JP2014236167A - Solar panel unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a force required for adjusting the angle of a solar panel, in a solar panel unit for supporting the solar panel oscillatably.SOLUTION: A solar panel (30) is supported oscillatably by a support mechanism (40). At the upper end of a frame (41) in the support mechanism (40), pin members (44a, 44b) coupled with the solar panel (30) and constituting the central axis (56) of oscillating movement of the solar panel (30) are provided. Coupling members (32a, 32b) having tips (34) extending farther to the panel body (30a) side than the lower surface (31b) of a crosspiece member (31), and being coupled with the pin members (44a, 44b) rotatably are attached to the crosspiece member (31) which is fixed to the back of the panel body (30a).

Description

  The present invention relates to a solar panel unit that supports a solar panel in a swingable manner, and particularly relates to a solar panel support mechanism.

  Conventionally, it is known to increase the amount of light received and increase the amount of power generated by the solar panel by controlling the light receiving surface of the solar panel to face the sun. For example, Patent Document 1 discloses a solar panel unit that supports a solar panel so as to be swingable by a support member, and swings the solar panel according to the direction of the sun and maintains it at a predetermined angle by driving control of a pneumatic actuator. It is disclosed.

JP 2012-117273 A

  By the way, in the above-mentioned solar panel unit, a certain force is required to swing the solar panel and maintain it at a predetermined angle. This required force increases as the distance between the center axis of the swinging motion of the solar panel and the center of gravity of the solar panel increases. On the other hand, in the conventional solar panel unit described above, the central axis of the swinging motion of the solar panel is provided below the crosspiece member attached to the back surface of the solar panel. Therefore, in the above solar panel unit, there is a problem that a large force for adjusting the angle of the solar panel is required because the distance between the center axis of the swing motion and the center of gravity is large.

  This invention is made | formed in view of this point, The objective is to reduce the force required for angle adjustment of a solar panel.

  According to a first aspect of the present invention, there is provided a solar panel (30) having a panel body (30a) and a crosspiece member (31) fixed to the back surface of the panel body (30a), and swinging the solar panel (30). It is a solar panel unit provided with the support mechanism (40) supported so that it is possible.

  In the first aspect of the present invention, the support mechanism (40) is provided on a gantry (41) fixed to an installation portion of the solar panel (30), and an upper end portion of the gantry (41). A receiving member (44a, 44b) connected to the panel (30) and constituting the central axis (56) of the swinging motion of the solar panel (30), and the base member (31) has a base end The portion (33) is fixed to the crosspiece member (31), and the tip end portion (34) extends to the panel body (30a) side from the lower surface (31b) of the crosspiece member (31), and the receiving member (44a, The connecting member (32a, 32b) formed in the front-end | tip part (34) to which 44b) is rotatably connected is attached, It is characterized by the above-mentioned.

  In 1st invention, the front-end | tip part (34) of the connection member (32a, 32b) attached to the crosspiece member (31) of the back surface of a panel main body (30a) is rather than the lower surface (31b) of a crosspiece member (31). Since it extends to the panel main body (30a) side, the central axis (56) of the swinging motion constituted by the receiving members (44a, 44b) connected to the tip end portion (34) is also the same as the crosspiece member ( It is located closer to the panel body (30a) than the lower surface (31b) of 31). That is, the center axis (56) and the center of gravity of the solar panel (30) are relatively close to each other. Therefore, the moment generated around the central axis (56) due to the load of the solar panel (30) is smaller than when the central axis (56) and the center of gravity of the solar panel (30) are relatively separated from each other.

  In a second aspect based on the first aspect, the receiving member (44a, 44b) has an insertion shaft portion (46) constituting the central shaft (56), while the connecting member (32a, 32b) A shaft hole (35) into which the insertion shaft portion (46) is inserted is formed in the distal end portion (34).

  In the second invention, the rotatable connection between the receiving member (44a, 44b) and the connecting member (32a, 32b) is such that the insertion shaft portion (46) of the receiving member (44a, 44b) is connected to the connecting member (32a, 32b). This is realized by being inserted into the shaft hole (35) formed in the tip (34) of 32b).

  In a third aspect based on the second aspect, the connecting member (32a, 32b) has the base end (33) from the side surface (31a, 31c) to the lower surface (31b) of the crosspiece member (31). Formed in a fixed part (33) to be mounted over, and the tip part (34) is formed in a flat plate bearing part (34) bent from the fixed part (33) to the panel body (30a) side It is characterized by being comprised by the substantially U shape made.

  In 3rd invention, the connection member (32a, 32b) is comprised by the substantially U shape. The base end portion (33) of the connecting member (32a, 32b) is formed on the fixing portion (33) attached from the side surface (31a, 31c) to the lower surface (31b) of the crosspiece member (31). Moreover, the front-end | tip part (34) of a connection member (32a, 32b) is formed in the flat-plate-shaped bearing part (34) bent from this fixing | fixed part (33) to the panel main body (30a) side.

  In a fourth aspect based on the third aspect, the panel body (30a) is provided to be inclined with respect to a horizontal plane, and the receiving member (46) is provided on the front side surface (30c) of the panel body (30a). ) The lower receiving member (44a) provided near the upper side receiving member (44b) provided near the rear side surface (30d) of the panel body (30a), and the lower side and The upper receiving member (44a, 44b) includes an insertion shaft portion (46) extending in a direction from the front side surface (30c) side to the rear side surface (30d) side of the panel body (30a), and the connecting member ( 32a, 32b) includes a lower connecting member (32a) and an upper connecting member (32b) corresponding to the lower and upper receiving members (44a, 44b). 44a, 44b) is inserted into the shaft hole (35) toward the rear side surface (30d) of the panel body (30a). Characterized in that it is configured urchin.

  In the fourth aspect of the invention, the receiving member (44a, 44b) and the connecting member (32a, 32b) are provided in two upper and lower portions, and the insertion shaft portion (46) of each receiving member (44a, 44b) is common to each other. It is inserted in the axial hole (35) of each connection member (32a, 32b) toward the direction of.

  The panel body (30a) is provided to be inclined with respect to the horizontal plane. That is, the central axis (56) constituted by the upper and lower receiving members (44a, 44b) provided at the upper end of the gantry (41) is inclined with respect to the horizontal plane. The two upper and lower receiving members (44a, 44b) each include an insertion shaft portion (46) extending in a direction from the front side surface (30c) side to the rear side surface (30d) side of the panel body (30a). These insertion shaft portions (46) are inserted into shaft holes (35) formed in the tip end portions (34) of the connecting members (32a, 32b) toward the rear side surface (30d) of the panel body (30a). The Such insertion is realized by lifting the solar panel (30) so that the insertion shaft portion (46) and the shaft hole (35) face each other, and then sliding the solar panel (30) obliquely downward. .

  According to a fifth invention, in any one of the first to fourth inventions, the gantry (41) includes a support member (42) fixed to the installation portion, and an upper end portion of the support member (42). And a support member (43) to which the receiving member (44a, 44b) is attached at the upper end, and the support member (43) is detachable from the support member (42). Features.

  In 5th invention, the mount frame (41) is provided with the support member (43) which can be attached or detached with respect to this support | pillar member (42) and this support | pillar member (42). The support member (42) is fixed to the installation part. A support member (43) is provided at the upper end of the support member (42). Receiving members (44a, 44b) are attached to the upper end of the support member (43). Accordingly, the gantry (41) is not an integrally formed member, but can be divided into at least a support member (42) and a support member (43), and is configured by combining them.

  According to the present invention, the top end portion (34) of the crosspiece member (31) extends to the panel body (30a) side from the lower surface (31b) of the crosspiece member (31), and the receiving members (44a, 44b) can rotate. By attaching the connecting members (32a, 32b) connected to the solar panel (30), the moment generated around the central axis (56) due to the load of the solar panel (30) is reduced. The force required to maintain the angle can be made relatively small.

  According to the second invention, the receiving member (44a, 44b) is provided with the insertion shaft portion (46) constituting the central shaft (56), while the distal end portion (34 of the connecting member (32a, 32b) is provided. ) To form a shaft hole (35) into which the insertion shaft portion (46) is inserted, thereby realizing a rotatable connection between the receiving member (44a, 44b) and the connecting member (32a, 32b). The configuration can be simplified.

  According to the third aspect of the invention, since the connecting members (32a, 32b) are formed in a substantially U shape, the receiving members (44a, 44b) are brought close to the panel body (30a) with a small space. be able to.

  According to the fourth invention, the insertion shaft portion (46) of the receiving member (44a, 44b) is inserted into the shaft hole (35) toward the rear side surface (30d) of the panel body (30a). In the installation work of the solar panel unit (20a, 20b), the insertion shaft part (46) is inserted into the shaft hole (35) by lifting and sliding the solar panel (30). Such installation work can be facilitated without disassembling or assembling the constituent members.

  According to the fifth aspect of the invention, since the support member (43) can be attached to and detached from the support member (42), the gantry (41) has the support member (42) and the support member (43). Since they are configured in combination, it is sufficient that the installation work for the gantry (41) is sufficient to handle the members (42, 43), and the load on the operator in the installation work can be reduced.

1 is a perspective view illustrating a schematic configuration of a photovoltaic power generation system according to Embodiment 1. FIG. 1 is a side view showing a solar panel unit according to Embodiment 1. FIG. 1 is a perspective view showing a solar panel unit according to Embodiment 1. FIG. It is a perspective view which shows the assembly state of the solar panel unit which concerns on Embodiment 1. FIG. 3 is an enlarged side view of a lower part of a support member of a solar panel unit according to Embodiment 1. FIG. It is a side view which shows the solar panel unit which concerns on the modification of Embodiment 1. 5 is a side view showing a solar panel unit according to Embodiment 2. FIG. 10 is a side view showing a solar panel unit according to Modification 1 of Embodiment 2. FIG. 10 is a side view showing a solar panel unit according to Modification 2 of Embodiment 2. FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

Embodiment 1 of the Invention
A first embodiment of the present invention will be described.

  As shown in FIG. 1, the solar power generation system (10) includes a plurality of solar panel units (20a, 20b) according to the present embodiment. For convenience of explanation, in FIG. 1, the direction indicated by the arrow A is defined as the front, the direction indicated by the arrow B is defined as the rear, the direction indicated by the arrow C is defined as the right, and the direction indicated by the arrow D is defined as the left.

  The solar power generation system (10) can construct a large-scale power generation system by combining a plurality of the solar power generation systems (10). Although not shown, the solar power generation system (10) is provided with a power conditioner that converts DC power generated by the solar panel units (20a, 20b) into AC power.

  The photovoltaic power generation system (10) is configured by combining one first solar panel unit (20a) and a plurality of other second solar panel units (20b) (four in the example shown in FIG. 1). Has been. Each solar panel unit (20a, 20b) includes one solar panel (30), and the angle of the solar panel (30) is adjusted according to the position of the sun. The plurality of solar panel units (20a, 20b) are arranged in a line in the left-right direction (east-west direction).

  The first solar panel unit (20a) includes a drive mechanism (50) that swings the solar panel (30) to change the angle of the solar panel (30), and solar panels (20a, 20b) in each solar panel unit (20a, 20b). And a link mechanism (55) configured to synchronize the swinging of (30). The second solar panel unit (20b) is not provided with a drive mechanism (50) for swinging the solar panel (30), and the swing of the solar panel (30) of each solar panel unit (20a, 20b) is synchronized. Only the link mechanism (55) configured to be provided is provided.

  The first solar panel unit (20a) and each second solar panel unit (20b) are configured substantially in the same manner except for the presence or absence of the drive mechanism (50). Specifically, each solar panel unit (20a, 20b) includes a solar panel (30) and a support mechanism (40) that supports the solar panel (30) in a swingable manner.

  As shown in FIGS. 2 to 4, the support mechanism (40) has a gantry (41) fixed to the installation portion. The gantry (41) includes a support member (42) fixed to the installation part and a support member (43) provided at the upper end of the support member (42). Receiving members (44a, 44b) are attached to the upper end of the support member (43).

  The support member (42) is a prismatic member extending in the vertical direction. As shown in FIG. 5, a taper portion (47) protruding downward is formed at the lower end portion of the support member (43). That is, the support member (43) of the present embodiment is configured by a pile fixed to the ground (G) by inserting the tapered portion (47) into the ground (G) as an installation portion, for example. On both side surfaces in the front-rear direction at the upper end of the column member (42), a hollow rectangular tube-shaped tubular portion (42a) extending in the vertical direction is fixed so as to open upward. The cylindrical portion (42a) is fitted with the lower end of the leg portion (43a) formed on the support member (43). That is, the cylindrical part (42a) constitutes an insertion part having a space in which the leg part (43a) can be inserted.

  The support member (43) is composed of a pair of leg portions (43a) and one plate-like portion (43b). The lower end part of a pair of leg part (43a) comprises the protrusion part (48) which protrudes toward the downward direction (namely, support | pillar member (42)). The protrusion (48) is supported by the column member (42) by fitting inside the cylindrical portion (42a). The pair of leg portions (43a) extends upward while being spaced apart from each other in the front-rear direction in a state where each protrusion (48) is inserted into the tubular portion (42a). The plate-like portion (43b) is fixed to the upper end portions of these leg portions (43a), and is inclined obliquely with respect to the horizontal plane so that the rear end thereof is located above the front end. The plate-like part (43b) is a member that is bent so that its longitudinal section is substantially U-shaped (substantially U-shaped), and opens downward to cover the upper end of each leg part (43a). ing.

  As shown in FIG. 4, the support member (43) can be attached to and detached from the support member (42). The support member (43) is attached to the column member (42) by inserting the protruding portions (48) of the pair of leg portions (43a) into the cylindrical portion (42a). Therefore, the support member (43) can be removed from the support member (42) by lifting the support member (43) and extracting each leg portion (43a) from the tubular portion (42a).

  A pair of receiving members (44a, 44b) are provided on the upper end of the gantry (41), that is, on the upper surface of the plate-like portion (43b) of the support member (43). The pair of receiving members (44a, 44b) is connected to the solar panel (30) and constitutes the central axis (56) of the swinging motion of the solar panel (30). The pair of receiving members (44a, 44b) are arranged at a predetermined interval in the axial direction of the central axis (56). The receiving member (44a, 44b) is composed of a pin member (44a, 44b). The pin member (44a, 44b) is provided near the lower side pin member (44a) provided near the front side surface (30c) of the panel body (30a) and the rear side surface (30d) of the panel body (30a). And an upper pin member (44b). The lower pin member (44a) is provided at the front end of the upper surface of the plate-like portion (43b), and the upper pin member (44b) is provided at the rear end of the upper surface of the plate-like portion (43b). .

  The pin members (44a, 44b) are composed of rod-like members bent in an L shape. Specifically, the pin member (44a, 44b) includes a connecting portion (45) and an insertion shaft portion (46). The connecting portion (45) is an elongated columnar member, and extends upward from the upper surface of the plate-like portion (43b) perpendicularly to the upper surface of the plate-like portion (43b). The insertion shaft portion (46) is an elongated cylindrical member, and extends rearward in parallel with the plate-like portion (43b) continuously from the tip of the connecting portion (45). An annular flange portion (46a) is formed in the vicinity of the distal end portion of the insertion shaft portion (46) so as to protrude radially outward. The collar portion (46a) constitutes a contact portion (stopper) that restricts the downward movement of the connecting member (32a) by contacting the connecting member (32a). The insertion shaft portion (46) extends in a direction from the front side surface (30c) side to the rear side surface (30d) side of the panel body (30a). That is, the insertion shaft portion (46) has an axis that is inclined obliquely with respect to the horizontal plane. The insertion shaft part (46) constitutes the central axis (56) of the swinging motion of the solar panel (30).

  As shown in FIGS. 2 and 3, the solar panel (30) includes a panel body (30a) and a plurality of (two in the example of this embodiment) crosspiece members fixed to the back surface of the panel body (30a). (31). The panel body (30a) is formed in a rectangular plate shape that is flat vertically. In the panel body (30a), one of the two side surfaces orthogonal to the axial direction of the central axis (56) is the front side surface (30c) closest to the installation portion, and the other side surface facing the front side surface (30c) The side surface is inclined so as to be the rear side surface (30d) farthest from the installation portion. The surface of the panel body (30a) constitutes a light receiving surface (30b). The solar panel (30) generates direct-current power by receiving sunlight at the light receiving surface (30b).

  The two cross members (31) are fixed to the back surface of the panel body (30a). These crosspiece members (31) are arranged at predetermined intervals in the axial direction of the central axis (56). One crosspiece member (31) of the two crosspiece members (31) is provided between the front end of the back surface of the panel main body (30a) and the middle portion in the front-rear direction of the panel main body (30a). The other crosspiece member (31) of the two crosspiece members (31) is provided between the rear end of the back surface of the panel main body (30a) and the intermediate portion in the front-rear direction of the panel main body (30a). The crosspiece member (31) is an elongated prismatic member extending in the left-right direction so as to be orthogonal to the central axis (56). The top surface of the crosspiece member (31) is joined to the back surface of the panel body (30a). The crosspiece member (31) extends across the left and right ends of the panel body (30a).

  The connecting members (32a, 32b) are fixed to intermediate portions in the left-right direction of the crosspiece members (31), respectively. The connecting member (32a, 32b) includes a lower connecting member (32a) and an upper connecting member (32b) corresponding to the lower and upper pin members (44a, 44b). The connecting members (32a, 32b) are configured in a substantially U shape (substantially U shape) that opens upward. The connecting member (32a, 32b) has a proximal end portion (33) and a distal end portion (34).

  The base end portion (33) is formed in a fixing portion (33) attached from the rear surface (31c) to the lower surface (31b) of the crosspiece member (31). The fixing portion (33) is continuous with the vertical wall portion (33a) along the rear surface (31c) of the crosspiece member (31) and the lower end portion of the vertical wall portion (33a), and the rear side surface of the panel body (30a). It is comprised with the horizontal wall part (33b) extended in the direction which goes to the front side surface (30c) side from the (30d) side. The front end portion (34) is formed in a flat plate bearing portion (34) and is bent upward from the front end of the fixed portion (33) (that is, the front end portion of the lateral wall portion (33b)) toward the panel body (30a). ing. That is, the bearing portion (34) extends to the panel body (30a) side from the lower surface (31b) of the crosspiece member (31). A shaft hole (35) having an inner diameter slightly larger than the outer diameter of the insertion shaft portion (46) of the pin member (44a, 44b) is formed in the bearing portion (34). These shaft holes (35) are formed inside a bearing (not shown) held in a through hole formed in the bearing portion (34). That is, the bearing supports the insertion shaft portion (46) of the pin member (44a, 44b) so as to be swingable.

  As shown in FIGS. 2 and 3, the solar panel (30) includes the insertion shaft portion (46) of the lower side and upper side pin members (44a, 44b) and the lower side and upper side connection members (32a, The support mechanism (40) is swingably supported by being inserted into shaft holes (35) formed in the bearing portion (34) of 32b). Each insertion shaft portion (46) is inserted into the shaft hole (35) toward the rear side surface (30d) of the panel body (30a).

  In the state where the panel body (30a) is supported by the support mechanism (40), the outer edge of the shaft hole (35) on the front surface of the bearing portion (34) contacts the flange (46a) of the insertion shaft portion (46). Touch. Thereby, it is controlled that a connection member (32a, 32b) and by extension, a solar panel (30) move below, and the solar panel (30) is positioned. The shaft hole (35) is formed in the bearing portion (34) located closer to the panel body (30a) than the lower surface (31b) of the crosspiece member (31). For this reason, the distance between the central shaft (56) constituted by the insertion shaft portion (46) and the back surface of the panel body (30a) is such that the lower surface (31b) of the crosspiece member (31) and the panel body (30a) It becomes smaller than the distance between the back.

  As shown in FIG. 2, the first solar panel unit (20a) is provided with a drive mechanism (50). The drive mechanism (50) includes an actuator (51), a pulley (52), a wire (53), and a pulley (54).

  The actuator (51) is provided on the lower surface of the plate-like portion (43b) of the support member (43). The actuator (51) swings the solar panel (30) and maintains it at a predetermined angle. The actuator (51) is, for example, a rotary pneumatic actuator.

  The actuator (51) includes a main body (51a) attached and fixed to the lower surface of the plate-like portion (43b), and a power transmission shaft (51b) extending upward from the center of the upper surface of the main body (51a). A disc-shaped pulley (52) is attached to the tip of the power transmission shaft (51b). That is, the pulley (52) is driven to rotate by the power transmission shaft (51b). One end of each of the two wires (53) is fixed to the peripheral edge of the pulley (52). The other end of each of these wires (53) is connected to the lower side connecting member (32a) via a pulley (54) protruding from the upper surface of the plate-like part (43b) on the front side of the actuator (51). It is fixed on the back. The other end of the one wire (53) is fixed to the left side (the front side in FIG. 2) of the central axis (56) on the rear surface of the connecting member (32a). The other end of the other wire (53) is fixed to the right side (the back side in FIG. 2) of the central axis (56) on the rear surface of the connecting member (32a). The distance between the portion where the other end of the wire (53) is fixed and the central axis (56) is set smaller than the radius of the pulley (52). Therefore, the swing angle of the solar panel (30) is larger than the rotation angle of the power transmission shaft (51b) of the actuator (51).

-Driving action-
In the solar power generation system (10) configured with the solar panel units (20a, 20b) of the present embodiment, the angle of the solar panel (30) is adjusted according to the direction of sunlight.

  In this solar power generation system (10), for example, a solar radiation sensor (not shown) is provided to detect the direction of the sun. Then, the actuator (51) of the first solar panel unit (20a) is controlled so that the solar panel (30) faces the sun.

  When the actuator (51) of the first solar panel unit (20a) is driven, the power transmission shaft (51b) rotates. The rotational force is transmitted to the connecting member (32a) via the pulley (52) and the wire (53), and the solar panel (30) swings about the central axis (56). By this swinging, the solar panel (30) is adjusted to an angle at which the light receiving surface (30b) faces the sun. At this time, the solar panels (30) of the plurality of second solar panel units (20b) in the solar power generation system (10) are connected to the solar panels of the first solar panel unit (20a) via the link mechanism (55). Adjusted to the same angle as 30).

-Solar panel unit installation work-
Next, installation work for installing each solar panel unit (20a, 20b) in a predetermined installation part will be described with reference to FIG. In addition, the solar panel unit (20a, 20b) of this example is installed on the ground (G) which is an installation part.

  Prior to the installation work of the solar panel units (20a, 20b), the first to third units (U1, U2, U3) are manufactured in a factory or the like. The first unit (U1) is composed of the above-described support member (42). The second unit (U2) is configured by the support member (43) described above. The third unit (U3) includes a solar panel (30) and connecting members (32a, 32b) fixed to the crosspiece members (31) of the solar panel (30). Since these units (U1, U2, U3) are configured separately, their weight and size are reduced. Therefore, each unit (U1, U2, U3) can be easily transferred to the site.

  In the installation work of the solar panel units (20a, 20b), first, a step (first step) of fixing the column member (42), which is the first unit (U1), to the installation portion is performed. In this first step, the tapered portion (47) of the support member (42) is hit against the ground (G), and the support member (42) is fixed to the installation portion in a vertical state (see FIG. 5).

  After the first step, a step (second step) of attaching the support member (43), which is the second unit (U2), to the support member (42) is performed. In the second step, the lower end portion (projection portion (48)) of the leg portion (43a) of the support member (43) is inserted into the cylindrical portion (42a) of the support member (42). As a result, the projecting portion (48) is fitted inside the cylindrical portion (42a), and the support member (43) is supported above the support member (42).

  After the second step, a step (third step) of attaching the third unit (U3) (the solar panel (30) and the receiving members (44a, 44b)) above the support member (43) is performed. . That is, in the third step, the third unit (U3) is attached to the support member (43) so that the solar panel (30) is supported above the support mechanism (40). In the third step, the connecting members (32a, 32b) of the third unit (U3) are positioned obliquely above the corresponding pin members (44a, 44b). Then, the third unit (U3) is inserted in the axial direction of the central axis (56) so that the insertion shaft portion (46) of each pin member (44a, 44b) is inserted into the corresponding shaft hole (35). Slide diagonally downward along When the insertion shaft portion (46) is further slid inside the shaft hole (35), the outer edge portion of the shaft hole (35) comes into contact with the flange portion (46a) of the insertion shaft portion (46). Thereby, the further downward movement of the connecting member (32a, 32b) is restricted, and the relative positions of the pin member (44a, 44b) and the connecting member (32a, 32b) are determined.

  Thus, in the installation work of the solar panel units (20a, 20b) of the present embodiment, the three divided units (U1, U2, U3) are assembled in order. For this reason, each unit (U1, U2, U3) is reduced in weight, and the work load of each process mentioned above is reduced. Specifically, for example, when these units (U1, U2, U3) are integrated, the column member (42) is placed on the ground while lifting the relatively heavy solar panel units (20a, 20b). It is necessary to hit (G), the installation work becomes complicated, and the work time is prolonged. On the other hand, in this embodiment, since each unit (U1, U2, U3) which is comparatively light is handled in the installation work, the installation work becomes easy and the working time can be shortened.

-Effect of Embodiment 1-
In the solar panel unit (20a, 20b) of the present embodiment, the central axis (56) of the rocking motion constituted by the lower and upper pin members (44a, 44b) is the lower surface of the crosspiece member (31) ( 31b) closer to the panel body (30a). That is, the center axis (56) and the center of gravity of the solar panel (30) are relatively close to each other. Therefore, since the moment generated around the central axis (56) due to the load on the solar panel (30) is reduced, the force for swinging the solar panel (30) and maintaining it at a predetermined angle should be made relatively small. Can do.

  The gantry (41) includes a support member (42) and a support member (43). The support member (43) can be attached to and detached from the support member (42). Therefore, the installation work of the gantry (41) is sufficient if there is enough force to handle each member (42, 43), and the load on the worker in such installation work can be reduced.

  The rotatable connection between the pin member (44a, 44b) and the connecting member (32a, 32b) is achieved by connecting the insertion shaft portion (46) of the pin member (44a, 44b) to the bearing portion of the connecting member (32a, 32b) ( This is realized by inserting into the shaft hole (35) formed in 34). Therefore, the configuration for realizing the rotatable connection between the pin members (44a, 44b) and the connection members (32a, 32b) can be simplified.

  The panel body (30a) is provided to be inclined with respect to the horizontal plane, and has a front side surface (30c) close to the installation portion and a rear side surface (30d) far from the installation portion. Further, the insertion shaft portions (46) of the lower side and upper side pin members (44a, 44b) both extend in the direction from the front side surface (30c) side toward the rear side surface (30d) side. On the other hand, the lower and upper connecting members (32a, 32b) include a fixing portion (33) attached from the rear surface (31c) to the lower surface (31b) of the crosspiece member (31), and the fixing portion (33). And a bearing portion (34) formed by bending upward from the front end toward the panel body (30a). A shaft hole (35) corresponding to the insertion shaft portion (46) is formed in the bearing portion (34). Since the insertion shaft portion (46) is inserted into the shaft hole (35) by lifting and sliding the solar panel (30), disassembling and assembling components in the installation work of the solar panel unit (20a, 20b). This installation work can be facilitated.

-Modification of Embodiment 1-
In the solar panel unit (20a, 20b) of the first embodiment, as shown in FIG. 6, the position of the crosspiece member (31) provided on the back surface of the panel body (30a) may be changed.

  Specifically, in the solar panel unit (20a, 20b) of the present modification shown in FIG. 6, crosspiece members (31) are provided at both ends in the front-rear direction on the back surface of the panel body (30a). Further, the lower side and upper side pin members (44a, 44b) are provided on the upper surface of the plate-like portion (43b) corresponding to each crosspiece member (31).

<< Embodiment 2 of the Invention >>
A second embodiment of the present invention will be described. In the present embodiment, in the solar panel unit (20a, 20b) of the first embodiment, the configuration of the pin members (44a, 44b) and the connecting members (32a, 32b) is changed. Here, the solar panel unit (20a, 20b) of the present embodiment will be described with respect to differences from the first embodiment with reference to FIG.

  As shown in FIG. 7, the insertion shaft portion (46) of the pin member (44b) on the upper side extends in the direction from the front side surface (30c) side to the rear side surface (30d) side of the panel body (30a). . On the other hand, the insertion shaft portion (46) of the lower pin member (44a) extends in the direction from the rear side surface (30d) side to the front side surface (30c) side of the panel body (30a). The insertion shaft part (46) constitutes the central axis (56) of the swinging motion of the solar panel (30).

  The lower side and upper side connecting members (32a, 32b) are configured in a substantially U-shape (substantially U-shape) that opens upward. The base end portion (33) of the lower connecting member (32a) is formed on a fixing portion (33) attached from the front surface (31a) to the lower surface (31b) of the crosspiece member (31). The fixing portion (33) is continuous with the vertical wall portion (33a) along the front surface (31a) of the crosspiece member (31) and the lower end portion of the vertical wall portion (33a), and is the front side surface of the panel body (30a). It is comprised with the horizontal wall part (33b) extended in the direction which goes to a rear side surface (30d) side from the (30c) side. The tip end portion (34) of the lower side connecting member (32a) is formed in a flat plate bearing portion (34) and is bent upward from the tip end of the fixed portion (33) toward the panel body (30a). . On the other hand, the base end part (33) of the connection member (32b) on the upper side is formed on the fixing part (33) attached from the rear surface (31c) to the lower surface (31b) of the crosspiece member (31). The fixing portion (33) is continuous with the vertical wall portion (33a) along the rear surface (31c) of the crosspiece member (31) and the lower end portion of the vertical wall portion (33a), and the rear side surface of the panel body (30a). It is comprised with the horizontal wall part (33b) extended in the direction which goes to the front side surface (30c) side from the (30d) side. The tip (34) of the upper connecting member (32b) is formed in a flat plate bearing (34) and is bent upward from the tip of the fixed part (33) toward the panel body (30a). . Each bearing portion (34) is formed with a shaft hole (35) having an inner diameter slightly larger than the outer diameter of the insertion shaft portion (46) of the pin member (44a, 44b).

  As shown in FIG. 7, the solar panel (30) includes the insertion shaft portions (46) of the lower and upper side pin members (44a, 44b) and the lower side and upper side connecting members (32a, 32b). By being inserted into shaft holes (35) formed in the bearing portion (34), the support mechanism (40) is swingably supported. The insertion shaft portion (46) of the lower pin member (44a) is inserted into the shaft hole (35) toward the front side surface (30c) of the panel body (30a). On the other hand, the insertion shaft portion (46) of the upper pin member (44b) is inserted into the shaft hole (35) toward the rear side surface (30d) of the panel body (30a). Other configurations are the same as those of the first embodiment.

-Effect of Embodiment 2-
In the solar panel unit (20a, 20b) of the present embodiment, the central axis (56) of the rocking motion constituted by the lower and upper pin members (44a, 44b) is the lower surface of the crosspiece member (31) ( 31b) closer to the panel body (30a). That is, the center axis (56) and the center of gravity of the solar panel (30) are relatively close to each other. Therefore, since the moment generated around the central axis (56) due to the load on the solar panel (30) is reduced, the force for swinging the solar panel (30) and maintaining it at a predetermined angle should be made relatively small. Can do.

  The gantry (41) includes a support member (42) and a support member (43). The support member (43) can be attached to and detached from the support member (42). Therefore, the installation work of the gantry (41) is sufficient if there is enough force to handle each member (42, 43), and the load on the worker in such installation work can be reduced.

  A rotatable connection between the pin member (44a, 44b) and the connecting member (32a, 32b), the pin member (44a, 44b) is a shaft hole formed in the bearing portion (34) of the connecting member (32a, 32b) It is realized by inserting it into (35). Therefore, the configuration for realizing the rotatable connection between the pin members (44a, 44b) and the connection members (32a, 32b) can be simplified.

-Modification 1 of Embodiment 2
In the solar panel unit (20a, 20b) of the second embodiment, as shown in FIG. 8, the position of the crosspiece member (31) provided on the back surface of the solar panel (30) may be changed.

  Specifically, in the solar panel unit (20a, 20b) of Modification 1 shown in FIG. 8, the crosspiece members (31) are provided at both ends in the front-rear direction on the back surface of the solar panel (30). Further, the lower side and upper side pin members (44a, 44b) are provided on the upper surface of the plate-like portion (43b) corresponding to each crosspiece member (31).

-Modification 2 of Embodiment 2
In the solar panel unit (20a, 20b) of the second embodiment, as shown in FIG. 9, the position of the crosspiece member (31) provided on the back surface of the panel body (30a) is changed, and the pin member (44a, 44b) The configuration of the connecting members (32a, 32b) may be changed.

  Specifically, in the solar panel unit (20a, 20b) of the second modification shown in FIG. 9, crosspiece members (31) are provided at both ends in the front-rear direction on the back surface of the panel body (30a). Further, the lower side and upper side pin members (44a, 44b) are provided on the upper surface of the plate-like portion (43b) corresponding to each crosspiece member (31).

  The insertion shaft portion (46) of the lower pin member (44a) extends in a direction from the front side surface (30c) side to the rear side surface (30d) side of the panel body (30a). On the other hand, the insertion shaft portion (46) of the upper pin member (44b) extends in the direction from the rear side surface (30d) side of the panel body (30a) toward the front side surface (30c) side. The insertion shaft part (46) constitutes the central axis (56) of the swinging motion of the solar panel (30).

  The lower side and upper side connecting members (32a, 32b) are configured in a substantially U-shape (substantially U-shape) that opens upward. The base end portion (33) of the lower connecting member (32a) is formed in a fixing portion (33) attached from the rear surface (31c) to the lower surface (31b) of the crosspiece member (31). The fixing portion (33) is continuous with the vertical wall portion (33a) along the rear surface (31c) of the crosspiece member (31) and the lower end portion of the vertical wall portion (33a), and the rear side surface of the panel body (30a). It is comprised with the horizontal wall part (33b) extended in the direction which goes to the front side surface (30c) side from the (30d) side. The tip end portion (34) of the lower side connecting member (32a) is formed in a flat plate bearing portion (34) and is bent upward from the tip end of the fixed portion (33) toward the panel body (30a). . On the other hand, the base end part (33) of the connection member (32b) on the upper side is formed on the fixing part (33) attached from the front surface (31a) to the lower surface (31b) of the crosspiece member (31). The fixing portion (33) is continuous with the vertical wall portion (33a) along the front surface (31a) of the crosspiece member (31) and the lower end portion of the vertical wall portion (33a), and is the front side surface of the panel body (30a). It is comprised with the horizontal wall part (33b) extended in the direction which goes to a rear side surface (30d) side from the (30c) side. The tip end portion (34) of the upper connecting member (32b) is formed in the bearing portion (34) and is bent upward from the tip end of the fixed portion (33) toward the panel body (30a). Each bearing portion (34) is formed with a shaft hole (35) having an inner diameter slightly larger than the outer diameter of the insertion shaft portion (46) of the pin member (44a, 44b).

  In the solar panel (30), the insertion shaft part (46) of the lower side and upper side pin members (44a, 44b) is formed in the bearing part (34) of the lower side and upper side coupling members (32a, 32b). By being inserted into the respective shaft holes (35), the support mechanism (40) is swingably supported. The insertion shaft portion (46) of the lower pin member (44a) is inserted into the shaft hole (35) toward the rear side surface (30d) of the panel body (30a). On the other hand, the insertion shaft portion (46) of the upper pin member (44b) is inserted into the shaft hole (35) toward the front side surface (30c) of the panel body (30a).

<< Other Embodiments >>
In each of the above embodiments, the receiving member (44a, 44b) has the insertion shaft portion (46) and the connecting member (32a, 32b) is formed with the shaft hole (35). A shaft hole may be formed in the receiving member (44a, 44b), and the connecting member (32a, 32b) may have an insertion shaft portion.

  In each of the above embodiments, two connecting members (32a, 32b) and two pin members (44a, 44b) are provided. However, the present invention is not limited to this, and one connecting member (32a, 32b) may be provided. Three or more of each may be provided.

  Furthermore, in each said embodiment, although the connection member (32a, 32b) in which a shaft hole (35) is formed is a substantially U-shaped (substantially U-shaped) member, it is not restricted to this, A shaft hole (35 ) Is formed at a position closer to the panel body (30a) than the lower surface (31b) of the crosspiece member (31), it may be a member having any other shape.

  In each of the above embodiments, the support member (43) can be attached to and detached from the support member (42). However, the support member (43) is not limited to this. For example, the support member (43) is fixed to the support member (42). Alternatively, the support member (43) and the support member (42) may be integrally formed.

  As described above, the present invention is useful for a solar panel unit that supports a solar panel in a swingable manner.

10 Solar power generation system
20a First solar panel unit
20b Second solar panel unit
30 solar panels
30a Panel body
30c front side
30d rear side
31 Crosspiece
31a Front (side)
31b Bottom
31c Rear (side)
32a Connecting member on the lower side
32b Upper connection member
33 Base end, fixed part
34 Tip, bearing
35 Shaft hole
40 Support mechanism
41 frame
42 Prop member
43 Support members
44a Lower pin member (receiving member)
44b Pin member on the upper side (receiving member)
56 Center axis

Claims (5)

A solar panel (30) comprising a panel body (30a) and a crosspiece member (31) fixed to the back surface of the panel body (30a);
A solar panel unit (20a, 20b) comprising a support mechanism (40) for swingably supporting the solar panel (30),
The support mechanism (40) is provided on a gantry (41) fixed to an installation portion of the solar panel (30), an upper end of the gantry (41), and is connected to the solar panel (30) and Receiving members (44a, 44b) constituting the central axis (56) of the swinging motion of the solar panel (30),
A base end portion (33) is fixed to the crosspiece member (31), and a tip end portion (34) is located on the panel body (30a) more than the lower surface (31b) of the crosspiece member (31). ) Side, and a connecting member (32a, 32b) formed at the tip (34) to which the receiving member (44a, 44b) is rotatably connected is attached. In claim 1,
While the receiving member (44a, 44b) has an insertion shaft portion (46) constituting the central shaft (56),
A solar panel unit, characterized in that a shaft hole (35) into which the insertion shaft portion (46) is inserted is formed at a distal end portion (34) of the connecting member (32a, 32b). In claim 2,
The connecting member (32a, 32b) is formed in a fixing portion (33) in which the base end portion (33) is attached from the side surface (31a, 31c) to the lower surface (31b) of the crosspiece member (31). In addition, the tip end portion (34) is configured in a substantially U shape formed in a flat plate bearing portion (34) bent from the fixing portion (33) to the panel body (30a) side. A featured solar panel unit. In claim 3,
The panel body (30a) is provided with an inclination,
The receiving member (46) is provided near the lower side receiving member (44a) provided near the front side surface (30c) of the panel body (30a) and the rear side surface (30d) of the panel body (30a). And a receiving member (44b) on the upper side,
The lower and upper receiving members (44a, 44b) include an insertion shaft portion (46) extending in a direction from the front side surface (30c) side to the rear side surface (30d) side of the panel body (30a),
The connecting member (32a, 32b) includes a lower connecting member (32a) and an upper connecting member (32b) corresponding to the lower and upper receiving members (44a, 44b), The insertion shaft portion (46) of the receiving member (44a, 44b) is configured to be inserted into the shaft hole (35) toward the rear side surface (30d) of the panel body (30a). A solar panel unit. In any one of Claims 1-4,
The gantry (41) is provided with a support member (42) fixed to the installation portion, and a support member (44a, 44b) attached to the upper end of the support member (44a, 44b) provided at the upper end of the support member (42). 43)
The solar panel unit, wherein the support member (43) is detachable from the support member (42).

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