The thickness of both ends (A) forming the width of the solar cell frame 42 is formed thinner than the thickness of the solar panel 40,
A slit 42-5 and a protrusion 42-6 are formed at both ends A, respectively, so that when the solar panel 40 is closed, the slit 42-5 of the solar panel 40 Project window system, characterized in that the protrusion (42-6) of the adjacent solar panel (40) is inserted.
The method of claim 1,
Grippers 42-7 are formed at both ends (A) of the solar cell frame 42, and water stop rubbers 44 are inserted into the grippers 42-7 so that adjacent solar cell frames 42 The project window system, characterized in that the index rubber (44) is compressed to each other when in contact.

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