JP2010144456A - Installation structure for solar cell panel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an installation structure for a solar panel allowing the adjustment of the installation inclination angle of the solar cell panel for efficiently taking in solar light according to seasons or the like and exhibiting a sun-shade effect for a window. <P>SOLUTION: The installation structure of a solar cell panel 1 having a square shape is installed above the window 4 formed in a wall face 5 so as to serve also as a window roof. The solar cell panel can be selectively switched between a first using state and a second using state. In the first using state, the rear face 1d of the solar cell panel is set along the wall face above the window, while the bottom side 1b of the solar cell panel is set in the vicinity of the top 4a of the window. In the second using state, the solar cell panel is inclined downward, while the top side 1a of the solar cell panel is positioned downward from the position of the top side in the first using state. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a solar cell panel mounting structure that is mounted above a window provided on a wall surface so as to also serve as a ridge of the window.

2. Description of the Related Art Conventionally, solar cell panel mounting structures that convert sunlight into electric energy to generate electric power are known that are mounted above the roof, roof, or window of a building.
However, since the solar radiation angle varies depending on the season and time, there has been a problem that solar light cannot be taken in efficiently if the installation angle of the solar cell panel is fixed.

Therefore, Patent Document 1 below describes a solar cell panel mounting structure that is mounted so as to double as a window ridge above a window provided on a wall surface, which shields sunlight from the daylighting part of the building. There is disclosed a solar cell panel attached to a shield which is disposed at a position and whose inclination angle is adjustable.
According to this, it is said that the light receiving posture can be adjusted at an optimum angle with respect to the solar radiation angle of the sun that changes depending on the season and time.
JP 2000-204735 A

  However, since the shaft for supporting the shield is fixed in the device described in the above-mentioned Patent Document 1, the lower the inclination angle of the shield, the farther from the upper part of the window. Therefore, when the inclination angle of the shielding body is made gentle, it is not possible to expect an effect as a ridge that blocks sunlight. Especially in the summer, it is known that the amount of power generation is increased by taking in sunlight with a gentler inclination angle of the shield. It will be.

Further, Patent Document 1 describes that when the shielding body is housed, it is turned downward and substantially parallel to the wall surface. However, as shown in Patent Document 1 and FIG. 2, a shield is covered above the window, and a part of the window is blocked by the shield.
Therefore, in order to prevent this, it is conceivable to arrange the shaft of the shield further above the position in the figure so that the window is not blocked when the shield is stored.
However, also in this case, the shield is separated from the upper part of the window, and the shade cannot be exhibited when the shield is used.
Further, Patent Document 1 also describes that when the shielding body is housed, the shielding body is rotated upward and housed so that the side on which the solar cell panel is attached follows the wall surface side.
In this case, a part of the window is not blocked, but the solar cell panel is disposed on the wall surface side, so that it is not possible to take in sunlight when it is in the housed state.

  The present invention has been made in view of the above circumstances, and provides a solar cell panel mounting structure capable of efficiently taking in sunlight according to the season and the like while exhibiting the sunshade effect of the window.

  In order to solve the above-mentioned problems, the solar cell panel mounting structure according to the present invention is desired in a first use state in which the solar cell panel is substantially parallel to the wall surface, and the solar cell panel is desired with respect to a horizontal plane. The second use state inclined at an angle can be used separately. In the first use state, the back surface of the solar cell panel is attached to the upper wall surface of the window, and the lower side of the solar cell panel is located above the window. The solar cell panel is inclined downward and the upper side portion of the solar cell panel is below the position of the upper side portion in the first use state in the second use state. It is comprised so that it may be located in.

In the present invention, two vertical frames spaced at a predetermined interval according to the width dimension of the solar cell panel are fixed substantially parallel to the upper wall surface of the window, and the vertical frame is slit in the longitudinal direction thereof. A support bar pivotally attached to both side portions of the solar cell panel is attached to the lower end portion of the vertical frame, and upper end portions on both sides of the solar cell panel are attached to the slit portion of the vertical frame. If the horizontal pin provided in the slidably inserted and held along the slit portion, when the horizontal pin reaches the uppermost end portion of the slit portion, the solar cell panel is the window The first use state along the upper wall surface of
A state in which the lower side portion of the solar cell panel projects forward from the upper portion of the window until the horizontal pin leaves the uppermost end portion of the slit portion and reaches the lowermost end portion is set to a second use state. it can.
According to this, although it is a simple structure, a solar cell panel can be made movable in a 1st use state and a 2nd use state. In addition, a support rod pivotally attached to both side portions of the solar cell panel is attached to the lower end portion of the vertical frame, and horizontal pins provided on both upper end portions of the solar cell panel extend along the slit portion to the slit portion of the vertical frame. In the second use state, the solar cell panel is easily desired by sliding the position of the horizontal pin provided on the solar cell panel along the slit portion. Can be tilted at an angle. Furthermore, even if the inclination angle of the solar cell panel is gently adjusted, the lower side of the solar cell panel does not move away from the upper side of the window, and the function of the bag can be exhibited.

According to the solar cell panel mounting structure of the present invention, the solar cell panel is mounted so as to serve as a window ridge. In the second use state, the solar cell panel is inclined downward and the upper side portion of the solar cell panel is the first side. Since it is configured to be positioned below the position of the upper side in the use state, even if the inclination angle of the solar cell panel is moderate, the solar cell panel does not move away from the window, and sunlight is effectively used as a kite Can be prevented. In addition, when the typhoon or snowfall is in the first use state, and when it is tilted to the desired angle according to the season, the second use state is used. Can be divided.
For example, when it is in the first use state, that is, when it is in the retracted state, the back surface of the solar cell panel is configured to follow the upper wall surface of the window, and the surface of the solar cell panel faces the front side so that sunlight can be taken in It can be. Therefore, the solar cell panel can be used even in the first use state.
Moreover, since the solar cell panel is configured to be positioned close to the upper part of the window so that the lower side thereof does not cover the window, the solar cell panel does not block the window.
In the second use state, for example, from spring to summer, if the lower side of the solar cell panel protrudes forward from the upper part of the window, the room temperature is suppressed by blocking the sunlight into the room approaching the window. In addition, it is possible to efficiently capture sunlight into the solar cell panel and increase the amount of power generation.
In winter and the like, if the inclination angle of the solar cell panel is increased, winter sunlight can be efficiently taken into the solar cell panel, and the amount of power generation can be increased.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is an exploded perspective view of each member for explaining a solar cell panel mounting structure according to the present invention, and FIGS. 2A and 2B are schematic side views for explaining the solar cell panel mounting structure. 3 to 5 are perspective views of relevant parts for explaining the mounting structure of the solar cell panel.

  The mounting structure of the solar cell panel 1 according to the present invention is attached above the window 4 provided on the wall surface 5 so as to serve also as a ridge of the window 4, and the solar cell panel 1 is substantially parallel to the wall surface 5. The use state (refer to FIG. 2 (b) and FIG. 5) and the second use state (refer to FIG. 2 (a), FIG. 3 and FIG. 4) where the solar cell panel 1 is inclined at a desired angle with respect to the horizontal plane. The structure is reusable. The means that can be moved between the first use state and the second use state may be either an electric type or a manual type. Here, a case where the electric type is movable will be described.

In FIG. 1, each member used in order to implement | achieve the attachment structure of the solar cell panel 1 is shown.
The solar cell panel 1 is a rectangular thin plate, and its four circumferences are surrounded by a frame material made of aluminum or the like, and a large number of solar cells are provided inside the frame material. The solar battery panel 1 collects the sunlight irradiated to the solar battery cells to produce electricity, and converts the direct current into alternating current with an exchanger (not shown) to produce electric energy. Therefore, the amount of power generation can be increased by efficiently incorporating sunlight into the solar cell panel 1.
In the figure, 1a is the upper side part of the solar cell panel 1, 1b is the lower side part of the solar cell panel 1, 1c is the surface of the solar cell panel 1, the side where the solar cells are provided, and 1d is the solar cell panel 1. This is the back side of the battery, and shows the side where no solar cells are provided. Reference numeral 10 denotes a first horizontal pin that is slidably inserted and held in a slit portion 20 of the vertical frame 2 to be described later. These are horizontal pins, and two first horizontal pins 10 and two second horizontal pins 11 are formed on both sides of the solar cell panel 1 in total.

Two vertical frames 2 are required to make the solar cell panel 1 tiltable to a desired angle and be movable.
The vertical frame 2 is formed so that a plate-like plate made of a metal material or a hard resin material has a substantially L-shaped cross section, and a predetermined interval is formed on the upper wall surface of the window 4 according to the width of the solar cell panel 1. Two separated vertical frames 2 are fixed in parallel with fixing screws 6.
In the figure, 20 is formed with a predetermined length in the longitudinal direction of the vertical frame 2, the slit portion into which the first horizontal pin is inserted and held, 20 a is the lowermost end portion of the slit portion 20, and 20 b is the slit portion 20. An uppermost end portion, 21 is a mounting hole through which a mounting pin 30 of the support bar 3 described later is inserted, and 22 is a screw insertion hole through which a fixing screw 6 (see FIGS. 3 and 4) for fixing to the wall surface 5 is inserted. is there. Here, an example in which three screw insertion holes 22 are formed at intervals in the longitudinal direction of the vertical frame 2 is shown. However, the screw insertion holes 22 are not limited to three as long as they can be firmly fixed to the wall surface 5. Although only one fixing screw 6 is shown in FIG. 1, it goes without saying that the fixing screw 6 is inserted into each of the screw insertion holes 22.

A support rod 3 is pivotally attached to both side portions of the solar cell panel 1 at the lower end portion of the vertical frame 2 and supports the solar cell panel 1 in a downwardly inclined state. Therefore, when the solar cell panel 1 is moved by driving the motor unit 9 to be described later, the support bar 3 moves with the movement of the solar cell panel 1, and the solar cell panel 1 can be moved while changing its inclination angle in the downward inclined state. .
The support bar 3 is made of a metal material or a hard resin material, and is formed of a plate-like plate. A mounting pin 30 pivotally attached to the vertical frame 2 is formed at one end of the support bar 3, and a pin insertion hole 31 pivotally attached to the solar cell panel 1 is formed at the other end. The attachment pin 30 is inserted and held in the attachment hole 21 formed in the vertical frame 2, and the second horizontal pin 11 formed on both sides of the solar cell panel 1 is inserted into the pin insertion hole 31. Therefore, when the first horizontal pin 10 of the solar cell panel 1 slides along the slit portion 20, the side inserted and held in the vertical frame 2 by the mounting pin 30 of the support bar 3 serves as an axis, and the support bar 3. While the pin insertion hole 31 side is driven by the movement of the solar cell panel 1, the solar cell panel 1 is always supported so as to be inclined downward in the second use state.

(Installation procedure)
Next, the attachment procedure of the solar cell panel 1 will be described.
First, in order to fix the two vertical frames 2 to the upper wall surface of the window 4 so as to have a predetermined interval according to the width of the solar cell panel 1, the vertical frames 2 are aligned and the fixing screws 6 are inserted. A pilot hole is previously formed in a place with an electric drill or the like. And the vertical frame 2 is arrange | positioned according to a pilot hole, and the vertical frame 2 is fixed with the fixing screw 6 using an electric screwdriver.
When the vertical frame 2 is fixed to the wall surface 5, the mounting pin 30 of the support bar 3 is fitted into the mounting hole 21 formed in the lower end portion of the vertical frame 2.
The first horizontal pin 10 of the solar cell panel 1 is fitted into the slit portion 20 of the vertical frame 2, and the second horizontal pin of the solar cell panel 1 is inserted into the pin insertion hole 31 of the support bar 3 attached to the vertical frame 2 in that state. If 11 is inserted, installation is complete.
In addition, the attachment point is not limited to the above-mentioned point. For example, after fixing the vertical frame 2 to the wall surface 5, the first horizontal pin 10 of the solar cell panel 1 is fitted into the slit part 20, and in this state The support rod 3 may be inserted into the second horizontal pin 11.

By attaching in this way, the solar cell panel 1 can be properly used between the first usage state in which the solar cell panel 1 is substantially parallel to the wall surface 5 and the second usage state in which the solar cell panel 1 is inclined at a desired angle with respect to the horizontal plane. It can be a structure.
As shown in FIG. 2 (a), in the mounting structure of the solar cell panel 1, each part is controlled in the solar cell panel 1 in order to make the solar cell panel 1 movable in the first use state and the second use state. The control part 7 which adjusts, the operation part 8 which adjusts and operates the inclination angle of the solar cell panel 1, and the motor part 9 for moving the solar cell panel 1 based on the control signal of the control part 7 are provided. As a mechanism of the motor unit 9 for moving the solar cell panel 1, a known drive mechanism using a belt or a chain is employed.
Therefore, by operating with the operation unit 8, the solar cell panel 1 moves in the direction of the arrow d1 (see FIG. 2A) or the direction of the arrow d2 (see FIG. 2B), and the second use state or the first Setting operation can be performed in the use state.

3-5 has shown the example which varied the inclination angle of the solar cell panel 1, respectively.
FIG. 3 is an example of the second use state, and shows a case where the inclination angle is minimum.
As shown in FIG. 3, when the first horizontal pin 10 reaches the lowermost end portion 20 a of the slit portion 20 of the vertical frame 2, the lower side portion 1 b of the solar cell panel 1 projects farthest forward from the upper portion 4 a of the window 4. The second use state is set.
According to the place where the inventor changed the inclination angle of the solar cell panel 1 and variously measured the power generation amount, in Tokyo, the efficiency of the solar cell panel 1 was changed from 10 ° to 20 ° from April to September. It is known that sunlight can be taken into the solar cell panel 1 well. Therefore, what is necessary is just to set the position used as the lowest end part 20a of the slit part 20 so that the minimum inclination | tilt angle may be set to 10 degrees-20 degrees.
Thus, for example, from April to September, it is assumed that the lower side portion 1b of the solar cell panel 1 protrudes the most, and if the inclination angle is moderated, the sunscreen is effectively exhibited and solar light is efficiently emitted from the solar cell. It can be taken into the panel 1 and the power generation amount can be increased.

FIG. 4 is an example of the second use state, and shows a case where the inclination angle is about 40 ° to 50 °.
As shown in FIG. 4, the position of the first horizontal pin 10 provided on the solar cell panel 1 is slid up and down along the slit portion 20 of the vertical frame 2 to easily make the solar cell panel 1 at a desired angle. Can be tilted.
According to the place where the inventor changed the inclination angle of the solar cell panel 1 and variously measured the power generation amount, in Tokyo, the efficiency of the solar cell panel 1 was changed from 30 ° to 60 ° in October to March. It is known that sunlight can be taken into the solar cell panel 1 well. Therefore, if the inclination angle is changed according to the season, sunlight can be efficiently taken into the solar cell panel 1 and the power generation amount can be increased.
Here, as described above, the example in which the inclination angle of the solar cell panel 1 is changed electrically by the operation of the operation unit 8 has been described, but it can be changed manually. In that case, for example, a recess in which the first horizontal pin 10 is locked may be formed in the slit portion 20.
As described above, as shown in FIGS. 3 and 4, the lower side 1b of the solar cell panel 1 is the window 4 until the first horizontal pin 10 leaves the uppermost end 20b of the slit portion 20 and reaches the lowermost end 20a. The second use state and the second use state projecting forward from the upper portion of. In the second use state, the solar cell panel 1 is inclined downward, and the upper side 1a of the solar cell panel 1 is always positioned below the position of the upper side 1a in the first use state. Since the inclination angle is adjusted by sliding the first horizontal pin 10 of the battery panel 1, the solar cell panel 1 does not move upward from the window even if the inclination angle of the solar cell panel 1 is moderated. Sunlight can be effectively prevented.

FIG. 5 shows the first use state, and shows a state stored as damage prevention such as during a typhoon or snow.
As shown in FIG. 5, when the first horizontal pin 10 reaches the uppermost end 20 b of the slit portion 20 of the vertical frame 2, the back surface 1 d of the solar cell panel 1 follows the upper wall surface of the window 4 and the solar cell panel 1 The lower side portion 1b is configured to be positioned close to the upper portion 4a of the window 4 and is in the first use state.
Thus, if it is set as the 1st use state, it is constituted so that back 1d of solar cell panel 1 may follow the upper wall of window 4, and since surface 1a of solar cell panel 1 faces the front side, even in the 1st use state Sunlight can be taken in and power can be generated. Therefore, for example, due to snow accumulation, sunlight can be taken in if there is sunlight even when the first use state is temporarily set.
Moreover, since the solar cell panel 1 is configured to be positioned close to the upper portion 4a of the window 4 so that the lower side 1b does not cover the window 4, the window 4 may be blocked by the solar cell panel 1. Absent.
Furthermore, as shown in FIG. 5, if it is in the first use state, the storage state can be made thin.

  In addition, the shapes and configurations of the solar cell panel 1, the vertical frame 2, the support bar 3, and the like are not limited to the illustrated examples.

It is a disassembled perspective view of each member for demonstrating the attachment structure of the solar cell panel which concerns on this invention. (A) (b) is a typical side view for demonstrating the attachment structure of the solar cell panel. It is a principal part perspective view for demonstrating the attachment structure of the solar cell panel. It is a principal part perspective view for demonstrating the attachment structure of the solar cell panel. It is a principal part perspective view for demonstrating the attachment structure of the solar cell panel.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Solar cell panel 1a Upper side part 1b Lower side part 1d Back surface 10 (1st) Horizontal pin 2 Vertical frame 20 Slit part 20a Bottom end part 20b Top end part 3 Support bar 4 Window 4a Upper part 5 Wall surface

Claims (2)

A rectangular solar cell panel mounting structure that is mounted above a window provided on a wall surface so as to double as a ridge of the window,
The solar cell panel has a structure in which the first usage state substantially parallel to the wall surface and the second usage state in which the solar cell panel is inclined at a desired angle with respect to a horizontal plane can be used separately.
In the first use state, the back surface of the solar cell panel is configured to be positioned close to the upper wall surface of the window and the lower side portion of the solar cell panel is located close to the upper portion of the window,
In the second use state, the solar cell panel is inclined downward, and the upper side portion of the solar cell panel is positioned below the position of the upper side portion in the first use state. The solar cell panel mounting structure. In claim 1,
On the upper wall surface of the window, two vertical frames with a predetermined interval are fixed in parallel according to the width dimension of the solar cell panel, and a slit portion is formed in the longitudinal direction of the vertical frame. And
Support bars pivotally attached to both side portions of the solar cell panel are attached to the lower end portion of the vertical frame, and horizontal pins provided at both upper end portions of the solar cell panel are provided to the slit portion of the vertical frame. Inserted and held slidably along the slit portion,
When the horizontal pin reaches the uppermost end of the slit portion, the solar cell panel is in a first use state along the upper wall surface of the window,
The lower side portion of the solar cell panel extends from the upper portion of the window to the front side until the horizontal pin leaves the uppermost end portion of the slit portion and reaches the lowermost end portion. A solar cell panel mounting structure characterized by the above.

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