JP2019130955A - Float type solar system - Google Patents

Abstract

To provide a float type solar system that hardly causes fatigue in members configuring a power generating structure.SOLUTION: A float type solar system 10 comprises a solar panel, a power generating structure 100 including a float type base 110 on which the solar panel is installed, and a parachute anchor 200 preventing the power generating structure 100 from floating. The float type solar system 10 includes a connection structure 20 to connect the power generating structure 100 and the parachute anchor 200 so that the power generating structure 100 and the parachute anchor 200 can relatively move in a predetermined vertically crossing direction.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a float solar system installed on the surface of water.

  2. Description of the Related Art A float type solar system that generates power using sunlight on a water surface is known. For example, Patent Document 1 describes a power generation float (11a) including a solar cell panel (15). A swing resistor (81) is attached to the power generation float (11a). The swing resistor (81) includes a bag (82) that is submerged in water, and a suspension wire (84) that connects the bag (82) to the power generation float (11a). When the strong wind blowing from the water surface hits the solar cell panel (15), a load is applied to the power generation float (11a) by the water pressure received by the bag (82), and the lift of the power generation float (11a) from the water surface is suppressed.

Japanese Patent Laid-Open No. 2006-113123

  The float solar system may be installed in an environment that receives repeated strong winds. Every time a strong wind hits the float solar system, a large load is applied to the power generation float (11a) due to the action of the rocking resistor (81). When a load is repeatedly applied to the power generation float (11a), there is a possibility that fatigue may occur in the members constituting the power generation float (11a).

(1) A float solar system according to the present invention includes a solar panel, a power generation structure including a float base on which the solar panel is installed, and a parachute anchor that prevents the power generation structure from being lifted. The power generation structure and the parachute anchor include a connection structure that connects the power generation structure and the parachute anchor so that the power generation structure and the parachute anchor can move relatively in a predetermined direction that intersects the vertical direction.
According to the float solar system, when a strong wind blowing from the water surface hits the solar panel, a large load is applied to the power generation structure due to the water pressure received by the parachute anchor, and the power generation structure is prevented from being lifted. When a strong cross wind strikes the power generation structure, the power generation structure and the parachute anchor move relatively in a predetermined direction, and the water pressure received by the parachute anchor does not increase significantly. For this reason, unlike the case where the strong wind blowing from the water surface hits the solar panel, the load applied to the power generation structure does not increase greatly. The structure in which the parachute anchor is fixed to the power generation structure is the same as the power generation structure due to the action of the parachute anchor both when the strong wind blowing from the water hits the solar panel and when the strong crosswind hits the power generation structure. A large load is applied. Compared with this structure, in the float solar system according to the present invention, the number of times that a large load is repeatedly applied to the power generation structure is reduced, and fatigue of members constituting the power generation structure is less likely to occur.

(2) In a preferred example, in the float solar system according to (1), the float solar system further includes a connection member that connects the adjacent float bases, and the connection structure is attached to the connection member and the connection member. Including a ring of the parachute anchor.
According to the float solar system, since the connection structure is configured using the connection member, the cost related to the connection structure can be reduced. In addition, the parachute anchor ring includes not only a connected ring but also an incomplete ring such as a half wheel.

(3) In a preferred example, in the float solar system according to (2), the connecting member is a linear bar and connecting ends provided at both ends of the bar so as to be connected to the power generation structure. A ring of the parachute anchor is hung on the bar.
According to the float type solar system, when a strong cross wind hits the power generation structure, the bar and the parachute anchor wheel relatively move in the direction along the bar. Since the ring of the parachute anchor is hung on a portion where it is difficult to catch, the relative movement between the power generation structure and the parachute anchor appropriately occurs even in a situation where the posture of the power generation structure frequently changes due to the influence of wind.

(4) In a preferred example, in the float solar system according to (2) or (3), the parachute anchor includes a resistor, and the diameter of the opening of the resistor is defined by the connecting member. It is wider than the maximum distance between bases.
According to the float solar system, the opening of the resistor is caught by the float base when a force is applied to pull up the parachute anchor located near the water surface onto the water surface. For this reason, it is difficult for the parachute anchor to jump out of the water.

(5) In a preferred example, in the float solar system according to any one of (2) to (4), the parachute anchor includes a weight, and the weight of the weight is the weight of the parachute anchor submerged in water. The ring is set to be bent.
According to the float type solar system, fatigue is less likely to occur in the connecting member.

  According to the float type solar system of the present invention, the members constituting the power generation structure are not easily fatigued.

The top view which shows the example of installation of the float type solar system of embodiment. The perspective view of the electric power generation structure of FIG. The figure which shows the connection structure which connects electric power generation structures. The perspective view of a parachute anchor. The bottom view of the parachute anchor of FIG. The figure which shows the 1st process of an anchor installation operation | work. The figure which shows the 2nd process of an anchor installation operation | work. The figure which shows the 3rd process of an anchor installation operation | work.

(Embodiment)
FIG. 1 shows an example of a float solar system 10 installed on the water surface. Typical examples of places where the float solar system 10 is installed are lakes, reservoirs, industrial ponds, and recreational ponds. As shown in the drawing, a plurality of wires 11 may be installed together with the float solar system 10. A plurality of wires 11 connect the float solar system 10 to the quay G, the bottom of a lake, or the bottom of a pond. By installing the plurality of wires 11, the position of the float solar system 10 on the water surface is stabilized. The float solar system 10 includes a plurality of power generation structures 100. The plurality of power generation structures 100 are regularly arranged.

  FIG. 2 is an example of the power generation structure 100. The power generation structure 100 is a solar power generation device that generates power using sunlight on the water surface. Main elements constituting the power generation structure 100 are a float base 110 and a solar panel 170. In one example, a plurality of solar panels 170 are installed on the float base 110. The float base 110 and the solar panel 170 are strongly coupled so that the solar panel 170 is not separated from the float base 110 even when strong wind strikes the solar panel 170.

  The float base 110 is configured to float on the water surface while supporting the solar panel 170. Main elements constituting the float base 110 are a frame 120, a float 150, and a mount 160. The frame 120 constitutes the outline of the float base 110. The frame 120 includes a frame 130 and a beam 140. An example of the material constituting the frame 130 is stainless steel or aluminum. The shape of the frame 130 is arbitrarily set. In one example, the shape of the frame 130 is a rectangle. The frame 130 includes a first side 131 and a second side 132 that face each other in the first direction, and a third side 133 and a fourth side 134 that face each other in the second direction. In the plan view of the float base 110, the first direction and the second direction are orthogonal to each other.

  An example of the material constituting the beam 140 is a high weather-resistant plated steel plate. The specific form and number of the beams 140 can be arbitrarily selected. In the example shown, the beam 140 is grating. The frame 120 includes four beams 140. The first beam 141 to the fourth beam 144, which are the four beams 140, are arranged in parallel to the first direction. The first beam 141 is disposed next to the first side 131. The first beam 141 is fixed to each of the first side 131, the third side 133, and the fourth side 134. The second beam 142 is disposed next to the second side 132. The second beam 142 is fixed to each of the second side 132, the third side 133, and the fourth side 134. The third beam 143 and the fourth beam 144 are installed between the first beam 141 and the second beam 142. In the second direction, a certain distance is provided between the first beam 141 and the third beam 143, between the third beam 143 and the fourth beam 144, and between the fourth beam 144 and the second beam 142. Is provided. The third beam 143 and the fourth beam 144 are fixed to the third side 133 and the fourth side 134, respectively.

  The plurality of solar panels 170 are arranged along the first direction and the second direction. In the row of solar panels 170 along the first direction, the solar panels 170 are arranged so that no gap is formed between adjacent solar panels 170. In the row of solar panels 170 along the second direction, the solar panels 170 are arranged such that the solar panels 170 are positioned between the beams 141 to 144 in a plan view of the power generation structure 100. An operator who works on the float base 110 can use the beams 141 to 144 as a passage for moving on the float base 110 and a scaffold for the work.

  The configuration of the float 150 can be arbitrarily selected. In one example, the float 150 is made of expanded polystyrene. In the illustrated example, one float base 110 is provided with three floats 150. The first float 151 to the third float 153 that are the three floats 150 are arranged in the second direction. The first float 151 is disposed between the first beam 141 and the third beam 143. The second float 152 is disposed between the third beam 143 and the fourth beam 144. The third float 153 is disposed between the fourth beam 144 and the second beam 142. Each of the floats 151 to 153 is fixed to the frame 120.

  The gantry 160 is installed on the frame 120 so that the solar panel 170 can be supported. The configuration of the gantry 160 can be arbitrarily selected. In one example, the gantry 160 includes a plurality of leg structures 161. The plurality of leg structures 161 are arranged in the first direction. A fixed interval is provided between the adjacent leg structures 161. In the illustrated example, the gantry 160 includes six leg structures 161.

  The leg structure 161 includes a base 162 and a plurality of legs 163. The stand 162 is fixed to each of the first beam 141 to the fourth beam 144. An example of means for fixing the table 162 is a bolt BX. A plurality of legs 163 are fixed to one table 162. In the illustrated example, the leg structure 161 includes six legs 163. An example of means for fixing the leg 163 is a bolt BY. The plurality of legs 163 are arranged in the longitudinal direction of the table 162. A constant interval is provided between the adjacent legs 163. An example of the stage 162 and the leg 163 is an angle. The table 162 which is an angle is constituted by a first flat bar 162A and a second flat bar 162B. The first flat bar 162A is fixed to the beams 141 to 144 by bolts BX.

  Two leg structures 161 adjacent in the first direction constitute one set. One set of leg structures 161 supports a plurality of solar panels 170. In the illustrated example, three solar panels 170 are supported by a set of leg structures 161. Each solar panel 170 is fixed to a corresponding leg 163. In the illustrated example, each of the four legs 163 is fixed to the four corners of one solar panel 170.

  As shown in FIG. 3, the float solar system 10 further includes a parachute anchor 200 and a connection structure 20. The parachute anchor 200 is installed to prevent the power generation structure 100 from floating from the water surface. The connection structure 20 connects the power generation structure 100 and the parachute anchor 200 so as to be relatively movable in a predetermined direction intersecting the vertical direction. In one example, the predetermined direction is a direction parallel to a plane defined by the first direction and the second direction. This plane is parallel to the stable water surface. When the water surface is stable, the predetermined direction is substantially the same direction as the horizontal direction perpendicular to the vertical direction.

  The connection structure 20 includes a connection member 300. The connecting member 300 connects the adjacent power generation structures 100 to each other. The material constituting the connecting member 300 is preferably excellent in strength and weather resistance. One example is galvanized iron. In FIG. 1, the connecting member 300 is omitted. For each power generation structure 100 shown in FIG. 1, adjacent power generation structures 100 are connected by a connecting member 300. All the power generation structures 100 included in the float solar system 10 are connected by a connecting member 300 to form one aggregate.

  As shown in FIG. 3, in two adjacent power generation structures 100, any one of the sides 131 to 134 of one power generation structure 100 and any of the sides 131 to 134 of the other power generation structure 100. One of them is opposed to the gap SA. In one example, a plurality of connecting members 300 are installed in the gap SA. In the following description, each side facing through the gap SA is referred to as an “opposed side”.

  The connecting member 300 is connected to a high-strength member included in each of the adjacent power generation structures 100. An example of the high-strength member is a gantry 160. In the illustrated example, the connecting member 300 is connected to the base 162 of the base 160. The connecting member 300 includes a connector bar 310 and two shackles 320. The connector bar 310 includes a straight bar 311 and round rings 312 provided at both ends of the bar 311. A shackle 320 is passed through the circular ring 312. The shackle 320 is fixed to the second flat bar 162B of the table 162. The posture of the connector bar 310 with respect to the shackle 320 is arbitrarily changed according to the force applied to the power generation structure 100. The interval between the opposing sides changes according to the posture of the connecting member 300. The connecting member 300 defines the interval between the opposing sides. When the connector bar 310 of the connecting member 300 is parallel to the second direction, the interval between the opposing sides is the widest. This corresponds to the maximum distance between the float bases 110 defined by the connecting member 300.

  FIG. 4 is an example of the parachute anchor 200. The main elements constituting the parachute anchor 200 are a resistor 210 and a ring 220. The resistor 210 is a bag. The ring 220 is approximately a half wheel. The ring 220 is connected to the resistor 210. The wheel 220 is attached to the power generation structure 100 (see FIG. 3). The resistor 210 is configured to be able to receive a strong water pressure when a force to be pulled up on the water surface is applied in a state where the resistor 210 is installed in water. The water pressure received by the resistor 210 acts on the power generation structure 100 via the ring 220.

  An example of the material constituting the resistor 210 is polyethylene including an ultraviolet absorber. The resistor 210 includes a cylinder 211 and a bottom 212. The tube 211 can be easily folded. The bottom 212 closes the lower opening of the tube 211. The cylinder 211 includes an opening 213 that forms an upper opening. A wire 214 that holds the shape of the opening 213 is provided in the opening 213. The diameter of the opening 213 is wider than the maximum interval between the opposing sides defined by the connecting member 300 (see FIG. 3).

  The parachute anchor 200 further includes a reinforcing belt 230. An example of a material constituting the reinforcing belt 230 is polypropylene. The reinforcing belt 230 is fixed to the resistor 210. An example of means for fixing the reinforcing belt 230 is sewing. The reinforcing belt 230 receives water pressure applied to the resistor 210. For this reason, even when a strong water pressure is applied to the resistor 210, the resistor 210 is hardly damaged. The number of reinforcing belts 230 can be arbitrarily selected. In the illustrated example, two reinforcing belts 230 are fixed to the resistor 210. Each reinforcing belt 230 is divided into a first fixing portion 231 and a second fixing portion 232 fixed to different portions of the cylinder 211 of the resistor 210, and a third fixing portion 233 fixed to the bottom 212 of the resistor 210. The A loop 234 for passing the ring 220 is formed at the ends of the first fixing portion 231 and the second fixing portion 232.

  In the illustrated example, the interval between the first fixing portion 231 and the second fixing portion 232 in the circumferential direction of the cylinder 211 is 180 °. Between the first fixing portion 231 and the second fixing portion 232 of one reinforcing belt 230, the first fixing portion 231 and the second fixing portion 232 of the other reinforcing belt 230 are provided. In the illustrated example, the interval between the fixing portions 231 and 232 adjacent in the circumferential direction of the cylinder 211 is 90 °. As shown in FIG. 5, the third fixing portion 233 of one reinforcing belt 230 and the third fixing portion 233 of the other reinforcing belt 230 are orthogonal to each other at the bottom 212 of the resistor 210. The overlapping portion 235 where the third fixing portions 233 overlap is provided at the center of the bottom 212.

  The resistor 210 further includes a pocket 215 and a weight 240. The pocket 215 is provided on the inner surface of the bottom 212 of the resistor 210. An example of the material constituting the pocket 215 is polyethylene containing an ultraviolet absorber. The pocket 215 is fixed to the bottom 212. An example of means for fixing the pocket 215 is sewing. The pocket 215 is provided so as to overlap the overlapping portion 235. The weight 240 is disposed in the pocket 215. The operator can arbitrarily put in and out the weight 240 from the opening 215A of the pocket 215. The weight of the weight 240 is set so that the ring 220 of the parachute anchor 200 submerged in the water is bent. For this reason, the connecting member 300 is not easily fatigued.

  In one example, the ring 220 is constituted by a rope. The number of rings 220 can be arbitrarily selected. In the illustrated example, the parachute anchor 200 includes two rings 220. One wheel 220 is connected to the loop 234 of the first fixing portion 231 of one reinforcing belt 230 and the loop 234 of the first fixing portion 231 of the other reinforcing belt 230. The other ring 220 is connected to the loop 234 of the second fixing portion 232 of the one reinforcing belt 230 and the loop 234 of the second fixing portion 232 of the other reinforcing belt 230. Since the ring 220 is connected to each loop 234 of the reinforcing belt 230, the resistor 210 is not easily damaged even when a strong water pressure is applied to the resistor 210.

  In one example, the connection structure 20 includes a connection member 300 and a ring 220 of a parachute anchor 200 attached to the connection member 300. As shown in FIG. 3, the bar 311 of the connecting member 300 is passed through the ring 220. The ring 220 is suspended from the bar 311. The wheel 220 and the bar 311 move relatively in the longitudinal direction of the bar 311.

  The installation location of the parachute anchor 200 can be arbitrarily selected. In one example, the parachute anchor 200 is attached to each of the plurality of connecting members 300. In this case, in one aggregate constituted by a plurality of power generation structures 100, not only the power generation structure 100 located at the outer peripheral portion of the aggregate, but also a large number of power generation structures 100 located inside the outer peripheral portion. A parachute anchor 200 is installed. Since the parachute anchor 200 is installed over the entire assembly, the power generation structure 100 is less likely to be lifted.

  The parachute anchor 200 is installed as follows, for example. As shown in FIG. 6, the worker uses the beam 140 of the adjacent power generation structure 100 as a work target among the plurality of power generation structures 100 installed on the water surface as a scaffold. First, the folded resistor 210 is submerged in the water through the gap SA on the opposite side. The resistor 210 submerged in water spreads by the gravity of the weight 240 (see FIG. 4). Next, one shackle 320 constituting the connecting member 300 is removed from the base 162 of the leg structure 161. Next, as shown in FIG. 7, the ring 220 is suspended from the bar 311. Next, as shown in FIG. 8, the one shackle 320 removed from the table 162 is connected to the table 162 again.

  According to the float solar system 10, the following actions and effects can be obtained. When a strong wind blowing from the water surface hits the solar panel 170, a large load is applied to the power generation structure 100 due to the action of the parachute anchor 200, and the power generation structure 100 is prevented from rising. When a strong cross wind strikes the power generation structure 100, the power generation structure 100 and the parachute anchor 200 move relatively in a predetermined direction, and the water pressure received by the parachute anchor 200 does not increase significantly. For this reason, unlike the case where the strong wind blowing from the water surface hits the solar panel 170, the load applied to the power generation structure 100 does not increase greatly. As a result, the number of times that a large load is repeatedly applied to the power generation structure 100 is reduced, and fatigue is less likely to occur in the portion of the power generation structure 100 that receives the load due to the action of the parachute anchor 200.

  According to the float solar system 10, the following effects can be further obtained. The parachute anchor 200 is attached to the connecting member 300. The connecting member 300 is connected to the gantry 160. The gantry 160 is fixed to the frame 120. For this reason, the float base 110 is damaged even in an environment where the load applied to the float base 110 due to the water pressure received by the parachute anchor 200 is received by a high-strength member and the strong wind blowing from the water surface repeatedly hits the power generation structure 100. Hateful.

(Modification)
The above embodiment is an example of a form that the float solar system according to the present invention can take, and is not intended to limit the form. The float solar system according to the present invention may take a form different from that illustrated in the embodiments. For example, a part of the configuration of the embodiment is replaced, changed, or omitted, or a new configuration is added to the embodiment.

  -The structure of the connection structure 20 can be changed arbitrarily. In the first example, the connecting member 300 constituting the connecting structure 20 includes a slide structure. The slide structure includes a rail and a slider. The slider moves in a predetermined direction with respect to the rail. The ring 220 of the parachute anchor 200 is attached to the slider. In the second example, the connection structure 20 includes a frame 120 instead of the connection member 300. The frame 120 includes a slide structure similar to the slide structure shown in the first example. In the third example, the connection structure 20 includes a frame 120 instead of the connection member 300. In this connection structure 20, the frame 120 and the ring 220 of the parachute anchor 200 are connected so as to be relatively movable in a predetermined direction. Specifically, the frame 130 or the beam 140 of the frame 120 includes an attachment member for attaching the ring 220. The attachment member is a rod or a similar member. The attachment member and the ring 220 move relatively along the longitudinal direction of the attachment member.

  -The structure of the parachute anchor 200 can be changed arbitrarily. In one example, the parachute anchor 200 includes a connected ring instead of the ring 220 that is a half wheel. This ring is provided at the tip of a wire connected to the resistor 210, for example.

DESCRIPTION OF SYMBOLS 10: Float type solar system 20: Connection structure 100: Power generation structure 110: Float type base 170: Solar panel 200: Parachute anchor 210: Resistor 220: Wheel 240: Weight 300: Connection member 310: Connector bar 311: Bar 320 : Shackle (connection end)

Claims (5)

A float solar system comprising a solar panel, a power generation structure including a float base on which the solar panel is installed, and a parachute anchor that prevents the power generation structure from being lifted,
A float solar system including a connection structure for connecting the power generation structure and the parachute anchor so that the power generation structure and the parachute anchor can move relatively in a predetermined direction intersecting a vertical direction. It further includes a connecting member that connects the adjacent float-type bases,
The float solar system according to claim 1, wherein the connection structure includes the connection member and a ring of the parachute anchor attached to the connection member. The connecting member includes a linear bar, and a connecting end provided at each of both ends of the bar so as to be connected to the power generation structure,
The float solar system according to claim 2, wherein a ring of the parachute anchor is suspended from the bar. The parachute anchor includes a resistor,
The float solar system according to claim 2 or 3, wherein a diameter of the opening of the resistor is wider than a maximum distance between the float bases defined by the connecting member. The parachute anchor includes a weight;
The float solar system according to any one of claims 2 to 4, wherein the weight of the weight is set so that the ring of the parachute anchor submerged in water is bent.