JP6260269B2 - Installation method of photovoltaic power generation system and photovoltaic power generation system - Google Patents

Description

    The present invention relates to a solar power generation system installation method and a solar power generation system including a plurality of solar panel units each including a solar panel and a support frame.

    Conventionally, a plurality of solar panel units each having a solar panel and a support base that rotatably supports the solar panel around a rotation axis, an actuator that rotationally drives a predetermined solar panel, A solar power generation system including a link mechanism for transmitting the rotational driving force of an actuator to all solar panels is known (for example, see Patent Document 1 below). The link mechanism is provided between each solar panel unit, and is pinned to a rotating member fixed to each of the two solar panels so that the rotating operations of the two adjacent solar panels are synchronized. It is comprised by the connecting rod connected with the member. In the solar power generation system, when the actuator is operated so that the predetermined solar panel follows the movement of the sun, the rotation driving force by the actuator rotates the solar panel unit via the connecting rod. Each solar panel is rotated around the rotation axis together with the rotating members. As a result, since all the solar panels follow the movement of the sun, the amount of received light in the solar power generation system increases and the power generation amount increases.

JP2013-142477A

    By the way, in the said photovoltaic power generation system, in order for the rotation operation of two solar panels to synchronize, from each rotating shaft of the two solar panel units connected with a connection rod to the pin member which connects a connection rod And the length of the connecting rod (distance between the pin members) must be equal to the distance between the solar panel units connected by the connecting rod (interval of the rotating shaft). Therefore, the length of the connecting rod is designed to be equal to the distance between the solar panel units.

    However, if the installation position of the solar panel unit is deviated from the designed installation position, the length of the connecting rod and the interval between the solar panel units are not equal, and the solar panels of the two solar panel units connected by the connecting rod are not the same. The rotation operation of the light panel is not synchronized. As a result, there has been a problem that the light receiving surface of the solar panels of some of the solar panel units does not follow the direction of sunlight and the amount of power generation is reduced. On the other hand, since it is difficult to accurately install a plurality of support frames at the designed installation positions, it has been desired to facilitate the installation work.

    This invention is made | formed in view of such a point, In a solar power generation system provided with the several solar panel unit, it is an easy installation operation | work, and a several solar panel unit is mutually connected with a solar panel. It aims at providing the installation method installed so that the rotation angle of may not shift, and the photovoltaic power generation system suitable for the installation method.

    The first invention is a solar panel (11) and a rotating shaft (s) that is fixed to the solar panel (11) and is positioned at a central portion in the width direction of the solar panel (11). A support frame having a freely configured rotating member (13) and supporting the solar panel (11) rotatably about the rotation axis (s) via the rotating member (13); 12), a plurality of solar panel units (10) installed such that the rotation axes (s) are parallel to each other at installation positions arranged in a straight line, and any one of the solar panels An actuator (51) connected to the rotating member (13) fixed to (11) and rotating the solar panel (11) about the rotation axis (s); and each solar panel unit ( 10), and the two solar panels (11) adjacent to each other are synchronized so that the rotational movements of the two solar panels (11) are synchronized. A solar power generation system installation method comprising a connecting rod (61) for connecting the rotating member (13) fixed to a sunlight panel (11), wherein the plurality of solar panel units (10) , An installation process for installing at each installation position, a fixing process for bringing the plurality of solar panels (11) into a fixed state in which the rotation is prevented at the same rotation angle after the installation process is completed, and the fixing After completion of the process, the connecting step of adjusting the length of the connecting rod (61) to connect the two rotating members (13) with the connecting rod (61), and after the connecting step, the fixing A fixing release step of releasing the fixed state of the solar panel (11) fixed in the step.

    In the first invention, after the plurality of solar panel units (10) are installed at the respective installation positions, the plurality of solar panels (11) are in a fixed state in which they do not rotate at the same rotation angle. The length of the connecting rod (61) is adjusted, and the rotating members (13) of two adjacent solar panel units (10) are connected by the connecting rod (61). Thus, by fixing the rotation angle of the two rotating members (13) connected by the connecting rod (61), the connecting rod (61) between the two rotating members (13) is connected. The distance between the connected portions becomes equal to the interval between the solar panel units (10) (the interval between the rotation axes (s)). In this state, the installation position of the solar panel unit (10) is shifted from the design position by adjusting the length of the connecting rod (61) and connecting the two rotating members (13). However, the length of the connecting rod (61) is equal to the interval between the two solar panel units (10) connected by the connecting rod (61) (the interval between the rotation axes (s)). As a result, the two solar panels (11) connected by the connecting rod (61) rotate at the same rotation angle (the rotation operation is synchronized).

    In a second aspect based on the first aspect, in the fixing step, the plurality of solar panels (11) are rotated at a rotation angle in which the width direction of each solar panel (11) is a horizontal direction. To a fixed state where is blocked.

    In the second invention, the plurality of solar panels (11) are fixed so as not to rotate at a rotation angle in which the width direction of each solar panel (11) is the horizontal direction, and the connecting rod (61) It is supposed to perform the connection work by. In the solar panel (11), there is a possibility that the angle may be shifted due to the strong wind. By setting the rotation angle to such a fixed state, the pressure receiving area with respect to the wind can be suppressed to be small. .

The third invention is a solar panel (11) and a rotating shaft (s) that is fixed to the solar panel (11) and is positioned at the center in the width direction of the solar panel (11). A support frame having a freely configured rotating member (13) and supporting the solar panel (11) rotatably about the rotation axis (s) via the rotating member (13); 12), a plurality of solar panel units (10) installed such that the rotation axes (s) are parallel to each other at installation positions arranged in a straight line, and any one of the solar panels An actuator (51) connected to the rotating member (13) fixed to (11) and rotating the solar panel (11) about the rotation axis (s); and each solar panel unit ( 10), and the two solar panels (11) adjacent to each other are synchronized so that the rotational movements of the two solar panels (11) are synchronized. A photovoltaic power generation system comprising a connecting rod (61) for connecting the rotating member (13) fixed to a sunlight panel (11), wherein the connecting rod (61) is an adjustment for adjusting the length. It has a mechanism (70), and the plurality of solar panels (11) are configured to be fixed at the same predetermined rotation angle .

    In the third aspect of the invention, the connecting rod (61) for connecting the rotating members (13) of the two adjacent solar panel units (10) has the adjusting mechanism (70) for adjusting the length. Yes. Therefore, when connecting the rotating members (13) of the plurality of solar panel units (10) by the connecting rod (61), the length of the connecting rod (61) is connected by the connecting rod (61). The length can be adjusted to be equal to the distance between the two solar panel units (10).

The fourth invention is a solar panel (11) and a rotating shaft (s) that is fixed to the solar panel (11) and is positioned at the center in the width direction of the solar panel (11). A support frame having a freely configured rotating member (13) and supporting the solar panel (11) rotatably about the rotation axis (s) via the rotating member (13); 12), a plurality of solar panel units (10) installed such that the rotation axes (s) are parallel to each other at installation positions arranged in a straight line, and any one of the solar panels An actuator (51) connected to the rotating member (13) fixed to (11) and rotating the solar panel (11) about the rotation axis (s); and each solar panel unit ( 10), and the two solar panels (11) adjacent to each other are synchronized so that the rotational movements of the two solar panels (11) are synchronized. A photovoltaic power generation system comprising a connecting rod (61) for connecting the rotating member (13) fixed to a sunlight panel (11), wherein the connecting rod (61) is an adjustment for adjusting the length. A detachable fixing jig (80) is provided which has a mechanism (70) and puts the plurality of solar panels (11) into a fixed state in which the rotation is prevented at a predetermined rotation angle.

    In the fourth invention, by using the detachable fixing jig (80), the plurality of solar panels (11) are not rotated at the same rotation angle, and the fixed state is released. Can be easily changed.

    According to the first invention, after the plurality of solar panel units (10) are installed at the respective installation positions, the plurality of solar panels (11) are fixed so as not to rotate at the same rotation angle. Therefore, the length of the connecting rod (61) was adjusted, and the rotating members (13) of the two adjacent solar panel units (10) were connected by the connecting rod (61). Therefore, even when the installation position of the solar panel unit (10) is deviated from the design position, the length of the connecting rod (61) and the two solar panel units connected by the connecting rod (61) ( The interval of 10) can be made equal, and the two solar panels (11) connected by the connecting rod (61) can be rotated at the same rotation angle (the rotation operation is synchronized). Therefore, it is not necessary to accurately install the solar panel unit (10) at the designed installation position in order to synchronize the rotation operations of the plurality of solar panels (11). A photovoltaic power generation system can be installed so that the rotation angle of the light panel (11) does not shift.

    According to the second aspect of the invention, the plurality of solar panels (11) are connected in a fixed state in which the solar panels (11) do not rotate at a rotation angle in which the width direction of each solar panel (11) is the horizontal direction. Since the connection work by the rod (61) is performed, the pressure receiving area with respect to the wind of each solar panel (11) can be reduced when the fixed state is set. Therefore, the angle shift of each solar panel (11) by a strong wind can be suppressed in the connection process after completion | finish of a fixing process. Therefore, it is possible to more easily install the solar power generation system so that the rotation angles of the plurality of solar panels (11) are not shifted.

    According to the third invention, the adjusting mechanism (70) for adjusting the length is provided on the connecting rod (61) for connecting the rotating members (13) of the adjacent solar panel units (10). It was. Therefore, the length of the connecting rod (61) can be adjusted to be equal to the distance between the two solar panel units (10) connected by the connecting rod (61). As a result, even if the installation position of the solar panel unit (10) is deviated from the design position, the length of the connecting rod (61) and the two solar panels connected by the connecting rod (61) The interval between the units (10) can be easily made equal. Therefore, it is not necessary to accurately install the solar panel unit (10) at the designed installation position, and the rotation angle of the plurality of solar panels (11) is shifted by an easy installation operation. It can be installed so that there is no.

    Moreover, according to 4th invention, it decided to provide the removable fixing jig (80) which makes the some solar panel (11) the fixed state which does not rotate by a predetermined rotation angle, respectively. By using such a detachable fixing jig (80), a plurality of solar panels (11) can be easily fixed in a state where they are not rotated at the same rotation angle and in a state where the fixed state is released. Can be changed. Thereby, the length adjustment work of the connecting rod (61) for equalizing the length of the connecting rod (61) and the distance between the solar panel units (10) connected to the connecting rod (61) and the connecting rod (61 ) Can be easily performed. Therefore, the installation work of the photovoltaic power generation system can be further facilitated by an easy installation work.

Drawing 1 is a perspective view showing a schematic structure of a photovoltaic power generation system concerning an embodiment. FIG. 2 is a side view of the first solar panel unit according to the embodiment. FIG. 3 is a perspective view of the first solar panel unit according to the embodiment with a part thereof omitted. 4 is an arrow view in the IV direction of FIG. FIG. 5 is a side view of the connecting rod according to the embodiment. FIG. 6 is a side view showing an installation process of the photovoltaic power generation system according to the embodiment. FIG. 7 is a side view showing a fixing process of the photovoltaic power generation system according to the embodiment. FIG. 8 is a side view illustrating a connection process of the photovoltaic power generation system according to the embodiment. FIG. 9 is a side view illustrating a fixing release process of the photovoltaic power generation system according to the embodiment. FIG. 10 is a perspective view showing an adjusting mechanism according to another embodiment.

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

    This embodiment relates to a solar power generation system including a plurality of solar panel units each having a solar panel whose angle is adjusted according to the position of the sun. The solar power generation system is configured to construct a large-scale solar power generation system called a so-called mega solar system by using a combination of a plurality of units.

(System configuration)
As shown in FIG. 1, the solar power generation system (1) of this embodiment includes a plurality (three in FIG. 1) of solar panel units (10) each having a solar panel (11). The plurality of solar panel units (10) are installed at installation positions arranged in a straight line in the east-west direction so that the rotation axes (s) of the solar panels (11) are parallel to each other. The plurality of solar panel units (10) are provided with an actuator unit (50), which will be described later, and are driven by the actuator (51) so that the solar panel (11) rotates about the rotation axis (s) 1 One first solar panel unit (10a) and a plurality of second solar panel units (10b) (only two are shown in FIG. 1) in which the actuator unit (50) is not provided. Although details will be described later, the first solar panel unit (10a) and the second solar panel unit (10b) are substantially the same except whether or not the actuator unit (50) including the actuator (51) is included. In the same way. Moreover, the several solar panel unit (10) is connected so that rotation operation | movement may synchronize by the link mechanism (60). Although not shown, the solar power generation system (1) is provided with a power conditioner that converts DC power generated by the plurality of solar panel units (10) into AC power.

<Solar panel unit>
Each solar panel unit (10) includes a solar panel (11) and a support base (12) that rotatably supports the solar panel (11) around the rotation axis (s). Yes.

    Each solar panel (11) is formed in a substantially plate shape, and its upper surface is configured as a sunlight receiving surface (11a). Each solar panel (11) is configured to generate DC power by receiving sunlight on the light receiving surface (11a). Each solar panel (11) is supported by the support base (12) in a state of being inclined so as to be higher toward the north side in the north-south direction with respect to the horizontal plane.

    As shown in FIG.2 and FIG.3, each support stand (12) has a rotation member (13) and a support member (14). The rotating member (13) is fixed to the supporting solar panel (11), and is configured to be rotatable around a rotation axis (s) extending in the north-south direction at the center in the width direction of the solar panel (11). ing. Specifically, the rotating member (13) includes two beam members (15a, 15b) fixed to the solar panel (11) and shafts fixed to the beam members (15a, 15b). It has a member (16) and a link member (17) (not shown in FIG. 3, see FIG. 2) fixed to one of the crosspiece members (15b).

    Two crosspieces (15a, 15b) are fixed to the back surface (11b) of the light receiving surface (11a) of the solar panel (11), and the width direction of the solar panel (11) along the back surface (11b) It extends in the direction perpendicular to the rotation axis (s). The two beam members (15a, 15b) are provided in parallel, and the upper (north) beam member (15a) is connected to a transmission mechanism (53) of an actuator unit (50), which will be described later. A link member (17) and a fixing jig (80) described later are fixed to the side (south side) cross member (15b) (see FIG. 2).

    Each shaft member (16) has a shaft portion (16a) and a base portion (16b) that supports the base end portion of the shaft portion (16a). The shaft portion (16a) is formed in a substantially cylindrical shape, and extends in a direction substantially perpendicular to the base portion (16b) from the base portion (16b) extending along the opposing side surfaces of the crosspiece members (15a, 15b). It protrudes. Each base part (16b) is fixed to each crosspiece member (15a, 15b) with bolts so that the axis of each shaft part (16a) is located at the center of the solar panel (11) in the width direction. Yes. In the present embodiment, the axis of the shaft portion (16a) of the two shaft members (16) serves as the rotation shaft (s).

    The link member (17) is constituted by an elongated rectangular plate-like first to third member (17a to 17c). The first member (17a) extends downward from the lower beam member (15b) along the back surface (11b) of the solar panel (11) in parallel with the rotation axis (s), and the solar panel (11) It is provided so as to extend further downward than the lower end of the. The second member (17b) is fixed to the lower end of the first member (17a), and extends vertically downward to the first member (17a). The base (17d) is fixed to the base (17d). And a folded plate-like spacer (17e) that forms a space at the lower end of (17d). A connecting portion (63) of two connecting rods (61) described later is inserted into a space formed by the base portion (17d) and the spacer (17e). One end of the third member (17c) is fixed to the lower beam member (15b) to which the first member (17a) is fixed, and the other end is the lower end of the base (17d) of the second member (17b) The second member (17b) is reinforced.

    The support member (14) includes a support base (18) provided at the upper end, and a support (19) extending downward from the lower end of the support base (18). The support base part (18) is a steel material extending in the inclination direction of the solar panel (11), and has two standing parts (18a) that rise upward substantially vertically from both ends of the upper surface. Each standing part (18a) is formed with a hole (18b). By inserting the shaft part (16a) of the two shaft members (16) into the hole (18b), the solar panel (11) rotates around the rotation axis (s) on the support frame (12). It is supported freely. The column (19) is a cylindrical steel material that is fixed to the support base (18) via the fixing bracket (19a), and the lower end is embedded in the ground. The position of the support member (14) is fixed by embedding the lower end of the column (19) in the ground and solidifying the periphery thereof with mortar. In addition, a holder (82) that holds the lower end of a plate-like member (81) of a fixing jig (80) described later is attached to the support post (19).

<Actuator unit>
As shown in FIG. 1, the actuator unit (50) is provided in only one first solar panel unit (10a) among the plurality of solar panel units (10).

    2 and 4, the actuator unit (50) includes an actuator (51), a drive base (52) for fixing the actuator (51) to the support base (18), and an actuator (51). A transmission mechanism (53) for transmitting the rotational force of the output shaft (51a) to the solar panel (11).

    In this embodiment, the actuator (51) is constituted by a rotary pneumatic actuator. Although a detailed description of the actuator (51) is omitted, the output shaft (51a) is rotated by air pressure to output a rotational force.

    The drive base (52) is configured by a substantially L-shaped plate body, one side is fixed to the lower surface of the support base (18), and the output shaft (51a) of the actuator (51) is provided on the other side. The actuator (51) is fixed so as to penetrate.

    The transmission mechanism (53) includes a first transmission member (53a) having a proximal end coupled to the output shaft (51a) of the actuator (51), and a proximal end at the distal end of the first transmission member (53a) by a pin member. It has the 2nd transmission member (53b) by which it connected and the front-end | tip was connected with the crosspiece member (15a) of the upper side of the solar panel (11) by the pin member. When the actuator (51) is actuated, the first transmission member (53a) rotates around the output shaft (51a) as the output shaft (51a) rotates, thereby causing the base of the second transmission member (53b) to rotate. The end rotates around the output shaft (51a). The connection part with the front-end | tip of the 2nd transmission member (53b) of a solar panel (11) is pushed up or pulled down with such a 2nd transmission member (53b). In this way, the rotational force of the output shaft (51a) is transmitted to the solar panel (11) by the transmission mechanism (53), and the solar panel (11) rotates about the rotational axis (s).

<Link mechanism>
The link mechanism (60) rotates the solar panels (11) of the second solar panel unit (10b) and rotates the solar panels (11) of the first solar panel unit (10a). Is configured to synchronize with.

    As shown in FIG. 1, the link mechanism (60) has a plurality of connecting rods (61) provided between the plurality of solar panel units (10). Each connecting rod (61) connects the rotating member (13) fixed to the two solar panels (11) so that the rotating operations of the two adjacent solar panels (11) are synchronized. . Specifically, in the present embodiment, as shown in FIG. 5, each connecting rod (61) includes a circular tubular main body (62) and a flat plate extending continuously at both ends of the main body (62). -Like connection part (63). Each connecting portion (63) has a hole (65) through which a pin member (64) (see FIG. 2) for connecting the connecting portion (63) to the link member (17) is inserted. . The main body (62) is constituted by two cylindrical portions (62a) having the same diameter, which are connected by an adjusting mechanism (70) described later. On the other hand, the two connecting portions (63) are formed in a flat plate shape and are connected to the end portions of the two cylindrical portions (62a). Each connecting rod (61) includes a base part (17d) and a spacer (17e) of the second member (17b) of the link member (17) of the two solar panel units (10) connected by the connecting rod (61). In a state where each connecting portion (63) is inserted between each other (see FIG. 2), the pin member (64) is rotatably connected to the second member (17b) of the link member (17). ing.

    As shown in FIG. 2, the solar panel units on both sides are between the base (17d) of the second member (17b) of the link member (17) of each solar panel unit (10) and the spacer (17e). The connecting portion (63) of the two connecting rods (61) provided between (10) is inserted. The connecting portion (63) of the two connecting rods (61) is connected to the lower end portion of the second member (17b) of the link member (17) by one pin member (64).

<Adjustment mechanism>
Each connecting rod (61) is provided with an adjusting mechanism (70) for adjusting the length. In the present embodiment, the adjustment mechanism (70) connects the two cylindrical portions (62a) constituting the main body portion (62) of the connecting rod (61), and sets the distance between the two cylindrical portions (62a). It is configured to be changeable. Specifically, in the present embodiment, the adjustment mechanism (70) is constituted by a clamping member (71) and a fastening member (72). The clamping member (71) extends from the both ends in the circumferential direction of the curved portion (73) to the radially outer side of the curved portion (73) by bending the plate-like member into a cylindrical shape. And a plate-like portion (74). The fastening member (72) is constituted by a bolt that penetrates the two plate-like portions (74) that are overlapped, and two nuts that are screwed from both ends of the bolt toward the two plate-like portions (74). Yes.

    With such a configuration, the ends of the two cylindrical portions (62a) of the main body portion (62) of the connecting rod (61) are inserted into the curved portion (73) of the clamping member (71), and the two plate-like portions ( When the fastening member (72) is fastened in a state where 74) is overlapped, the two cylindrical portions (62a) of the main body portion (62) of the connecting rod (61) are connected by the adjusting mechanism (70). Further, before fastening the fastening member (72), the distance between the two cylindrical portions (62a) of the main body portion (62) of the connecting rod (61) in the curved portion (73) of the clamping member (71) is changed. Thus, the length of the connecting rod (61) is changed. The clamping member (71) is configured such that when the fastening member (72) is fastened, the two cylindrical parts (62a) of the main body part (62) of the connecting rod (61) The dimension is formed so that the position does not shift inside (73).

<fixing jig>
The solar power generation system (1) is a detachable fixing jig that fixes each solar panel (11) of a plurality of solar panel units (10) in a fixed state in which the rotation is prevented at a predetermined rotation angle. (80). In the present embodiment, the fixing jig (80) is fixed to the solar panel (11) and the support base (12) in each solar panel unit (10) to rotate the solar panel (11). It comprises a plurality of long plate-like members (81) for blocking.

    Each plate-like member (81) is formed in an elongated rectangular shape, and an insertion hole through which a bolt is inserted is formed in the upper end portion and the lower end portion. The upper end of the plate-like member (81) is fixed to the lower beam member (15b) with a bolt. On the other hand, the lower end portion of the plate-like member (81) is held by a holding tool (82) attached to the column (19) and fixed to the column (19). Specifically, the holder (82) includes a cylindrical portion (82a) surrounding the middle portion of the support column (19) and two plate-like pieces (82b) extending radially outward from the cylindrical portion (82a). Have. By sandwiching the lower end of the plate member (81) between the two plate pieces (82b) and fastening the bolts so as to penetrate the two plate pieces (82b) and the plate member (81), The lower end portion of the plate-like member (81) is held by the holder (82) and fixed to the column (19). In this way, by fixing each plate member (81) to each solar panel (11) and each support frame (12), each solar panel (11) is prevented from rotating at the same rotational position. Is done. In this embodiment, each plate-like member (81) is fixed to each plate-like member (81) so that each solar panel (11) is horizontal in the width direction of each solar panel (11). It is formed in a length that prevents the rotation at a rotation angle. Each plate-like member (81) is connected to connect the rotating member (13) of each solar panel unit (10) with a connecting rod (61) in the installation work of the photovoltaic power generation system (1) described later. It is attached before the process and is removed after the connection process is completed.

(Installation method of solar power generation system)
This solar power generation system (1) is installed by sequentially performing the following installation process, fixing process, connecting process, and fixing release process.

<Installation process>
First, as shown in FIG. 6, the installation process which installs each solar panel unit (10) in each installation position is performed. Specifically, first, the support member (14) of the support frame (12) is installed in a state of being assembled in advance. The support member (14) is installed by driving the struts (19) into predetermined installation positions arranged in a straight line, and hardening the periphery with mortar. At this time, each strut (19) is driven into the ground so that the rotating shafts (s) of each solar panel unit (10) are arranged in parallel at the same height.

    Next, each solar panel (11) to which the rotating member (13) of the support base (12) is fixed is assembled to each support member (14). Specifically, the two shaft portions (16a) of the shaft member (16) of the rotating member (13) are respectively connected to the two standing portions (18a) of the support base portion (18) of the support member (14). Each solar panel (11) is assembled | attached to each support member (14) by inserting in the formed hole (18b). As a result, each solar panel unit (10) is installed at each installation position in a state where each solar panel (11) is rotatably supported around the rotation axis (s) with respect to the support base (12). Is done.

    The actuator unit (50) is attached in advance to the support base (18) of the support member (14) of the first solar panel unit (10a) before driving the support post (19) into the installation position. . After the solar panel (11) of the first solar panel unit (10a) is assembled to the support member (14), the tip of the second transmission member (53b) of the transmission mechanism (53) of the actuator unit (50) (The end opposite to the end connected to the first transmission member (53a)) is connected to the upper beam member (15a) of the solar panel (11) by a pin member.

<Fixing process>
When the installation process is completed, as shown in FIG. 7, a fixing process is performed to bring each solar panel (11) into a fixed state in which the rotation is prevented at the same rotation angle. The fixing step is performed using a fixing jig (80). In this embodiment, the solar panels (11) are rotated at a rotation angle in which the width direction of the solar panels (11) is a horizontal direction. To a fixed state where is blocked. Specifically, the upper end of each plate-like member (81) is fixed to the lower beam member (15b) fixed to each solar panel (11) with a bolt. Further, the lower end portion of each plate-like member (81) is sandwiched between two plate-like pieces (82b) of the holder (82) fixed to the column (19), the two plate-like pieces (82b) and By fastening the bolt so as to penetrate the plate-like member (81), the lower end portion of the plate-like member (81) is fixed to the support column (19) via the holder (82). By attaching each plate-like member (81) in this way, each solar panel (11) is prevented from rotating at a rotation angle at which the width direction of each solar panel (11) is horizontal. It becomes a fixed state. In this way, by connecting each solar panel (11) to a fixed state that does not rotate at the same rotation angle, in the two adjacent solar panel units (10), the connecting rod of the rotating member (13) The distance between the connecting portions to which (61) is connected (the distance between the pin members (64)) is equal to the distance between the solar panel units (10) (the distance between the rotation axes (s)).

<Consolidation process>
When the fixing step is finished, as shown in FIG. 8, the rotation fixed to the two solar panels (11) so that the rotation operations of the two adjacent solar panels (11) are synchronized. A connecting step of connecting the member (13) with the connecting rod (61) is performed. The connecting step is performed by adjusting the length of the connecting rod (61).

    Specifically, first, the length L of the connecting rod (61) (the distance L between the holes (65) formed in the connecting portions (63) at both ends) is connected by the connecting rod (61) 2. Adjustment is made to be equal to the distance between the pin members (64) of the two rotating members (13). The length L of the connecting rod (61) is adjusted by separating the two cylindrical portions (62a) of the main body portion (62) of the connecting rod (61) inserted into the bending portion (73) of the holding member (71). Is done by changing Specifically, the ends of the two cylindrical portions (62a) of the main body portion (62) of the connecting rod (61) are inserted into the curved portion (73) of the clamping member (71), and the two plate-like portions (74 ) Are fastened together so that the two cylindrical portions (62a) of the main body portion (62) of the connecting rod (61) are connected by the adjusting mechanism (70) and connected. The length of the rod (61) is adjusted.

    As described above, in the fixing step, the distance between the pin members (64) of the two rotating members (13) connected by the connecting rod (61) is the interval (rotation) of the solar panel unit (10). It is in a state equal to the interval of the axis (s). Therefore, by adjusting the length L of the connecting rod (61) to be equal to the distance between the pin members (64) of the two rotating members (13) connected by the connecting rod (61), The length L of the connecting rod (61) is equal to the interval D (the interval D of the rotating shaft (s)) of the solar panel units (10) to which the connecting rod (61) is connected.

    After adjusting the length L of the connecting rod (61) to a desired length in this way, the two rotating members (13) are connected by the connecting rod (61). Specifically, two connecting portions (63) of a connecting rod (61) whose length is adjusted (the length L is equal to the distance D) are connected to two connecting rods (61). The second member (64) is inserted into the second member (64) while being inserted between the base (17d) and the spacer (17e) of the second member (17b) of the link member (17) of the solar panel unit (10). 17b) is pivotally connected. In this way, the length L of the connecting rod (61) was adjusted to be equal to the distance D (the distance D of the rotating shaft (s)) of the solar panel units (10) to which the connecting rod (61) is connected. In this state, by connecting the two rotating members (13) with the connecting rod (61), the two solar panels (11) adjacent to each other are connected so as to synchronize.

<Unlocking process>
When the connection step is finished, as shown in FIG. 9, a fixing release step for releasing the fixed state of the solar panel (11) fixed in the fixing step is performed. In the fixing step, each plate-like member (81) fixed to the lower beam member (15b) fixed to each solar panel (11) and the holding tool (82) is removed in the fixing step. . Thereby, the fixed state of each solar panel (11) is cancelled | released, and each solar panel (11) will be in the state which can rotate around a rotating shaft (s).

-Driving action-
In the solar power generation system (1) of this embodiment, the angle of the solar panel (11) is adjusted according to the direction of the sun.

    The solar power generation system (1) is provided with, for example, a solar radiation sensor (not shown) to detect the direction of the sun. The controller (not shown) calculates the angle at which the solar panel (11) is in a state corresponding to the direction of the sun, and the actuator (51) is controlled so that the solar panel (11) is at that angle. Is done.

    When the actuator (51) is driven and the output shaft (51a) rotates, the rotating member (13) of the first solar panel unit (10a) rotates around the rotating shaft (s), and accordingly the sun The light panel (11) rotates. When the rotating member (13) of the first solar panel unit (10a) rotates, the rotating operation is transmitted to each second solar panel unit (10b) via each connecting rod (61). The rotating member (13) and the solar panel (11) of each second solar panel unit (10b) rotate. As a result, the rotating operation of the solar panel (11) of each second solar panel unit (10b) and the rotating operation of the solar panel (11) of the first solar panel unit (10a) are all synchronized. The solar panel (11) of the solar panel unit (10) is adjusted to the same angle according to the direction of the sun.

    Thus, in this embodiment, all the solar panels (11) are oriented in the direction that matches the direction of the sun, the incident angle of sunlight on each solar panel (11) is set to the optimum angle, and the efficiency is improved. Good solar power generation.

-Effect of the embodiment-
According to the installation method of this photovoltaic power generation system (1), after installing a plurality of solar panel units (10) at their respective installation positions, the plurality of solar panels (11) are rotated at the same rotation angle. After the fixed state that does not move, the length of the connecting rod (61) is adjusted, and the rotating members (13) of two adjacent solar panel units (10) are connected by the connecting rod (61). It was decided. Therefore, even when the installation position of the solar panel unit (10) is deviated from the design position, the length of the connecting rod (61) and the two solar panel units connected by the connecting rod (61) ( The interval of 10) can be made equal, and the two solar panels (11) connected by the connecting rod (61) can be rotated at the same rotation angle (the rotation operation is synchronized). Therefore, it is not necessary to accurately install the solar panel unit (10) at the designed installation position in order to synchronize the rotation operations of the plurality of solar panels (11). The solar power generation system (1) can be installed so that the rotation angle of the light panel (11) does not shift.

    Moreover, according to the installation method of this solar power generation system (1), a plurality of solar panels (11) are not rotated at a rotation angle in which the width direction of each solar panel (11) is a horizontal direction. Since the connection work by the connecting rod (61) is performed in the fixed state, the pressure receiving area with respect to the wind of each solar panel (11) can be reduced when the fixed state is set. Therefore, the angle shift of each solar panel (11) by a strong wind can be suppressed in the connection process after completion | finish of a fixing process. Therefore, the solar power generation system (1) can be installed more easily so that the rotation angles of the plurality of solar panels (11) do not shift.

    Moreover, according to this solar power generation system (1), the adjustment mechanism (70) which adjusts length to the connection rod (61) which connects the rotation member (13) of an adjacent solar panel unit (10) It was decided to provide. Therefore, the length of the connecting rod (61) can be adjusted to be equal to the distance between the two solar panel units (10) connected by the connecting rod (61). As a result, even if the installation position of the solar panel unit (10) is deviated from the design position, the length of the connecting rod (61) and the two solar panels connected by the connecting rod (61) The interval between the units (10) can be easily made equal. Therefore, it is not necessary to accurately install the solar panel unit (10) at the designed installation position, and the solar power generation system (1) can be rotated by a plurality of solar panels (11) with easy installation work. It can be installed so that the angle does not shift.

    In addition, according to the photovoltaic power generation system (1), the detachable fixing jig (80) for fixing the plurality of solar panels (11) so as not to rotate at a predetermined rotation angle is provided. It was. By using such a detachable fixing jig (80), a plurality of solar panels (11) can be easily fixed in a state where they are not rotated at the same rotation angle and in a state where the fixed state is released. Can be changed. Thereby, the length adjustment work of the connecting rod (61) for equalizing the length of the connecting rod (61) and the interval between the solar panel units (10) connected to the connecting rod (61) and the connecting rod (61 ) Can be easily performed. Therefore, the installation work of the photovoltaic power generation system can be further facilitated by an easy installation work.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

    The adjustment mechanism (70) according to the present invention may have any form as long as the length of the connecting rod (61) can be changed, and is not limited to the structure of the above embodiment. For example, as shown in FIG. 10, the two cylindrical portions (62a) of the main body portion (62) of the connecting rod (61) are inserted into one inside the other so that the other can be inserted and slidable from the other. Also, the length of the connecting rod (61) may be adjusted by changing the length in which the two cylindrical portions (62a) overlap in the axial direction. In FIG. 10, a large number of holes (67) into which the pin member (66) can be inserted are arranged in the axial direction at the end of the large-diameter cylindrical part (62a) of the two cylindrical parts (62a), The position of the hole (67) through which the pin member (66) is inserted in the end of the small diameter cylindrical portion (62a) and the pin member (66) is inserted through the large diameter cylindrical portion (62a) The length of the connecting rod (61) can be adjusted by changing.

    Moreover, the structure of the rotating member (13) and the supporting member (14) described in the above embodiment is an example. In the present invention, each rotating member (13) together with the solar panel (11) has a rotating shaft (s). As long as it rotates around, you may change suitably the structure of a rotation member (13) and a support member (14).

    Moreover, in the said embodiment, the number of the solar panel units (10) in a solar power generation system (1) can be suitably changed according to the electric power etc. which are requested | required of a system.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a solar power generation system installation method and a solar power generation system including a plurality of solar panel units each including a solar panel and a support frame.

1 Solar power generation system
10 Solar panel unit
10a First solar panel unit
10b Second solar panel unit
11 Solar panels
12 Support stand
13 Rotating member
51 Actuator
61 Connecting rod (connecting rod)
70 Adjustment mechanism
80 Fixing jig

Claims (4)

A solar panel (11), and a rotating shaft fixed to the solar panel (11) and configured to be rotatable about a rotation axis (s) positioned at a central portion in the width direction of the solar panel (11). Each having a moving member (13) and a support frame (12) for rotatably supporting the solar panel (11) around the rotation axis (s) via the rotating member (13). A plurality of solar panel units (10) installed such that the rotation axes (s) are parallel to each other at installation positions arranged in a straight line;
An actuator (51) connected to the rotating member (13) fixed to any one of the solar panels (11) and rotating the solar panel (11) about the rotation axis (s);
The solar panel unit (10) provided between the solar panel units (10) and fixed to the two solar panel (11) so that the rotating operations of the two adjacent solar panels (11) are synchronized. A solar power generation system installation method comprising a connecting rod (61) for connecting a rotating member (13),
An installation step of installing the plurality of solar panel units (10) at respective installation positions;
After completion of the installation step, a fixing step of bringing the plurality of solar panels (11) into a fixed state in which rotation is prevented at the same rotation angle;
After completion of the fixing step, the connecting step of adjusting the length of the connecting rod (61) and connecting the two rotating members (13) with the connecting rod (61);
An installation method for a solar power generation system, comprising: a fixing release step of releasing the fixed state of the solar panel (11) fixed in the fixing step after the connection step. In claim 1,
In the fixing step, the plurality of solar panels (11) are in a fixed state in which the rotation is prevented at a rotation angle in which the width direction of each solar panel (11) is a horizontal direction. How to install a solar power system. A solar panel (11), and a rotating shaft fixed to the solar panel (11) and configured to be rotatable about a rotation axis (s) positioned at a central portion in the width direction of the solar panel (11). Each having a moving member (13) and a support frame (12) for rotatably supporting the solar panel (11) around the rotation axis (s) via the rotating member (13). A plurality of solar panel units (10) installed such that the rotation axes (s) are parallel to each other at installation positions arranged in a straight line;
An actuator (51) connected to the rotating member (13) fixed to any one of the solar panels (11) and rotating the solar panel (11) about the rotation axis (s);
The solar panel unit (10) provided between the solar panel units (10) and fixed to the two solar panel (11) so that the rotating operations of the two adjacent solar panels (11) are synchronized. A photovoltaic power generation system comprising a connecting rod (61) for connecting a rotating member (13),
The connecting rod (61) has an adjustment mechanism (70) for adjusting the length ,
The solar power generation system , wherein each of the plurality of solar panels (11) is configured to be fixed at a predetermined same rotation angle . A solar panel (11), and a rotating shaft fixed to the solar panel (11) and configured to be rotatable about a rotation axis (s) positioned at a central portion in the width direction of the solar panel (11). Each having a moving member (13) and a support frame (12) for rotatably supporting the solar panel (11) around the rotation axis (s) via the rotating member (13). A plurality of solar panel units (10) installed such that the rotation axes (s) are parallel to each other at installation positions arranged in a straight line;
An actuator (51) connected to the rotating member (13) fixed to any one of the solar panels (11) and rotating the solar panel (11) about the rotation axis (s);
The solar panel unit (10) provided between the solar panel units (10) and fixed to the two solar panel (11) so that the rotating operations of the two adjacent solar panels (11) are synchronized. A photovoltaic power generation system comprising a connecting rod (61) for connecting a rotating member (13),
The connecting rod (61) has an adjustment mechanism (70) for adjusting the length,
A photovoltaic power generation system comprising: a detachable fixing jig (80) for bringing the plurality of solar panels (11) into a fixed state in which the rotation is prevented at a predetermined rotation angle. .

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