JP2019056276A - Solar power generation unit system - Google Patents

Abstract

To provide a solar power generation unit system which can be installed easily and simply even in a place where construction conditions are severe such as a roof of a building with a limited area and which can perform efficient solar power generation by minimizing a load on an installation target such as a building and securing a large-capacity installation area.SOLUTION: There is provided a solar power generation unit system comprising a solar power generation panel, and a base frame member disposed in contact with an installation surface and supporting the solar power generation panel. The solar power generation panel is configured with the base frame member so as to be inclined at a predetermined angle. A front end cover, a rear end cover, and side covers, which seal respectively between the solar power generation panel and the installation surface, are provided respectively at a front end where a height position of the solar power generation panel is low, a rear end where a height position is high, and both side edges of the front end and the rear end. The front end cover and the rear end cover are respectively inclined outward, and the side covers are not inclined.SELECTED DRAWING: Figure 1

Description

  The present invention can be installed easily and easily in a limited area such as a rooftop of a building, where the construction conditions are severe, and it is efficient to secure a large capacity installation area by minimizing the load on the installation target such as a building. The present invention relates to a photovoltaic power generation unit system that can perform typical photovoltaic power generation.

Photovoltaic power generation systems are attracting attention as the degree of attention of renewable energy increases. In recent years, especially on the rooftops of buildings where it was difficult to install foundations for power generation units in line with conventional installations, considering installation from the viewpoint of effective use of dead space and effective use of renewable energy Has been.
Therefore, development of a unit system capable of installing solar power generation without installing a foundation has been studied and various proposals have been made.
For example, in Patent Document 1, a solar power generation panel can be installed on a rooftop of a seven-story building or more on the middle upper floor, and the south side is provided for the purpose of providing a solar power panel installation table with good workability. A photovoltaic power generation panel installation table that is inclined to the frame, includes a frame, a horizontal support bracket, and an inclined bracket that is arranged to be inclined on the frame, and has a stone plate that is arranged on the frame, and has a photovoltaic panel installation In the stand, a unit system is proposed in which nine photovoltaic power generation panels are installed on the lateral support bracket.
Patent Document 2 discloses that a frame-combined frame is horizontally installed as a frame system for a photovoltaic power generation module that is lightweight and can be rationalized, and that is lightweight but extremely stable against strong winds. A mounting system for mounting a power generation module on the mounting base, and mounting a plurality of mounting bases in parallel on the horizontal mounting surface, and installing one or a plurality of power generation modules on the mounting base; A cover body is formed to cover the gap that opens from the side surface of the power generation module installed on the gantry to the installation surface, the cover body is attached around the gantry, and the power generation module is pressed against the installation surface by the wind pressure blown to the power generation module. A fixed system has been proposed.

Noto 3186568 JP 2012-87560 A

However, in the systems according to the proposals of Patent Documents 1 and 2, it is not possible to secure a large capacity installation area and perform efficient solar power generation, and it is not sufficient to simply install the system during construction. There was no need for installation work for reinforcement.
In short, there is a demand for the development of a solar power generation system that can secure a large-capacity installation area without requiring special installation work in a limited area such as the rooftop of a building.

  Accordingly, the object of the present invention is to enable easy and simple installation in a limited area such as a rooftop of a building, where the construction conditions are severe, and to minimize the load on the installation target such as a building and to reduce the installation area of a large capacity. The object is to provide a photovoltaic power generation unit system that can secure and perform efficient photovoltaic power generation.

As a result of intensive studies to solve the above-mentioned problems, the inventors of the present invention can prevent wind lift by providing a slope only in the front-rear direction when covers are disposed in the front-rear and left-right regions of the photovoltaic power generation panel. The inventors have found that the pressing force can be used efficiently and the area can be increased, and the present invention has been completed.
That is, the present invention provides the following inventions.

1. A solar power generation panel and a base frame member that is disposed in contact with the installation surface and supports the solar power generation panel;
The solar power generation panel has a basic frame member configured to be inclined at a predetermined angle,
The solar power generation panel has a low front end, a high rear end, and the front end and both side edges of the rear end are sealed between the solar power generation panel and the installation surface, respectively. Front end cover, rear end cover, and side cover are provided respectively.
The front end cover and the rear end cover are each inclined outward, and the side cover is not inclined.
A solar power generation unit system characterized by that.
2. The photovoltaic power generation panel is an aggregate of a plurality of photovoltaic power generation panels, the front end is a front end of the aggregate, the rear end is a rear end of the aggregate, and both side edges are the aggregate. The solar power generation unit system of 1 which is the both-sides edge of.
3. 2. The photovoltaic power generation unit system according to 1, wherein an inclination angle of the front end cover and an inclination angle of the rear end cover are both 130 to 140 degrees.
4). Each of the front end cover, the rear end cover, and the side cover is a sealing member made of an elastic material for sealing a gap between the installation surface and the cover main body, provided at the lower end edge of the cover main body. The solar power generation unit system of 1 which comprises these.
5. The photovoltaic power generation unit system according to 4, wherein the cover body is provided with a folded portion at a lower end thereof, and the sealing member is disposed at the folded portion.

  The photovoltaic power generation unit system of the present invention can be easily and easily installed in a limited area such as a rooftop of a building where the construction conditions are severe, and it can be installed in a large capacity while minimizing the load on the installation target such as a building The area can be secured and efficient solar power generation can be performed.

FIG. 1 is a perspective view schematically showing one embodiment of a photovoltaic power generation unit system of the present invention. FIG. 2 is a transparent side view in the A direction showing the internal structure of the photovoltaic power generation unit system shown in FIG. FIG. 3 is a perspective view in the A direction showing a state in which the side cover is removed from the rear end side of the photovoltaic power generation unit system shown in FIG. 4 is an enlarged view of part B of the photovoltaic power generation unit system shown in FIG. 3 showing one embodiment of the mounting bracket for the photovoltaic power generation panel. FIG. 5 is a partial perspective view showing the inside of the photovoltaic power generation system of the present invention with a part of the front end cover removed. FIG. 6 is a perspective view of the photovoltaic power generation unit system shown in FIG. FIG. 7 is an enlarged cross-sectional view of the vii portion of FIG. FIG. 8 is an enlarged cross-sectional view of part viii of FIG. FIG. 9 is an enlarged cross-sectional view of the ix portion of FIG. FIG. 10 is a perspective view showing a member that can be attached to the opening.

DESCRIPTION OF SYMBOLS 1 Photovoltaic unit system; 10 Photovoltaic power generation panel; 10a Individual photovoltaic power generation panel; 12 Front end; 14 Rear end; 16 Both-sides edge; 20 Base frame member; 20a Base unit; 22 Base frame; 24 both ends of 22; 24 inclined frame; 24a, 24b both ends of inclined frame 24; 26 holding portion; 25 connecting portion; 28 support frame; 27 transverse frame; 30 front end cover; 30a individual front end cover; 30b connecting portion; 50 side cover; 50-2 individual side cover; 50-2 individual side cover; 50c air hole; 50d cover hood; 50e bent part; 32, 42, 52 cover body; 34, 44, 54 folded part; , 56 sealing member; 60 connecting bracket; 62 bolts; 4 nut; 66 cover member; 67 retainer member; 68 washers; 70L-shaped bracket

Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings.
<Overall structure>
As shown in FIGS. 1 to 3, the photovoltaic power generation unit system 1 of the present embodiment is disposed in contact with the photovoltaic power generation panel 10 and the installation surface A, and supports the photovoltaic power generation panel 1. It comprises.
This will be described in detail below.
<Solar power generation panel>
In the present embodiment, the photovoltaic power generation panel 10 (hereinafter sometimes simply referred to as “panel”) is a panel that receives sunlight to generate power, and a known photovoltaic power generation panel can be used without particular limitation. .
In this embodiment, nine rectangular individual photovoltaic power generation panels 10a (vertical 3 rows × horizontal 3 rows) are arranged side by side. That is, in this embodiment, the photovoltaic power generation panel 1 is an aggregate of a plurality of individual photovoltaic power generation panels, and the front end 12, the rear end 14, and both side edges 16 of the aggregate are “ It constitutes “front end”, “rear end of solar power generation panel” and “both side edges of solar power generation panel”.
Moreover, the size of each individual photovoltaic power generation panel 10a in this embodiment is 1000 mm (front-rear direction) × 1600 mm (lateral direction). The height of the front end 12 is 200 mm, the height of the rear end 14 is 450 mm, and the inclination of the photovoltaic power generation panel is about 5 °.

<Fundamental frame member>
The basic frame member 20 is configured so that the photovoltaic power generation panel 10 is inclined at a predetermined angle.
2 and 3, the base frame member 20 includes a base frame 22 positioned in contact with the installation surface A, and an inclined frame 24 installed at a predetermined angle above the base frame 22. A holding portion 26 that holds the inclined frame 24 in an inclined state above the basic frame 22 is provided, and the base unit 20a is configured by these members. Further, a support frame 28 for fixing the photovoltaic power generation panel is installed in parallel to the inclined frame 24 and above the inclined frame 24. The support frame 28 is fixed to the inclined frame 24 via a transverse frame 27 provided on the inclined frame 24 so as to connect the inclined frame 24.
A plurality of base units 20a are arranged in parallel, and are connected and fixed by connecting portions (not shown) provided on the inclined frames 24 so as to cross the inclined frames 24.
The base frame 22 is a metal frame having a U-shaped cross section, although not particularly illustrated. Both ends 22a (FIG. 4) are considered in consideration of the presence of a front end cover and a rear end cover, which will be described later, and stability. In this figure, only the rear end side is shown, but the front end side is also configured in the same manner), but the length is positioned outward from both ends 24 a of the inclined frame 24.
The holding portions 26 are provided at three positions corresponding to the edge positions of the individual photovoltaic power generation panels 10a to be installed, and the inclined frame 24 is inclined at a predetermined angle by having different lengths. I am doing so.
The inclined frame 24 and the base frame 22 are connected via the holding portion 26 as described above, but both are connected in direct contact on the front end 12 side. For this reason, the height of the front end is held by the height of the transverse frame 27, and the inclination angle of the front end cover 30 described later is held by holding this height.
Although the inclined frame 24 is provided immediately above the base frame 22, in the present embodiment, the support frame 28 is arranged with a slight shift from the inclined frame 24. Thus, the support frame 28 employs a configuration in which the support frame 28 is connected to the inclined frame 24 via the transverse frame 27 so that the arrangement position can be adjusted according to the size of the photovoltaic power generation panel 10a to be used.
Each part and frame are not particularly illustrated and shown individually, but in the present embodiment, they are connected using fastening members such as screws or bolts and nuts.
The support frame 28 and the transverse frame 27 are respectively disposed along the end edge and the side edge of the individual photovoltaic power generation panel 10a, and the photovoltaic power generation panel is supported by the connecting metal fitting 60 shown in FIG. And fixed to the transverse frame. As shown in FIG. 4, the transverse frame 27 is provided with a projection 27a for holding the panel on the upper part of the transverse frame 27 along the length direction of the frame and over the entire length of the frame. A cavity 27b is provided in the upper portion of the frame 27 along the length direction of the frame, and a holding portion 27c having a hook-like tip is formed to hold the metal fitting. The separate photovoltaic power generation panel 10a is fixed to the connecting metal fitting 60 by a metal fitting 60 comprising a bolt 62 and a nut 64 shown in FIG. The metal fitting 60 is fastened by sandwiching a belt-like cover member 66 made of an elastic body that directly contacts the panel 10a, a holding metal fitting 67 that holds the cover member 66, and two washers 68 between the bolt 62 and the panel 10a. Has been.
In addition, although a clearance gap arises between each panel, it is preferable to inject | pour and seal a silicon sealing material etc. between each panel from a waterproof viewpoint.
Further, in the support frame 28, a panel is fixed through an L-shaped metal fitting 70 shown in FIG. 5 as necessary, and a band-shaped cover member is laid on the upper surface of the metal fitting 70 so that a gap between the panels is formed. It is lost.

<Cover>
As shown in FIGS. 1 to 3 and 6, the solar power generation unit system 1 of the present embodiment includes a front end 12 having a low height position, a rear end 14 having a high height position, and the front end in the solar power generation panel 10. 12 and both side edges 16 of the rear end 14 are respectively provided with a front end cover 30, a rear end cover 40, and a side cover 50 that seal between the photovoltaic power generation panel and the installation surface.
Note that “sealing” in the front end cover 30, the rear end cover 40, and the side cover 50 does not mean that the front end cover 30, and the side cover 50 are completely sealed. It means that the gap is not generated so that the wind is not blown.
The front end cover 30, the rear end cover 40, and the side cover 50 seal the gap between the installation surface A and the cover main bodies 32, 42, 52 provided at the lower ends of the cover main bodies 32, 42, 52, respectively. Sealing members 36, 46, and 56 made of an elastic material. Further, the cover main bodies 32, 42, 52 are provided with folded portions 34, 44, 54 at their lower ends, and the sealing members 36, 46, 56 cover the entire surface of the folded portions 34, 44, 54 on the installation surface side. Is provided. Due to the provision of the sealing members 36, 46, 56 (see FIGS. 7 to 9), wind blows in through the clearance on the installation surface side, and the position of the system is shifted, damaged, or flies by the lift of the wind. Disappears. The width of the folded portions 34, 44, 54 is usually about 2 to 3 cm.
The front end cover 30 and the rear end cover 40 include an individual front end cover 30a and an individual rear end cover 40a each having a size corresponding to the size of each panel. In the present embodiment, the individual front end cover 30a corresponds to the number of installed panels. Three individual rear end covers are provided. Each of the individual front end cover 30a and the individual rear end cover is formed with a connecting portion (not shown) for overlapping each other, and the connecting portions are overlapped and connected by a fastening member such as a screw. The width of the connecting portion 30b is usually about 2 to 3 cm.
The side cover 50 is composed of two individual side covers 50-1 on the front end side and individual side cover 50-2 on the rear end side, and three air holes 50c are formed in the individual side cover 50-2. Yes. By providing the air hole 50c, it is possible to prevent heat from being accumulated inside the photovoltaic power generation unit system 1, and to appropriately release the wind pressure applied to the side surface without interfering with the pressing force by the wind pressure. The desired effect of the invention can be further improved. In addition, it is preferable to provide a cover hood 50d shown in FIG. 10 in the air hole 50c in order to prevent rainwater from entering and to minimize the influence of wind lift.
A connecting portion between the side cover 50 and the front end cover 30 or the rear end cover 40 is provided with a connecting bent portion (not shown) on the side cover 50, and the connecting portion and the bent portion of the front end cover 30 are overlapped. In addition, they are connected with fastening members such as screws. The width of the bent portion is usually about 2 to 3 cm.
In the present embodiment, the front end cover 30 and the rear end cover 40 are each inclined outward. On the other hand, the side cover 50 is not inclined and is erected substantially vertically with respect to the installation surface.
Here, the inclination angle of the front end cover (θ in FIG. 2) and the inclination angle of the rear end cover (θ in FIG. 2) are both preferably 130 to 140 °. By setting the angle within this range, it is possible to make maximum use of the pressing force caused by the wind pressure when the wind blows against the photovoltaic power generation unit system of the present embodiment, and fix it at the installation location.
Further, “the side cover 50 is not inclined” means that the installation angle between the installation surface and the side cover is within a range of 90 ° ± 5 °, particularly preferably 90 ° ± 2 °.

<Material / Manufacturing>
The above-mentioned basic frame member 20 can use a material used for installing this type of panel without any particular limitation, and specifically, a metal material such as stainless steel or aluminum can be used. The same applies to the front end cover 30, the rear end cover 40, and the side cover 50.
The sealing members 36, 46, and 56 can use elastic materials such as various rubbers and urethane materials.
The cover member disposed between the panels is preferably made of an elastic material such as a urethane material.
Each of the above-described members can usually be manufactured in the same manner as this type of frame or panel, and the solar power generation unit system of this embodiment can be assembled by performing an operation of connecting the respective members at the installation site.

<Effect>
In the photovoltaic power generation unit system 1 of the present embodiment, the front end cover 30 and the rear end cover 40 are inclined at a predetermined angle as described above, whereas the side cover 50 is not inclined. It is possible to use the pressing force of the wind rather than the thing, and it is possible to increase the capacity by effectively utilizing the area of the installation surface because the side cover is not inclined. In this case, the pressing force can be further maximized by setting the predetermined inclination angle within the above-mentioned specific range. In addition, since the folded portions 34, 44, 54 are provided at the lower ends of the covers 30, 40, 50 and the sealing members 36, 46, 56 are provided, the wind is particularly generated inside the unit system 1. Since the effect of the lift force is not exerted by blowing, the above-described operational effects of the present invention are more satisfactorily exhibited. Further, since the sealing members 36, 46 and 56 are provided, the function as a waterproof structure is also exhibited, and the installation surface can be prevented from being damaged by rainwater.

In addition, about the photovoltaic power generation unit system 1 of this embodiment, it is preferable to give the weight not to be defeated by the wind lift, but the photovoltaic power generation panel and the base frame member may not be sufficient. In this case, it is preferable to add a weight separately.
At this time, the weight of the weight to be given can be calculated by the calculation method described in Utility Model Registration 3186568. An example is shown below.
(Calculation of lift and shape of installation base. Determination of weight)
First, the inventor of the present application assumes that a photovoltaic power generation panel is installed on a building roof of a middle upper floor or higher (7 floors or higher), and from the size and weight of the solar power generation panel to be used, The lift by the wind force applied to the installation base and the total weight of the installation base against the lift are obtained, and based on the result, the shape, weight, etc. of the photovoltaic power generation panel installation base according to the present invention according to Example 1 are determined. .

(A) Wind load calculation This calculation basically uses the values of the “design standard for solar cell array indicator (JIS C 8955)” and wind tunnel test results.

(B) Input parameters
(a) Examine the lift on the panel when installing nine photovoltaic panels.
Dimensions: 4990 (W) x 3690 (D) x 450 (H) (unit: mm)
Weight: 150 (kg)
(b) Ground clearance: H = 45m (top of mount): Equivalent to the roof of a 15-story building
(c) Design standard wind speed: Vo = 34 (m / s)
The standard wind speed for design is a value within the range of 30 m / s to 46 m / s determined according to the degree of wind damage and other wind properties based on the past typhoon records in the construction site law (JIS C 8955), assuming 23 wards of Tokyo, 34 (m / s).
(d) Ground surface roughness classification: III
Ground surface roughness classification is a classification determined based on the “Surface roughness classification (I to IV)” (May 31, 2000, Ministry of Construction Notification No. 1454) for calculating wind pressure. The normal urban area is classified as (Division = III).
(e) Application factor: I = 1.0
The application factor is a factor that must be considered according to the application when calculating wind pressure load or seismic load, and 1.0 is usually sufficient. 32.
(f) Wind coefficient: Cw = 0.193
The wind power coefficient is a coefficient of wind pressure acting on a single solar power generation panel determined by a wind tunnel experiment, and the manufacturer's measured value was 0.193. However, the solar power generation unit system of the present invention is as described above. In addition, since the front end cover and the rear end cover are inclined outward, and the side cover is not inclined, the measured value of the coefficient of wind pressure by the wind tunnel experiment is lower. And falls to about 0.160.

(C) Calculation of velocity pressure (q) Velocity pressure (q) = 0.6 × E × Vo 2 × I (N / m ² )
Where E = Er2 × Gf
Er = 1.7 × (Zb / ZG) α
: When H is less than Zb
Er = 1.7 × (H / ZG) α
: When H exceeds Zb E is an environmental factor to consider depending on the height of the installation location and the topography and features around the construction site when calculating the wind pressure load. Er is the average wind speed The coefficient representing the distribution in the height direction, Gf is a gust influence coefficient that increases the average wind speed considering the gust component, Zb, ZG, and α are values according to the ground surface roughness classification, When H = 45 m and the surface roughness classification = III, the values are Zb = 5, ZG = 450, α = 0.20, and Gf = 2.10.
When Er, E, and q are obtained under these conditions, Er = 1.07, E = 2.42, and q = 1675.82 (N / m ² ).

(D) Lift calculation (kg)
As a result of the above,
Dimensions: 4990 (W) x 3690 (D) x 457 (H) (unit: mm)
Weight: 150 (kg)
The lift applied to) is obtained from the following equation.
Lift (W) = wind force coefficient (Cw) × speed pressure (q) × wind receiving area where wind force coefficient (Gw) = 0.160, wind receiving area = 18.4 m ²
Because
Lift (W) = 4934 (N) = 503 kg.
Considering a safety factor of about 1.3, lift (W) × safety factor = 653.9 kg.
Moreover, since the weight of the photovoltaic power generation panel is about 150 kg, and the weight of this type of installation base is about 300 kg, it is preferable to arrange a weight of about 200 kg so that the above lift force can be countered. become.
In addition, by laying an adhesive or double-sided adhesive tape on the contact surface with the installation surface in the folded portions 34, 44, 54, the fixing power of the photovoltaic power generation unit system can be strengthened and the weight of the weight can be reduced. In that case, the wind power coefficient fluctuates depending on the type of adhesive and adhesive tape used, but the wind power coefficient is reduced to about 1.3 to 1.4 even if an ordinary easy-to-peel type adhesive tape is used. It is possible to reduce the weight to 100 kg or less.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.

Hereinafter, the present invention will be described more specifically with reference to examples, but the present invention is not limited thereto.
[Example 1]
A photovoltaic power generation unit system (with a size of 1/7 scale) having the configuration shown in FIG. 1 is manufactured with the angle between the front end and the installation surface being 135 ° and the angle between the rear end and the installation surface being 135 °. It was placed in the wind tunnel experiment facility as a virtual building rooftop. When wind at a wind speed of 15 m / s was blown for 10 seconds at the installed wind tunnel experimental facility, no particular movement of the installation position was observed. Also, from the results at this time, the buoyancy of the solar power generation unit system due to the wind was calculated by converting it to a wind scale of 50 m and the actual scale. The maximum value of the buoyancy was 97.8 kgf, and the backward moving force was 39 kgf Met. This did not affect the installation status for the actual weight of the actual photovoltaic unit system of 250 kg.
[Example 2]
A 1/7 scale photovoltaic power generation unit system was manufactured in the same manner as in Example 1 except that the angle between the front end and the installation surface was 150 °, and the angle between the rear end and the installation surface was 150 °. Was installed in the wind tunnel experimental facility. When the wind at a wind speed of 15 m / s was blown for 10 seconds at the installed facility, the installation position was hardly moved, but the position was shifted by about 1 cm in the lateral direction as a whole.
Example 3
A 1/7 scale photovoltaic power generation unit system was manufactured in the same manner as in Example 1 except that the angle between the front end and the installation surface was 120 °, and the angle between the rear end and the installation surface was 120 °. Was installed in the wind tunnel experimental facility. When the wind at a wind speed of 15 m / s was blown for 10 seconds at the installed facility, the installation position was hardly moved, but the position was shifted by about 1 cm in the front-rear direction.

Claims (5)

A solar power generation panel and a base frame member that is disposed in contact with the installation surface and supports the solar power generation panel;
The solar power generation panel has a basic frame member configured to be inclined at a predetermined angle,
The solar power generation panel has a low front end, a high rear end, and the front end and both side edges of the rear end are sealed between the solar power generation panel and the installation surface, respectively. Front end cover, rear end cover, and side cover are provided respectively.
The front end cover and the rear end cover are each inclined outward, and the side cover is not inclined.
A solar power generation unit system characterized by that.
The photovoltaic power generation panel is an aggregate of a plurality of photovoltaic power generation panels, the front end is a front end of the aggregate, the rear end is a rear end of the aggregate, and both side edges are the aggregate. The photovoltaic power generation unit system according to claim 1, wherein the photovoltaic power generation unit system is a side edge of each of the two.
2. The photovoltaic power generation unit system according to claim 1, wherein an inclination angle of the front end cover and an inclination angle of the rear end cover are both 130 to 140 degrees.
Each of the front end cover, the rear end cover, and the side cover is a sealing member made of an elastic material for sealing a gap between the installation surface and the cover main body, provided at the lower end edge of the cover main body. The photovoltaic power generation unit system according to claim 1 comprising:
The photovoltaic power generation unit system according to claim 4, wherein the cover body is provided with a folded portion at a lower end thereof, and the sealing member is disposed at the folded portion.