JP4409462B2 - Solar panel mounting structure - Google Patents

Description

  The present invention relates to a solar panel mounting structure used for a power source of a lighting device such as a street lamp.

  Lighting devices such as street lights and garden lights are installed in roadsides, parks, gardens, etc., and turn on at night to illuminate the surroundings. As a power source for lighting devices such as street lamps, a commercial power source is generally applied. For example, in a street lamp used in a place where it is difficult to secure a power source, a solar panel (solar cell panel) is used as a power source. Electric power generated in the daytime or the like by the solar panel is stored in a storage battery, and illumination is performed by supplying (discharging) power from the storage battery to the light source at night (see, for example, Patent Document 1).

  In addition, incandescent lamps, fluorescent lamps, mercury lamps and the like have been used as light sources used in lighting devices such as street lamps. Recently, however, power consumption has been reduced and maintenance and management have been reduced. For the purpose of measuring, an LED (light emitting diode) is used as a light source (see, for example, Patent Document 2).

In a solar panel type street lamp or the like, for example, a light source such as an LED is disposed on an upper portion of a pole (post), and a solar panel is attached above the light source. Here, since it is necessary to install the solar panel facing south, a mounting structure capable of adjusting the horizontal angle of the solar panel is adopted. Conventionally, as shown in FIGS. 9A and 9B, for example, as shown in FIGS. 9A and 9B, a circular pipe (for example, a steel pipe) 203 that supports the solar panel 202 is provided at the upper end of a pole (not shown). There is a structure in which the rotating support shaft (for example, a steel pipe) 204 is fixed by a non-rotating screw 205 in a state of being inserted.
Japanese Patent Application Laid-Open No. 10-12007 JP 2002-270281 A

  By the way, according to the solar panel mounting structure as shown in FIG. 9, the horizontal angle of the solar panel 202 is adjusted before the fixing by the locking screw 205 or in the state where the tightening by the locking screw 205 is loosened. Although it is possible to adjust the horizontal angle, it is necessary for the operator to adjust the orientation of the panel while supporting the solar panel 202. In addition, since the rotation of the solar panel 202 is fixed only by the tightening force (force caused by point friction between the tip of the locking screw 205 and the surface of the rotation support shaft 204) by the locking screw 205, If the strength against wind pressure load is weak and strong wind or the like acts on the solar panel 202, the solar panel 202 may be displaced in the rotational direction.

  The present invention has been made in view of such circumstances, and it is possible to easily adjust the horizontal angle of the solar panel, and further, a solar panel capable of firmly holding the solar panel with a stable fixing force. An object is to provide a mounting structure.

  The present invention is a structure for attaching a solar panel to a column (for example, a pole), a flange fixed to an end of a support member (for example, a support pipe) that supports the solar panel, and the flange on the solar panel side A presser plate for pressing the presser plate, and with the solar panel flange placed on a support surface (for example, the upper surface of the support plate) provided on the column, the presser plate is fixed to the column (for example, a bolt). A flange of the solar panel is fixed in a state of being sandwiched between the presser plate and the support surface by being fixed using a nut.

  According to the present invention, the flange at the end of the support member of the solar panel is disposed on the support surface of the support column, and the presser plate is bolts, nuts, etc. with the flange sandwiched between the support surface and the presser plate. The solar panel (flange) can be installed in a state in which the solar panel (flange) can be rotated (rotated in the horizontal direction) with respect to the column by temporarily fixing to the column with the fixing means. Moreover, in such a temporarily fixed state, the solar panel flange is sandwiched between the presser plate and the support surface of the support column, and the entire solar panel is held by the presser plate and the support surface. When the horizontal angle adjustment is performed, the operator does not need to support the solar panel, and the horizontal angle adjustment work at a high place can be easily performed. In addition, the solar panel flange is in surface contact with the lower surface of the presser plate and the support surface (for example, the upper surface of the support plate) with the presser plate fully tightened (finally tightened with bolts, nuts, etc.). The fixing force is larger than the mounting structure, and the solar panel can be firmly fixed with a stable force.

  According to the present invention, the solar panel mounting portion has a flange structure, and the solar panel is fixed by frictional force due to surface contact. Therefore, the solar panel can be firmly fixed with a stable force. Strength against wind pressure load can be increased. Thereby, even if a strong wind etc. act on a solar panel, the position shift of a rotation direction does not arise in a solar panel. In addition, when the horizontal angle adjustment is performed at the time of solar panel installation and maintenance, the operator does not need to support the solar panel, so the workability of the horizontal angle adjustment is improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  First, an example of a lighting device to which the present invention is applied will be described with reference to FIGS.

  The lighting device L in this example is a street light installed on a roadside, a park, a garden, etc., and includes a solar panel (solar cell panel) 2, a plurality (5) of storage batteries 5 and 5, a controller 6, And the pole (support | pillar) 1 etc. are provided and the solar panel 2 is attached to the upper end part of the pole 1 (details of attachment structure are mentioned later). The solar panel 2 is provided with bird guards 2a, 2a.

  The pole 1 is obtained by bending an upper portion of a hollow quadrangular column (for example, an aluminum pipe) into a curved shape, and a main illumination lamp 3 is provided at the bent portion. Also, a foot lamp 4 is provided at a predetermined height position (for example, 1150 mm) from the lower end of the pole 1. A base plate 10 is fixed to the lower end of the pole 1 by welding or the like. By using this base plate 10, the pole 1 can be installed on a roadside or a park. The front sides of the main illumination lamp 3 and the foot lamp 4 are covered with transparent covers 3a and 4a, respectively.

  A plurality of light bulb shaped LED lamps 101... 101 are arranged on the main illumination lamp 3 and the foot lamp 4 respectively. For example, as shown in FIG. 6, each of the light bulb shaped LED lamps 101 has high-intensity white LEDs 102... 102 arranged geometrically (for example, a circle and a polygon) on a substrate 103, and the LEDs 102. Is covered with a glass sphere 104, and a base 105 for electrical connection is provided at the base of the glass sphere 104.

  Inside the pole 1, storage batteries 5... 5 for storing electric power generated by the solar panel 2 and a controller 6 are incorporated.

  The controller 6 charges the power generated by the solar panel 2 in the daytime etc. to the storage batteries 5.. 5 and supplies power to the main lighting 3 and the foot lamp 4 from the storage batteries 5. The discharge control is performed to turn on the light bulb shaped LED lamps 101... 101 of the main illumination lamp 3 and the foot lamp 4. The controller 6 also executes control for protecting the storage batteries 5.. 5 from overcharge / overdischarge. In the above lighting control, as a method of recognizing sunset, for example, an illuminance sensor that detects brightness (illuminance) is arranged on the pole 1 to detect ambient brightness, or a timer is used. For example, a method of measuring the time of sunset.

-Solar panel mounting structure-
Next, the mounting structure of the solar panel 2 will be described with reference to FIGS.

  The solar panel 2 is attached to the upper end portion of the pole 1 in a state inclined by 45 ° with respect to the horizontal direction. A support pipe (for example, a circular steel pipe) 21 is fixed to the center of the back surface of the solar panel 2 in a state inclined by 45 ° with respect to the front surface (light receiving surface) of the solar panel 2. A square presser plate 22 is fitted into the support pipe 21, and a square flange 23 is fixed to the lower end.

  The presser plate 22 has a larger area than the flange 23. The inner diameter of the circular through hole 22 a at the center of the presser plate 22 is slightly larger than the outer diameter of the support pipe 21. Accordingly, the presser plate 22 is rotatable and slidable with respect to the support pipe 21, and the entire flange 23 at the lower end of the support pipe 21 can be pressed from the solar panel 2 side (upper side).

  Bolt through holes 22b and 22b are provided at four corners of the presser plate 22. These bolt through holes 22b... 22b are provided at positions where the bolts 14 passed through the respective through holes 22b do not interfere with the flange 23, and rotate the flange 23 relative to the presser plate 22 (centering on the support pipe 21). The flange 23 does not come into contact with the bolt 14 even when the rotation is performed.

  Note that two connection cables (not shown) from the solar panel 2 are passed through the support pipe 21, and connectors 8 a and 8 b provided at the ends of the connection cables are below the flange 23. I'm here.

  On the other hand, a rectangular support plate 11 is fixed to the upper end of the pole 1. The upper surface 11a of the support plate 11 is along the horizontal direction. A circular through hole 13 and a circular boss 12 protruding upward from the peripheral edge of the through hole 13 are provided at the center of the support plate 11. The outer diameter of the circular boss 12 is slightly smaller than the inner diameter of the support pipe 21, and the circular boss 12 can be inserted into the lower end portion of the support pipe 21 as shown in FIG. 5.

  In addition, bolts (planting bolts) 14... 14 are fixed to the support plate 11 at four locations that are rotationally symmetric with respect to the center of the circular boss 12. Each bolt 14... 14 is provided perpendicular to the upper surface 11 a of the support plate 11. Furthermore, the bolts 14 and 14 are arranged in a positional relationship corresponding to the bolt through holes 22b and 22b of the presser plate 22 on the solar panel 2 side.

  Two connection cables 7 and 7 from the controller 6 are passed through the circular boss 12, and connectors 7 a and 7 b provided at the ends of the connection cables 7 and 7 are located above the circular boss 12. I'm here.

  Next, the installation procedure of the solar panel 2 will be described with reference to FIGS.

  (1) The connectors 8a and 8b protruding from the lower end of the support pipe 21 of the solar panel 2 are connected to the connectors 7a and 7b protruding from the circular boss 12 of the pole 1, respectively.

  (2) While pushing the connecting portions of the connectors 8a and 8b on the solar panel 2 side and the connectors 7a and 7b on the pole 1 side into both the inside of the support pipe 21 and the inside of the pole 1, or either side, The lower end of the support pipe 21 is fitted into the circular boss 12 of the support plate 11, and the flange 23 at the lower end of the support pipe 21 is disposed on the support plate 11.

  Next, the bolt through holes 22 b of the presser plate 22 are aligned with the bolts 14 of the support plate 11, and the presser plate 22 is moved downward and placed on the flange 23. In this state, a plain washer 25 and a spring washer 26 are sequentially passed through the end portions of the bolts 14 protruding above the presser plate 22, and nuts 24 are screwed into the end portions of the bolts 14, respectively. At this time, fixing of the presser plate 22 by the nut 24 is temporarily fixed so that the solar panel 2 (flange 23) can rotate (rotate around the vertical axis) with respect to the pole 1.

  (3) At the place where the illuminating device (street light) L is installed, the solar panel 2 is rotated and the direction is adjusted (horizontal angle adjustment) so that the front surface (light receiving surface) of the solar panel 2 faces south. Then, with the solar panel 2 facing southward, each nut 24 is tightened (finally tightened) to fix the solar panel 2 to the pole 1 and to fix the horizontal angle of the solar panel 2 (see FIG. 5).

  According to the above mounting structure, in the temporarily fixed state of (2) described above, the flange 23 of the solar panel 2 is sandwiched between the presser plate 22 and the support plate 11, and the presser plate 22 and the support plate 11. Since the entire solar panel 2 is held by the operator, when the horizontal angle adjustment of the solar panel 2 is performed, the operator does not need to support the solar panel 2 and the horizontal angle adjustment work at a high place can be easily performed. Can do.

  Moreover, as shown in FIG. 5, the flange 23 of the solar panel 2 is connected to the lower surface 22 c of the presser plate 22 and the upper surface 11 a (support surface) of the support plate 11 with the presser plate 22 fully tightened (finally tightened with the nut 24). 9), the fixing force is larger than that of the mounting structure shown in FIG. 9, and the solar panel 2 can be firmly fixed with a stable force. Accordingly, even if strong wind or the like acts on the solar panel 2 after the press plate 22 is finally tightened, the solar panel 2 is not displaced in the rotational direction.

  Furthermore, since the fixing bolts 14 and nuts 24 are arranged at four positions symmetrical to each other with respect to the rotation center of the solar panel 2 (the rotation center of the support pipe 21), the flange 23 can be fixed on the surface. Therefore, the solar panel 2 can be reliably supported in a stable posture regardless of the direction from which the force is applied to the solar panel 2.

  The number of bolts and nuts for fixing the presser plate 22 is not particularly limited as long as the flange 23 can be fixed on the surface, and may be any number of three or five or more.

  Moreover, the shape of the flange fixed to the lower end of the support pipe 21 of the solar panel 2 is not limited to a square, and may be any other shape such as a circle.

  Furthermore, the shape of the through-hole (through-hole through which the support pipe 21 is passed) of the presser plate 22 is not limited to a circle, but may be any other shape such as a quadrangle. Further, instead of the presser plate having such a through hole, a presser plate 122 having a U-shaped notch 122a that can be fitted into the support pipe 21 is used as shown in FIGS. Also good. The shape of the notch is not limited to the U shape, and may be any other shape such as a quadrangle.

It is a perspective view which shows an example of the illuminating device to which the attachment structure of the solar panel of this invention is applied. It is a figure which writes together and shows the front view (A) of the illuminating device of FIG. 1, a side view (B), and a rear view (C). It is a disassembled perspective view which shows an example of the attachment structure of the solar panel of this invention. It is a principal part enlarged view of the attachment structure of FIG. It is principal part sectional drawing of the attachment structure of FIG. It is a side view of the lightbulb-type LED lamp used for the illuminating device of FIG. It is a disassembled perspective view which shows the other example of the attachment structure of the solar panel of this invention. FIG. 8 is a plan view of a presser plate used in the mounting structure of FIG. 7. It is a figure which shows an example of the attachment structure of the conventional solar panel.

Explanation of symbols

L Lighting device (street light)
1 pole
10 Base plate 11 Support plate 11a Upper surface of support plate (support surface)
14 bolts (planted bolts)
2 Solar panel 21 Support pipe 22 Presser plate 22a Through hole 22b Bolt through hole 22c Lower surface of presser plate 23 Flange 24 Nut 3 Main illumination light 4 Footlight 5 Storage battery 6 Controller

Claims (1)

A structure for mounting a solar panel to a support, comprising: a flange fixed to an end of a support member that supports the solar panel; and a press plate for pressing the flange from the solar panel side, In the state where the flange of the solar panel is placed on the support surface provided on the support plate, the press plate is fixed to the support column using a fixing means, so that the flange of the solar panel is connected to the press plate and the support surface. A solar panel mounting structure characterized by being fixed in a state of being sandwiched between them.

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