WO2013022277A2 - Solar cell module array - Google Patents

Abstract

Provided is a solar cell module array, the solar cell module array comprising: a plurality of solar cell modules, each of which includes a solar cell module body converting solar energy into electrical energy and a solar cell module frame disposed on the outer periphery of the solar cell module; a module support section which supports the solar cell module; a module mounting section formed on the solar cell module frame and module support section; and a module restrainer section including a module restrainer which is provided on one surface of the module support part and is disposed to be rotatable on an outer side of the solar cell module frame, and thus changes the coupling state of the solar cell module and the module support section through a rotational operation thereof.

Description

Solar Module Array

TECHNICAL FIELD The present invention relates to a solar cell apparatus, and to a solar cell apparatus having a structure that improves mountability and enables mass replacement in an assembly process.

Solar cells are environmentally friendly energy devices, and various researches and installations are in progress. However, in the case of the solar cell module array according to the prior art, a considerable mounting difficulty was involved in a complicated installation structure and a fixing structure for supporting a plurality of solar cell modules.

It is an object of the present invention to provide a solar cell module array having a structure that allows easy installation of a solar cell module and secures a mass using rainwater.

The present invention for achieving the above object, a plurality of solar cell module having a solar cell module body for converting solar energy into electrical energy and a solar cell module frame disposed on the outer periphery of the solar cell module, and the solar cell A solar cell module array having a module support part for supporting a module, the solar cell module frame and the module support part formed in the module support part, and one surface of the module support part being rotatably disposed on the outside of the solar cell module frame to be rotated. It provides a solar cell module array comprising a module list rainer unit including a module list rainer for changing the coupling state of the solar cell module and the module support through the operation.

In the solar cell module array, the module mounting portion may include: a frame locking portion disposed outside the inclined direction on the ground of the solar cell module frame, and a body locking portion disposed to be engaged with the frame locking portion. .

In the solar cell module array, the module wrist liner is: a wrist liner body disposed on one surface of the module support and at least a portion of the outer circumferential surface of the solar cell module frame, and connected to the wrist liner body and connected to the module You may be provided with the wristrain fastening part which can be inserted and arranged in a support part.

In the solar cell module array, a wrist liner body chamfer may be formed on an outer circumferential surface of the wrist liner body in contact with the solar cell module frame.

In the solar cell module array, on one surface of the wrist liner body may be provided with a wrist liner body wrench for the rotational force transmission to rotate the wrist liner body.

In the solar cell module array, an outer circumference of the wrist liner fastening part may be provided with a wrist liner fastening protrusion for allowing a rotational fastening state to the module support part.

In the solar cell module array, the bottom liner fastening elastic portion for preventing separation from the module support portion may be provided at the lower end of the outer peripheral fastening portion.

In the solar cell module array, the solar cell module frame has a frame body disposed between the body catching portion and the wrist liner, the frame catching portion is disposed perpendicular to the frame body at the bottom of the frame body , The wrist liner body forms a rectangular structure when viewed on one surface of the module support, the thickness (t) of the frame body, the long axis length (L) and the short axis length (S) of the wrist liner body, and the wrist liner Between the distance (a) between the pivotal axis of the body and the end of the body engaging part:

,

,

A relationship such as may be formed.

In the solar cell module array, module spacers may be disposed between the solar cell modules to maintain a gap of the solar cell module.

In the solar cell module array, the module support portion includes a module support cavity as an internal space, and when the solar cell modules are arranged in a row with respect to the ground, when the solar cell modules are projected relative to the ground, an intersection area with the solar cell module is provided. A module rear gutter may be provided on the rear surface of the solar cell module to collect rainwater that flows through the bottom of the solar cell module and deliver the rainwater to the module support cavity.

In the solar cell module array, the module back gutter may be a plate type disposed in the row direction of the solar cell module in parallel with the ground to an end of the solar cell module adjacent to the ground.

In the solar cell module array, the module back gutter portion is disposed in the row direction of the solar cell module parallel to the ground to the end of the adjacent solar cell module, at least a part of the portion excluding the crossing area is A gutter round may be provided that is rounded so that the center of curvature is disposed opposite to the ground.

In the solar cell module array, the module back gutter portion may be a clip type fastened to an end horizontal to the ground of the solar cell module frame.

In the solar cell module array, the module back gutter portion: a gutter body disposed to form an intersecting area in the solar cell module, and a gutter clip disposed at an end of the gutter body and mounted to the solar cell module frame. It can also be provided.

In the solar cell module array, a module spacer is mounted between the solar cell modules to maintain the gap of the solar cell module, the module spacer is: a module spacer body in contact with the solar cell module; And a module spacer mounting part mounted to the module support part and connected to the module support part cavity of the module support part, the module spacer body having a spacer to allow flow of rainwater flowing from the module back gutter adjacent to the module spacer. A body flow port is formed, and the module spacer mounting portion may be provided with a spacer mounting flow port in fluid communication with the spacer body flow port.

In the solar cell module array, one surface of the module back gutter toward the solar cell module may be provided with a gutter inclined portion to promote the flow of rainwater.

In the solar cell module array, the gutter inclined portion may include a bidirectional gutter inclined portion in which a central portion in the longitudinal direction of the module rear gutter portion is formed to protrude.

In the solar cell module array, the module support part may further include a module support excellent collecting part corresponding to an end of the module back gutter part.

In the solar cell module array, the module support may be provided with an indicator window for determining the state of good collection of the cavity of the module support.

In the solar cell module array, the indicator window may be provided with an indicator state line indicating a preset storm water collection state.

In the solar cell module array, the module support portion includes a module support cavity as an internal space, and when the solar cell modules are arranged in a row with respect to the ground, when the solar cell modules are projected relative to the ground, an intersection area with the solar cell module is provided. A module rear gutter is disposed on the rear surface of the solar cell module to collect rainwater that flows through the bottom of the solar cell module and to deliver the rainwater to the module support cavity. A module joint connection part may be provided for introducing the rainwater transmitted from the module back gutter to the module support cavity, and one surface of the module back gutter may be provided with a gutter groove for guiding the rainwater toward the module support cavity. .

In the solar cell module array, the module support portion includes a module support cavity as an internal space, and when the solar cell modules are arranged in a row with respect to the ground, when the solar cell modules are projected relative to the ground, an intersection area with the solar cell module is provided. A module rear gutter is disposed on the rear surface of the solar cell module to collect rainwater that flows through the bottom of the solar cell module and to deliver the rainwater to the module support cavity. A module cavity connection is provided for introducing rainwater from the module back gutter into the module support cavity, wherein the module cavity connection allows for flow of rainwater and limits movement between the exterior of the foreign body and the module support cavity. A modular common screen unit may be provided. .

In the solar cell module array, a plurality of solar cell module having a solar cell module body for converting solar energy into electrical energy and a solar cell module frame disposed on the outer periphery of the solar cell module, and supports the solar cell module A solar cell module array having a module support, comprising: a module mounting portion formed on the module support, and rotatably disposed on an outer surface of the solar cell module frame on one surface of the module support, and the solar cell module being rotated. And a module wrist liner including a module wrist liner for changing a coupling state of the module support, wherein the module mounting portion includes: a body catching portion disposed in contact with the solar cell module frame, wherein the module wrist liner includes: Lease insertable to the module support The aspect between the trainer fastening portion, the wrist liner body connected to the wrist liner fastening portion, and the one side of the module support part rotated together when the wrist liner body is disposed on one side of the wrist liner body. It may be provided with a wrist liner foil for supporting the battery module frame.

In the solar cell module array, at least a part of the wrist liner body may be in contact with the solar cell module frame to maintain the solar cell module frame between the body latching portions.

In the solar cell module array, the body locking portion may be removable to the module support.

In the solar cell module array, the list liner body: a list liner main body connected to the list liner fastening portion, a list liner movable body disposed relatively movable to the list liner main body, and the list liner movable It may be provided with a wrist liner body elastic portion elastically supported between the body and the wrist liner main body.

In the solar cell module array, the wrist liner body may further include a wrist liner movable guide for preventing separation and separation between the wrist liner movable body and the wrist liner main body and guiding relative operation.

In the solar cell module array, the wrist liner foil may be of an elastic clip type.

In the solar cell module array, a module support bumper may be provided at an outer circumference of the module support part to enhance rigidity in a direction perpendicular to the ground of the module support part.

In the solar cell module array, the module support portion may be provided with a module support portion penetrating portion penetrating from one side to the other side.

According to another aspect of the present invention, the present invention provides a plurality of solar cell modules including a solar cell module body for converting solar energy into electrical energy and a solar cell module frame disposed on an outer circumference of the solar cell module, and the solar cell module A solar cell module array having a module support for supporting a light source, wherein the module support includes a module support cavity as an inner space, and the solar cell module is arranged in a row with respect to the ground, when projected with respect to the ground. The module rear gutter is disposed on the rear surface of the solar cell module to collect rainwater flowing through the bottom of the solar cell module to have a cross section with the solar cell module and to deliver the rainwater to the module support cavity. It provides a solar cell module array characterized in that.

The solar cell module array according to the present invention having the configuration as described above has the following effects.

First, the solar cell module array according to the present invention may enable a quick and stable mounting through the coupling with the module support through the module wrist liner may facilitate the work process quickly and smoothly.

Second, the solar cell module array according to the present invention, through the collection of rainwater through the module back gutter to enable the use as a mass of the module support portion to enable quick and smooth assembly of mountainous terrain or other terrain that needs to be transported You can also maximize the assembly.

Third, the solar cell module array according to the present invention enables fast and stable mounting by combining with the module support unit through the module wrist liner, thereby making the work process quick and smooth and various modifications of the module wrist liner. Through the structure to secure the maintainability in the vertical and horizontal direction through it can be ensured the universality corresponding to various specifications of the solar cell module smoothly.

Fourth, the solar cell module array according to the present invention, through the collection of rainwater through the module back gutter to enable the use as a mass of the module support portion to enable quick and smooth assembly of mountainous terrain or other terrain that needs to be transported. At the same time, by maintaining a constant isolation of the inside and the outside of the module support through the module screen unit, it is possible to prevent the inflow of foreign objects or the outflow of insects to facilitate maintenance.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a schematic perspective view of a solar cell module array according to an embodiment of the present invention.

2 is a schematic partial perspective view of a solar cell module and a module support unit and a module listrainer of a solar cell module array according to an embodiment of the present invention.

3 is a schematic perspective view of a module listrainer of a solar cell module array according to an embodiment of the present invention.

4 and 5 are partial cross-sectional views showing a change in mounting according to the rotation state of the module wrist liner of the solar cell module array according to an embodiment of the present invention.

6 is a schematic perspective view of a solar cell module array according to an embodiment of the present invention.

7 is a schematic cross-sectional view of a solar cell module array according to an embodiment of the present invention.

8 is a schematic diagram illustrating a partially projected state of a solar cell module array according to an embodiment of the present invention.

9 is a schematic partial perspective cross-sectional view of a module spacer of a solar cell module array according to an embodiment of the present invention.

10 is a perspective view of a module back gutter of another example of a solar cell module array according to an embodiment of the present invention.

11 is a state diagram showing a mounting state of another example of the module spacer of the solar cell module array according to an embodiment of the present invention.

12 is a schematic cross-sectional view of the module support of the solar cell module array according to an embodiment of the present invention.

FIG. 13 is a schematic partial perspective view of another type of module back gutter of a solar cell module array according to an embodiment of the present invention. FIG.

14 is a schematic partial perspective view illustrating a mounting state of a module spacer of a solar cell module array according to an embodiment of the present invention.

15 is a partial cross-sectional view of the module spacer of the solar cell module array according to an embodiment of the present invention.

16 to 18 are schematic partial cross-sectional views taken along lines P1-P1, P2-P2, and P3-P3 of FIG.

19 is a schematic perspective view of yet another type of module back gutter of a solar cell module array according to an embodiment of the present invention.

20 is a schematic perspective view of yet another type of module back gutter of a solar cell module array according to an embodiment of the present invention.

21 is a schematic cross-sectional view taken along the line P4-P4 of FIG. 20.

22 is a schematic rear view of the module support of the solar cell module array according to an embodiment of the present invention.

23 is a schematic partial perspective view of a modification of the module back gutter portion of the solar cell module array according to an embodiment of the present invention.

24 is a schematic partial cross-sectional view of a modification of the module back gutter portion of the solar cell module array according to the embodiment of FIG. 23.

25 is a schematic perspective view of a module screen unit of a solar cell module array according to an embodiment of the present invention.

26 is a schematic mounting cross-sectional view of a module screen unit of a solar cell module array according to an embodiment of the present invention.

27 is a schematic perspective view of a solar cell module array according to another embodiment of the present invention.

28 is a schematic exploded perspective view of a module listrainer of a solar cell module array according to another embodiment of the present invention.

29 and 30 are schematic partial enlarged cross-sectional views illustrating a mounting operation state of a module wrist liner of a solar cell module array according to another embodiment of the present invention.

Fig. 31 is a schematic perspective view of a modification of the module wrist liner of the solar cell module array of the present invention.

32 is a schematic perspective view of another modification of the module wrist liner of the solar cell module array of the present invention.

33 and 34 are schematic state diagrams showing an operating state of another modified example of the module listrainer of the solar cell module array of the present invention of FIG. 32.

35 is a schematic perspective view of yet another modification of the module wrist liner of the solar cell module array of the present invention.

36 and 37 are schematic perspective views of a modification of the module spacer of the solar cell module array of the present invention.

38 to 39 are schematic perspective views, side views, and cross-sectional views of a modification of the module support of the solar cell module array of the present invention.

Hereinafter, a solar cell module array will be described with reference to the drawings.

1 is a schematic perspective view of a solar cell module array according to an embodiment of the present invention, Figure 2 is a solar cell module and module support of the solar cell module array according to an embodiment of the present invention and the module listrainer A schematic partial perspective view is shown, FIG. 3 is a schematic perspective view of a module listrainer of a solar cell module array according to an embodiment of the present invention, and FIGS. 4 and 5 are solar cells according to an embodiment of the present invention. A partial cross-sectional view showing a mounting change in accordance with the rotation state of the module listrainer of the module array is shown, Figure 6 is a schematic perspective view of a solar cell module array according to an embodiment of the present invention, Figure 7 of the present invention A schematic cross-sectional view of a solar cell module array according to one embodiment is shown, and FIG. 8 illustrates a solar cell module according to an embodiment of the present invention. A schematic view of a partial projection onto the ground is shown, FIG. 9 is a schematic partial perspective cross-sectional view of a module spacer of a solar cell module array according to an embodiment of the present invention, and FIG. A perspective view of a module back gutter of another example of a solar cell module array according to an embodiment is shown, and FIG. 11 is a state diagram illustrating a mounting state of another example of a module spacer of a solar cell module array according to an embodiment of the present invention. 12 is a schematic cross-sectional view of the module support of the solar cell module array according to an embodiment of the present invention, Figure 13 is a module back gutter portion of the solar cell module array according to an embodiment of the present invention A schematic partial perspective view of another type of is shown, and FIG. 14 shows a model of a solar cell module array according to one embodiment of the invention. A schematic partial perspective view showing a mounting state of a spacer is shown, FIG. 15 is a partial cross-sectional view of a module spacer of a solar cell module array according to an embodiment of the present invention, and FIG. 16 to FIG. 18, a line P1 of FIG. 14 is shown. Schematic partial cross-sectional views of P1, P2-P2, and P3-P3 are shown, and FIG. 19 shows a schematic perspective view of another type of module back gutter of a solar cell module array according to an embodiment of the invention. 20 is a schematic perspective view of yet another type of module back gutter of a solar cell module array according to an embodiment of the present invention, and FIG. 21 is a schematic cross-sectional view taken along the line P4-P4 of FIG. 20. 22 is a schematic rear view of the module support of the solar cell module array according to an embodiment of the present invention.

The solar cell module array 10 according to an embodiment of the present invention includes a solar cell module 100 and a module support part 200. The solar cell module 100 is mounted on and supported by the module support part 200.

The solar cell module 100 includes a solar cell panel, that is, a solar cell module body 110 and a solar cell module frame 120, the solar cell module body 110 converts solar energy into electrical energy. The solar cell module frame 120 is disposed on the outer circumference of the solar cell module body 110 to protect the solar cell module body 110 and achieve a stable mounting structure.

The solar cell module frame 120 according to the present embodiment is disposed on the edge of the solar cell module body 110, the solar cell module frame 120 is a frame body 121 disposed on the outer periphery of the solar cell module body 110 ) And frame body mounting portions 122 and 123. The frame body mounting parts 122 and 123 protrude from the inner surface of the frame body 121 toward the frame body 121, and end portions of the solar cell module body 110 are formed in a space formed by the pair of frame body mounting parts 122 and 123. It forms a structure that is mounted stably.

A frame locking part 125 is disposed at an inner lower end of the frame body 121 to extend toward the inside of the closed curve formed by the solar cell module frame 120, and the frame locking part 125 may be a module supporting part 200. The module mounting parts 125 and 211 are formed together with the body catching part 211 formed in the body.

The module support part 200 is disposed at the lower end of the solar cell module 100. The module support part 200 according to the present embodiment forms an integral inclination structure, but this can be variously modified as an example of the present invention. On one surface of the module support portion 200, the body engaging portion 211 constituting the module mounting portion (125, 211) is disposed as described above. That is, the module support 200 includes a module support body 210, a module support cavity 220, and a module joint connector 230, and the module support cavity 220 is disposed inside the module support body 210. Is formed. That is, the module support body 210 includes the module support cavity 220 as an inner space and the module cavity connecting portion 230 is formed on the inclined surface of the module support body 210 of the module support 200. The module support joint 220 may form a structure in fluid communication with the outside through the module joint connector 230, the module joint connector 230 is delivered to the rain through the module back gutter in the following embodiment It is also possible to collect the rain (water) to serve as a self-weight as a module support for supporting the solar cell module.

The solar cell module array 10 according to the exemplary embodiment of the present invention includes the module wrist liner parts 125, 211 and 300, and the module wrist liner parts 125, 211 and 300 include the module mounting parts 125, 211 and the module wrist liner 300. . The module mounting parts 125 and 211 are formed in the solar cell module frame 120 and the module support part 200, and the module wrist liner 300 is rotatable to the outside of the solar cell module frame 120 by one surface of the module support part 200. Is disposed so as to change the coupling state of the solar cell module 100 and the module support portion 200 through the rotation operation.

The module mounting parts 125 and 211 include a frame locking part 125 and a body locking part 211. As described above, the frame engaging portion 125 is disposed on the frame body 121 disposed outside the inclined direction on the ground of the solar cell module frame 120, and extends inward from the inner end of the frame body 121. Is formed. The body catching part 211 forms a structure that protrudes from one inclined surface of the module support part 200. The frame catching part 125 and the body catching part 211 form a structure that can be engaged with each other.

The module listrainer 300 takes a rotatable structure on the outside of the solar cell module frame 120 with one surface of the module support body 210 of the module support 200, and the module listrainer 300 includes a listrainer body ( 310 and the wrist liner fastening part 320.

The wristrainer body 310 is disposed on one surface of the module support part 20 and forms a structure in which at least a portion of the outer circumferential surface is in contact with the outer surface of the frame body 121 of the solar cell module frame 120. The wrist liner body 310 forms a rectangular structure, and when the wrist liner body 310 rotates, the length of the long axis length L (see FIG. 3) and the short axis length S (see FIG. 3) of the wrist liner body 310 is rotated. Due to the difference in length, a change in contact state with the outer circumferential surface of the frame body 121 occurs.

An outer circumferential surface of the outer liner body 310 and an outer circumferential surface in contact with the solar cell module frame 120 is arranged, the restrainer body chamfer 312, which is adjacent to the solar cell module frame when the rotational body 310 forms a rotational movement It is a structure to make a smooth contact with the outer surface of the frame body 121 of (120). The wrist liner body wrench portion 313 is disposed on one surface of the wrist liner body 310, and the wrist liner body wrench portion 313 forms a hexagonal receiving structure to enable a smooth connection with a fastening tool such as a hexagon wrench. can do.

The wristlane fastening unit 320 is disposed at the bottom of the wristliner body 310 to be connected to the wristliner body 310. The wristlane fastening part 320 forms a structure that can be inserted into the module support part 200. The listrainer fastening protrusion 321 is disposed on an outer circumference of the listrainer fastening part 320, and the listrainer fastening protrusion 321 is formed on the module support part body 210 of the module support part 200. ) To achieve a state of rotational fastening. That is, a thread structure corresponding to the inner side surface of the module wrist restrainer mounting part 213 is formed to enable the rotation of the module wrist restrainer 300.

In addition, the bottom liner fastening portion 320, the bottom liner fastening elastic portion 323 is disposed, the wrist liner fastening elastic portion 323 is the wrist liner fastening elastic projection 324 and the listrainer fastening elastic groove 325. Includes, the listrainer fastening elastic portion 323 is spaced apart from the listrainer fastening protrusion 321 by a predetermined distance. When the lower end of the wrist liner fastening part 32 is inserted into and mounted on the module wrist liner mounting part 213, it is elastically deformed to allow smooth insertion into the module wrist liner mounting part 213 but undesirably through the lister fastening elastic protrusion 324. It can be prevented from being separated from the module listrainer mounting portion 213, so that even when the solar cell module 100 and the module support portion 200 is separated, the module listrainer mounting portion 213 occupies a predetermined position. Concerns about missing elements can be prevented and subsequent work can be performed smoothly.

On the other hand, the frame locking portion 125 forms a structure that can be engaged with the body locking portion 211, the body locking portion 211 is one surface and the body locking portion receiving portion of the module support portion body 210 of the module support portion 200 212 is formed so that the frame locking portion 125 may be accommodated in the body locking portion receiving portion 212. When the frame catching portion 125 is accommodated and disposed in the body catching portion receiving portion 212 and the frame body 121 is pressed from the outside by the module wrist liner 300, an end portion of the body catching portion 211 may be a frame body. It may be in contact with the inner surface of the 121, unlike in the present embodiment, when the module wrist liner 300 is rotated, the inner end of the frame engaging portion is in contact with the inner surface of the body engaging portion disposed inside the body receiving portion receiving portion Various changes are possible, such as to form a.

On the other hand, in the present embodiment, the distance between the end of the body engaging portion 211 and the rotational central axis (OO) of the module list liner 300, a reference numeral a, of the list liner body 310 of the module list liner 300 When the major axis length is denoted by reference numeral L, the minor axis length is denoted by S, and the thickness of the frame body 121 is denoted by t, they form the following relationship.

,

,

Here, γ is an adjustment variable for adjusting the mounting pressure state between the solar cell module and the module support portion through the module wrist liner 300, to prevent the change of other components and at the same time to maintain the pressure mounting force as described above It is desirable to maintain the numerical range.

As shown in FIGS. 4 and 5, when the module wrist liner 300 is mounted on the module wrist liner mounting part 213 of the module support body 210 and takes an alignment structure constituting a short axis length S, the solar cell module 100 is smoothly disposed on the upper end of the module support portion 200 to prepare the locking state of the body locking portion 211 and the frame locking portion 125. Then, in the case of transmitting the rotational force to the wrist liner body wrench portion 313 through a predetermined fastening tool, when the longitudinal liner body 310 rotates about the central axis OO, the wrist liner body chamfer 313 Presses the frame body 121 in contact with the outer circumferential surface of the frame body 121, and the pressing force is transmitted to the solar cell module 100 to form an engagement state between the frame locking portion 125 and the body locking portion 211. By positioning the frame body 121 between the end of the body engaging portion 211 and the outer circumferential surface of the wrist liner body 310 to form a position fixing state between the solar cell module 100 and the module support portion 200 Can be. At this time, the frame locking portion 125, the body locking portion 211, and the module wrist liner 300 forms the mechanical relationship as described above.

Meanwhile, a module spacer 400 is disposed between the plurality of solar cell modules 100 of the solar cell module array 10 according to the present invention to maintain a constant distance between the solar cell modules. The module spacer 400 (see FIG. 2) includes a module space body 410 and a module space connector 420, the module space connector 420 being connected to the bottom of the module space body 410, and the module space body 410. ) Contacts the outer circumferential surface of the solar cell module frame 120 of the solar cell module 100. The module spacer connection part 420 is fixedly mounted on the module support part 400. In this embodiment, the module spacer connection part 420 is formed on the inclined surface of the module support part body 210 of the module support part 200. It may be mounted on the connection 230.

The module spacer 400 may have a structure that is injection molded from a material such as polyethylene or polycarbonate.

On the other hand, a solar cell module array including a module support and a solar cell module according to another embodiment according to the present invention is shown in Figure 6, the solar cell module array (10a) includes a module back gutter 500 . Here, the same reference numerals and names are assigned to the same components as in the above embodiment, and duplicate descriptions are omitted.

The module back gutter part 500 includes a solar cell module 100 and an intersection area (A, C; see FIG. 8) when the solar cell modules 100 are arranged in a row with respect to the ground and are projected with respect to the ground. Collecting rainwater flowing from the surface of the solar cell module 100 disposed on the upper side of the plurality of rows through the region B between the plurality of solar cell modules 100 and collecting the rainwater from the module of each module support unit 200. By transferring to the module support cavity 220 formed as the internal space of the module support body 210 through the joint connection 230, it can be used as a mass for forming a stable solar cell module support structure of the module support 200. . As shown in FIG. 7, the module back gutter part 500 may be implemented in a plate type, wherein the module back gutter part 500 is an end portion of the adjacent solar cell module 100 in parallel to the ground. It is arranged in the row direction of (100). That is, the module back gutter 500 may have a structure connected to the back of the solar cell module 100 arranged in a plurality of rows, through which the module back gutter 500 and the plurality of solar cell modules are connected. The interspace may form a predetermined flow path and stably transmit rainwater flowing from one surface of the solar cell module 100 to the module support part cavity 220 of the module support part 200.

In addition, a plurality of module back gutters 500 may be arranged to have a structure in which each of the plurality of solar cell modules is individually arranged, and between the plurality of module back gutters and the module back gutter 500. The module spacer 400a is disposed in the module spacer 400a, and the module spacer 400a may have a structure in which a predetermined fluid communication is achieved. That is, as shown in Figure 9, the module spacer (400a) is disposed between the plurality of solar cell modules, the solar cell module and the module back gutter portion abuts, such an aspect of the module back gutter portion A predetermined flow port is disposed in an area in which the battery module and the module back gutter portion contact the space where rainwater is collected. That is, the module spacer 400a includes a module spacer body 410a and a module spacer mounting portion 420a. The module spacer body 410a is in contact with the solar cell module and the module spacer mounting portion 420a is connected to the module support 200. It is mounted and connected to the module support cavity 220 of the module support 200. The module spacer body 410a is disposed with a spacer body flow port 411a that allows flow of rainwater flowing from the module back gutter portion 500 adjacent to the module spacer 400a. The spacer body flow port 411a has a structure in which both sides are disposed through, and in some cases, only one side may be opened. The space mounting part 420a is provided with a space mounting part flow hole 421a in fluid communication with the space body flow hole 411a. The solar cell module is formed in the region of the solar cell module and the top row side of the solar cell module and the module rear gutter through the flow connection structure. Rainfall falling from the end of the module is collected to the module support cavity of the module support 200 via the spacer body flow port 411a and the space mount flow port 421a of the module space 400a via the module back gutter.

11 and 12, the rainwater is collected through the module space through the module back gutter to the module support, which may be provided with a module support drain 223, which is usually a module support drain 223. ) Is closed through the module support drain plug 225 and the module support drain plug 225 can be separated therefrom when discharging the water stored inside the module support cavity 220 for movement. In addition, in order to prevent excessive generation of internal vapor pressure due to evaporation of water due to high temperature, the module support part exhaust port 221 may be further provided at the upper end of the module support part 200. In addition, an indicator window 240 (refer to FIG. 22) may be further provided to visually grasp the collection level of the water level or the rainwater inside the module support 200. The indicator window 240 is formed of a transparent window, in which the indicator state line 241 corresponding to one or more preset mounting states is disposed in the indicator window 240 to satisfy the requirement for the module support to perform a function as a predetermined mass. It can also be made available to the manager for visual inspection.

Meanwhile, in the present embodiment, the spacer mounting portion of the module spacer may have a curved rounding structure, but various modifications may be made depending on the design specification such as a straight structure.

In addition, the module back gutter portion may have a unitary structure for each row of the plurality of solar cell modules. That is, as shown in FIG. 10, another plate type module back gutter part 500a is shown, and the module back gutter part 500a has a gutter mounting part 501 for mounting on the solar cell module frame 120. Is disposed, and at least one module back gutter flow hole 503 is disposed at the module back gutter portion 500a. The module back gutter flow port 503 may take a structure connected to the module cavity connecting portion 230 formed on one surface of the module support 200 through the gutter line 510a.

In addition, the module rear gutter portion 500b is disposed in the row direction of the solar cell module 400 in parallel with the ground at the end of the adjacent solar cell module 100, and at least a part of the portion excluding the crossing area is separated from the ground. A gutter round 510b rounded to form the center of curvature OR may be further provided on the opposite side. The outside of the gutter round 510b may be provided with a gutter support part 510b to be fixedly mounted on the solar cell module frame 120 of the solar cell module 100. The gutter mounting part 501 may be disposed on the gutter support part 510b to form a fixing structure through a fastening means such as a bolt with the solar cell module frame. In this case, although not shown, the module spacer having the flow port may have a structure corresponding to that of the spacer body.

In addition, unlike the simple plate type, the module back gutter portion 500c may have a structure that improves mountability. That is, FIGS. 13 to 18 show another type of module back gutter according to an embodiment of the present invention, wherein the module back gutter 500c is fastened to an end horizontal to the ground of the solar cell module frame 120. The back of the module gutter portion 500c includes a gutter body 510c and gutter clips 520c and 530c, and the gutter clips 520c and 530c extend from the gutter body 510c. The gutter body 510c is disposed to have an intersection area when the gutter body 510c is projected on the back surface of the solar cell module 100 as in the above embodiment. The gutter clips 520c and 530c include a gutter clip connection part 520c and a gutter clip catching part 530c. The gutter clip connection part 520c extends at an angle of 90 degrees from both ends of the gutter body 510c. The gutter clip engaging portion 530c forms a structure and is connected to the horizontal end side of the solar cell module frame 120 of the solar cell module 100. That is, as shown in FIG. 16, which is a cross-sectional view taken along line P1-P1 of FIG. 14, the frame horizontal portion 127 of the solar cell module frame 120 is disposed on the horizontal end side of the solar cell module 100. The horizontal portion 127 is a component corresponding to the frame locking portion 125 disposed in the vertical direction in the above embodiment, and may have a structure in which the frame locking portion and the frame horizontal portion extend integrally. The gutter clip connection part 520c, the gutter clip catching part 530c, and the gutter body 510c of the gutter clip take a structure surrounding the outer circumference of the frame horizontal part 127.

FIG. 17 is a cross-sectional view taken along the line P2-P2 of FIG. 14. An end portion of the module spacer 400c is interposed in a space 130 (see FIG. 16) formed by the solar cell module and the module rear gutter part. The module spacer 400c is provided with a module spacer body 410c and a module spacer mounting portion 420c as in the module spacer 400a in the above embodiment, and each has a spacer body flow port 411c and a spacer mounting flow port 421c. ) Are arranged and they have a structure in fluid communication with each other. The difference from the previous embodiment is that the module spacer mount takes a straight structure, which can be variously modified according to the design specification as described above. The module spacer mounting protrusion 430c may be disposed at the end of the module spacer mounting portion 420c to prevent the module spacer mounting portion 420c from being undesirably separated from the module joint connecting portion 230 of the module support 200.

On the other hand, the module back gutter provided in the present invention may further include a component for smooth movement of rainwater. That is, as shown in FIGS. 20 and 21, the module back gutter part 500d is disposed in the row direction of the solar cell module 400 in parallel with the ground to the end of the adjacent solar cell module 100, and crosses an area. At least a part of the part except for the above may have a structure in which a gutter round 510c is formed to be rounded so that the center of curvature OR is disposed on the opposite side to the ground. The outside of the gutter round 510c may be provided with a gutter support part 510c to be fixedly mounted on the solar cell module frame 120 of the solar cell module 100. The gutter mounting part 501 may be disposed on the gutter support part 510c to form a fixing structure through a fastening means such as a bolt with the solar cell module frame. The module back gutter portion 500d further includes a gutter inclined portion 515d in the space 511d formed by the gutter round 510c, and the gutter inclined portion 515d has an inclined surface to provide excellent slope in the inclined direction. Promote smooth flow. In the present embodiment, the gutter inclined portion 515d may be formed in both directions with respect to the gutter inclined center 513d so as to evenly distribute rainwater to the module supports disposed on the left and right sides of the solar cell module.

On the other hand, the solar cell module array according to the invention may further comprise a structure for stable storm water delivery. 23 and 24 show the module back gutter portion 500e of the solar cell module array according to another embodiment of the present invention, which is collected through the flow path formed by the module back gutter portion 500e and the solar cell module. May be introduced directly into the module support cavity through the module joint connection 230e of the module support 200e. Here, the module joint connection portion 230e has a long structure, through which a plurality of solar cell modules and a module back gutter disposed adjacent to each other may form a stable inflow structure. In addition, the module joint connection 230e includes a module joint connection inlet 232e and a module joint connection inlet round 231e, and the module joint connection inlet round 231e surrounds the outside of the module joint connection inlet 232e. Forming an inclined structure allows for smooth ingress into the module support cavity through the superior module cavity connection inlet 232e.

Gutter groove 501e is provided in the module back gutter portion 500e to guide more stable inflow of rainwater, and the gutter groove 501e moves the module support part cavity portion 230e to one surface of the module back gutter portion 500e. Are placed towards guides to excellence. That is, the rainwater flowing through the space formed by the module back gutter part 500e and the plurality of solar cell modules is stably guided to the module joint connection inlet 232e through the gutter groove 501e to provide the module support part 200e. Collection of rainwater can be made to the module support cavity.

In addition, in the solar cell module array according to the present invention, the module cavity screen unit 600 which prevents the inflow and outflow of foreign matter other than the rainwater from the inner space and the outside of the module support may be further extended. That is, as shown in FIG. 25 and FIG. 26, the module cavity screen unit 600 is disposed in the module cavity connection portions 230 and 230e, and the module cavity screen unit 600 includes a unit body 610 and a unit screen ( 620). The unit body 610 is implemented in a ring type, the unit body through-hole 610 is provided to allow the collection into the module support cavity of the rain through the module cavity connection. The unit body 610 is provided with an inclined unit body inclined surface 613 for stable detachment from the module joint connection as in the embodiment of Figs. Inflow can be enabled. In addition, a predetermined unit body protrusion 615 is disposed on an outer circumference of the unit body 610, and a corresponding counterpart is provided at a corresponding position thereof, and in this embodiment, a unit body protrusion counterpart is provided to maintain a predetermined mounting state. It may be further provided.

The lower portion of the unit body 610 is provided with a unit screen 620, the lower portion of the unit screen 620 may have a predetermined horizontal area may enable a smooth entry into the cavity of the excellent module support. The scale of the unit screen 620 can be adjusted according to a predetermined use, but a unit screen having a somewhat larger size of the eye can prevent foreign matter from entering. In addition, after rainwater is stored in the cavity of the module support, which is the inner space of the module support, insects such as mosquitoes may occur under a certain external environment after a certain time. Disinfection can be removed to prevent damage to the environment.

On the other hand, the solar cell module array according to another embodiment of the present invention may take a structure to quickly and smoothly detach the solar cell module to the module support. FIG. 27 shows a solar cell module array according to an embodiment of the present invention. In the solar cell module array 10f, the same components as in the previous embodiment are denoted by the same reference numerals and redundant descriptions thereof will be omitted. .

The plurality of solar cell modules 100 are stably supported by a plurality of module support parts 200f. The rear surface of the solar cell module 100 includes a module back gutter part 500 (see FIG. 6) and a module support part ( A module support cavity is provided inside 200f) to form a support structure using the collected rainwater as a mass. At this time, the module list liner 300 is provided to stably support the plurality of solar cell modules 100. The module list liner 300f includes the solar cell module 100 between the module list liner 300f and the module support part 200f. You can also take a supporting structure.

FIG. 27 and FIG. 28 show a schematic mounting state and a perspective view of the module list liner 300f, and FIGS. 29 and 30 show mounting states showing the mounting state of the module list liner 300f and the solar cell module 100. Shown. The module wrist liner 300f includes a wrist liner fastening part 320, a wrist liner body 310, and a wrist liner foil 330, and the wrist liner fastening part 320 can be inserted into the module support part 200f. , The list liner body 310 is connected to the list liner fastening part 320, the list liner foil 330 is disposed on the rear surface of the list liner body 310 and rotates together when the list liner body 310 rotates. Thus, the solar cell module frame 120f is supported between the one side of the module support part 20f. The wrist liner fastening part 320 may be mounted on the module wrist liner mounting part 213 formed on the module support part 200f. The mutual mounting structure of the module wrist liner mounting portion 213 and the wrist liner fastening portion 320 is the same as in the above embodiment, and thus duplicated description thereof will be omitted.

The wrist liner foil 330 is disposed on one surface of the wrist liner body 310, and the wrist liner foil 330 is formed at a position corresponding to the wrist liner body wrench 313. To achieve a rotational motion of the listrainer body 310. In addition, although not clearly shown here, the wrist liner foil 330 is connected to the wrist liner body 310 to form a relatively fixed structure such that mutual rotation does not occur.

In addition, in the present embodiment, the body locking portion 211f is mounted to the module support body of the module supporting portion 200f, and the body locking portion 211f may be formed in a detachable structure detachable to the module supporting portion 200f. 28 illustrates a body locking part 211f having a structure that can be attached to and detached from the module supporting part 200f. The module supporting part 200f is provided with a body locking part mounting part 214f. A body locking mounting protrusion 212f is provided at a lower end of the body locking portion 211f, and the body locking mounting protrusion 212f may prevent the body locking portion 211f from being separated and separated from the module support portion 200f. have.

As shown in FIG. 28 and FIG. 29, the solar cell module 100 includes a solar cell module body 110 that is a solar cell panel and a solar cell module frame 120f. Unlike in the embodiment, there are no components protruding inward at the bottom. The solar cell module body 110 is disposed inside the solar cell module frame 120f. The solar cell module frame 120f disposed at the side of the solar cell module body 110 has a body catching portion 211f and a moduleless. It is arranged between the trainers 300f. In the module list liner 300f, the list liner foil 330 is disposed on the top of the list liner body 310. The listrainer foil 330 has a rectangular structure, and when the solar cell module is disposed on one surface of the module support unit as shown in FIG. 29, the surface forming the shorter side of the listrainer foil 330 faces the module frame 120f. do.

Then, when the module wrist liner mounted on the module support part is rotated by the operator through the wrist liner fastening part 320, as shown in FIG. 30, the rectangular wrist liner foil 330 is formed of the solar cell module frame 120f. The solar cell module frame 120f may be disposed between the upper surface and the upper surface of the module support to prevent the solar cell module 100 from being separated from the top and bottom.

In addition, at the same time, at least a part of the wrist liner body 310 may be in contact with the solar cell module frame 120f so that the solar cell module frame 120f may be held between the body latch part 211f. That is, when the wrist restrainer body 310 of the module wrist restrainer 300f also takes the rectangular structure and rotates from the shortened state of FIG. 29 to the long axis state of FIG. 30 as in the previous embodiment, the body catching portion 211f and the lease The solar cell module frame 120f may be disposed between the trainer body 310 to prevent unwanted left and right movement and departure.

On the other hand, in the above embodiment is formed of a structure in which the wrist liner foil and the wrist liner body are arranged separately, it may take a structure in which they are integrated. That is, as shown in FIG. 31, a module listener 300g having an integrated listrainer foil and a listrainer body may be provided in the solar cell module array. The module listrainer 300g having an integrated listrainer foil may be provided. ) Includes a solar cell module body 110 and a solar cell module frame 120g. The solar cell module frame 120g includes a frame body 121 and frame body mounting parts 122 and 123g. The frame body mounting parts 122 and 123g protrude from the inner surface of the frame body 121 toward the frame body 121. The frame body mounting parts 122 and 123g of the solar cell module body 110 are formed in a space formed by the pair of frame body mounting parts 122 and 123g. It forms a structure in which the end is mounted stably.

The side frame body mounting portion 123g of the solar cell module frame 120g is located between the body catching portion 211 and the module wrist liner 300g when viewed from the left and right, and the vertical liner foil and module when viewed from the vertical basis. It is arranged between the supports. Through such a structure, a stable vertical and / or horizontal mounting structure can be formed. In addition, in this embodiment, the body catching portion 211 of the structure that is integrally injected in the previous embodiment and integrated into the module support body may be used to achieve a separate mounting process and generalization.

On the other hand, in the above embodiments, although the wrist liner body of the module wrist liner is only shown as a simple integral injection structure, the wrist liner body has a variable structure and can be variously adapted to changes in the size of the module support and the solar cell module. It may take a general purpose structure. That is, a modified example of the module list liner 300h is shown in FIG. 32. The module list liner 300h includes a list liner body 310h and a list liner fastening part 320, and the list liner body 310h and the lease are provided. The trainer fastening part 320 takes a structure connected to each other. The wrist liner body 310h includes a wrist liner main body 311h, a wrist liner movable body 312h, and a wrist liner body elastic portion 330h. The wrist liner main body 311h has a structure that is connected to the wrist liner fastening part 320, and the wrist liner movable body 312h is disposed to be relatively movable on the wrist liner main body 311h. The outer circumferential surface of the wrist liner movable body 312h may have a smooth curved structure to make a smooth contact with the solar cell module frame as in the above embodiment.

The wrist liner elastic part 330h is disposed between the wrist liner movable body 312h and the wrist liner main body 311h, and the wrist liner elastic part 330h includes the wrist liner movable body 312h and the wrist liner main body 311h. Elastic force between 311h). In this embodiment, in order to take a stable structure, the wrist liner elastic part 330h is described based on a structure having a plurality, but is not limited thereto. The main body elastic mounting part 311-1h and the movable body elastic mounting part 312-1h are respectively disposed on the wrist liner main body 311h and the wrist liner movable body 312h. Each of them may be disposed to form a stable operating state.

In addition, when the restrainer movable body is elastically supported by the restrainer elastic part 330h, a component for achieving a stable movable state may be further provided. That is, the wrist liner body 310h may further include a wrist liner movable guide 340h. The wrist liner movable guide 340h may separate the separation between the wrist liner movable body 312h and the wrist liner main body 311h. In this embodiment, the listrainer movable guide 340h is disposed on the listrainer movable body and the listrainer movable guide receiving portion 311-3h is disposed at a corresponding position thereof. It may take the structure which becomes. In addition, a movable guide stopper 341h may be provided at the end of the wristliner movable guide to prevent unwanted separation from the wristliner main body of the wristliner movable body. 33 and 34 show the operating state of the module list rainer 300h of the movable variable structure as described above, wherein the module list rainer 300h is not in contact with the solar cell module frame and the list rain main body and the list rain liner. A gap indicated by reference numeral t1 is formed between the movable bodies, but when the module wrist liner rotates during the mounting of the solar cell module, the wrist liner movable body presses the elastic part of the wrist liner to move toward the main body of the list liner, so that the gap between the movable bodies is formed. It is also possible to take a structure in which a gap of reference t2 (t1> t2) is formed. Through the module list liner having the movable variable structure, it is possible to proactively cope with the change in the specifications of the solar cell module frame or the module support, thereby securing the versatility of the component.

In addition, although the module wrist liner of the movable variable structure has an elastic support structure for the solar cell module in the horizontal direction, it may have an elastic support structure in the vertical direction. That is, as shown in FIG. 35, the module listrainer 300i may include a listrainer foil 330i having an elastic clip structure. In this embodiment, the wristrainer body 310i takes a circular cross-sectional structure instead of a rectangular structure, which can be cooked according to design specifications. The elastic clip type wrist liner foil 330i includes a foil center portion 331i, a foil contact portion 333i, and a foil end portion 335i. The foil center portion 331i is connected to the wrist liner body 310i and the foil contact portion ( 333i is in contact with one surface of the solar cell module frame (see FIG. 27), and the foil end 335i is disposed upward with the foil contact portion 333i between the foil center portion 331i to rotate the listrainer body 310i. The interference with the solar cell module frame can be prevented. A wrench portion 313 may be formed at the foil center portion 331i to enable the rotation operation by the operator. The elastic clip type wrist liner foil 330i is formed of steel or synthetic vertical having a predetermined elasticity.

Meanwhile, in the above embodiment, the module spacer has been described based on a structure including a module spacer body and a module spacer mounting unit, but the module spacer according to the present invention is not limited thereto. That is, as shown in FIGS. 36 and 37, the module spacer 400j may have a structure including only the module spacer body. That is, the module spacer 400j includes a spacer row support 413j and a spacer column support 415j. The spacer row support 413j supports between the solar cell modules in a row unit, and the spacer column support 415j is provided. Supports between solar cell modules in rows. FIG. 37 is a schematic side view of a state in which the module spacer 400j is mounted, in which Ap denotes an area in contact with the solar cell module of the spacer column support 415j, and Ag denotes a module back gutter portion ( 500 indicates an area where it is mounted.

At this time, the spacer row support part flow part 411j is formed along the longitudinal direction of the space row support part 413j, and the module back gutter part 500 is formed at the intersection of the spacer row support part 413j and the spacer column support part 415j. A spacer body flow port 412j may be formed in the interregion to allow rainwater collected from both sides of the module spacer to flow into the module support cavity through the lower module cavity connection. Through such a structure, the gap between the plurality of solar cell modules may be kept constant, and the structure of minimizing the resistance elements may be taken to achieve smooth and rapid flow of rainwater.

In addition, when the solar cell module array of the present invention takes an excellent collection structure, the module support portion may take a structure to strengthen the bearing force to achieve a more stable solar cell module structure. That is, as illustrated in FIGS. 38 to 40, a module support bumper 250 may be further provided on the outer circumference of the module support part 200k to reinforce the rigidity of the module support part 200k. 40 is a cross-sectional view taken along the line k-k of FIG. 39.

In the present exemplary embodiment, the module support bumper 250 is formed in a direction perpendicular to the ground, and in order to stably support the vertical load of the solar cell module 100, a horizontal bumper may be further provided in some cases.

In addition, the module support part 200k may further include a module support part through part 260 formed therethrough from one side to the other side. The module support penetrating portion 260 may enhance the rigidity of the module support, mitigate the expansion caused by the evaporation of rainwater collected therein due to the heat, and at the same time will reduce the transportability and manufacturing cost in the mounting process. Can be.

The above embodiments are examples for describing the present invention, and various modifications are possible in the range including the module wristrainer or the module back gutter, without being limited thereto.

The solar cell module array of the present invention can be mounted and utilized in various terrains, and can be utilized as a power supply means through linkage with other devices as well as its own power generation facility.

Claims (31)

1. A plurality of solar cell modules including a solar cell module body for converting solar energy into electrical energy and a solar cell module frame disposed on an outer circumference of the solar cell module;

   A solar cell module array having a module support for supporting the solar cell module,

   A module mounting part formed on the solar cell module frame and the module support part;

   It includes a module list rainer portion that is rotatably disposed on the outside of the solar cell module frame to one surface of the module support portion including a module list rainer for changing the coupling state of the solar cell module and the module support through a rotation operation. The solar cell module array characterized in that.
2. The method of claim 1,

   The module mounting portion:

   A frame engaging portion disposed outside the inclined direction on the ground of the solar cell module frame;

   The solar cell module array characterized in that it comprises a body engaging portion which is arranged to be engaged with the frame engaging portion.
3. The method of claim 2,

   The module listrainer is:

   A wrist liner body disposed on one surface of the module support and at least a portion of an outer circumferential surface thereof contacts the solar cell module frame;

   Solar cell module array characterized in that it is connected to the wrist liner body and has a wrist liner fastening portion insertable to the module support.
4. The method of claim 3,

   The solar cell module array, characterized in that the wrist liner body chamfer is formed in an area of the outer circumferential surface of the wrist liner body to contact the solar cell module frame.
5. The method of claim 4, wherein

   The solar cell module array, characterized in that on one side of the wrist liner body is provided with a wrist liner body wrench for transmitting a rotational force to rotate the wrist liner body.
6. The method of claim 3,

   The outer periphery of the listrainer fastening portion of the solar cell module array, characterized in that the listrainer fastening protrusion for allowing a rotational fastening state to the module support.
7. The method of claim 3,

   The solar cell module array, characterized in that the wrist restrainer fastening elastic portion for preventing separation from the module support portion is provided at the outer peripheral lower end of the wrist liner fastening portion.
8. The method of claim 2,

   The solar cell module frame has a frame body disposed between the body catching portion and the wrist liner, the frame catching portion is disposed perpendicular to the frame body at the bottom of the frame body,

   The wrist liner body forms a rectangular structure when viewed on one surface of the module support,

   Between the thickness t of the frame body, the long axis length L and the short axis length S of the wrist liner body, and the distance a between the pivot center axis of the wrist liner body and the end of the body engaging portion:

   

   ,

   

   ,

   

   The solar cell module array, characterized in that the relationship is formed.
9. The method of claim 1,

   The solar cell module array, characterized in that the module spacer is mounted between the solar cell module to maintain the gap of the solar cell module mounted on the module support.
10. The method of claim 1,

    The module support has a module support cavity as an interior space,

    When the solar cell modules are arranged in a row with respect to the ground, the solar cell module collects rainwater that flows through the bottom of the solar cell module so as to have an intersection area with the solar cell module when projected with respect to the ground. And a module back gutter disposed on a rear surface of the solar cell module so as to be transferred to a support cavity.
11. The method of claim 10,

    And the module rear gutter portion is a plate type disposed in a row direction of the solar cell module in parallel with the ground to an end of the solar cell module adjacent to the ground.
12. The method of claim 10,

    The module rear gutter portion is disposed in the row direction of the solar cell module parallel to the ground to an end portion of the adjacent solar cell module, and at least a part of the portion excluding the crossing area is disposed at the opposite side to the ground. Solar cell module array, characterized in that the gutter round is formed to be rounded.
13. The method of claim 10,

    The module back gutter portion is a solar cell module array, characterized in that the clip type is fastened to the end horizontal to the ground of the solar cell module frame.
14. The method of claim 13,

    The module back gutter portion:

    A gutter body disposed to form an intersection area in the solar cell module;

    And a gutter clip disposed at an end of the gutter body and mounted to the solar cell module frame.
15. The method of claim 10,

    Module spacers are disposed between the solar cell modules to maintain a distance between the solar cell modules and mounted on the module support units.

    The module spacer is:

    A module spacer body in contact with the solar cell module,

    The module spacer body is a solar cell module array, characterized in that provided with a spacer body flow port that allows the flow of rain flow from the module back gutter portion adjacent to the module spacer.
16. The method of claim 10,

    The solar cell module array, characterized in that a gutter inclined portion is provided on one surface of the module rear gutter portion facing the solar cell module to increase the flow of rainwater.
17. The method of claim 16,

    And the gutter inclined portion includes a bidirectional gutter inclined portion protruding from a central portion of the module rear gutter portion in a longitudinal direction.
18. The method of claim 17,

    The module support part, the module support excellent collection unit further comprises a module support excellent corresponding to the end of the module back gutter portion.
19. The method of claim 10,

    The module support unit is a solar cell module array, characterized in that the indicator window for identifying the excellent collection state of the module support unit cavity.
20. The method of claim 19.

    And the indicator window is provided with an indicator state line indicative of a predetermined rainwater collection level.
21. The method of claim 10,

    The module support has a module support cavity as an interior space,

    When the solar cell modules are arranged in a row with respect to the ground, the solar cell module collects rainwater that flows through the bottom of the solar cell module so as to have an intersection area with the solar cell module when projected with respect to the ground. The module back gutter is provided on the back of the solar cell module so as to be delivered to the support cavity,

    The module support is provided with a module joint connection for introducing the rainwater transmitted from the module back gutter portion into the module support cavity,

    One surface of the module rear gutter portion is provided with a gutter groove for guiding the rain toward the cavity of the module support portion.
22. The method of claim 10,

    The module support has a module support cavity as an interior space,

    When the solar cell modules are arranged in a row with respect to the ground, the solar cell module collects rainwater that flows through the bottom of the solar cell module so as to have an intersection area with the solar cell module when projected with respect to the ground. The module back gutter is provided on the back of the solar cell module so as to be delivered to the support cavity,

    The module support is provided with a module joint connection for introducing the rainwater transmitted from the module back gutter portion into the module support cavity,

    And the module cavity connection unit is provided with a module cavity screen unit which allows for excellent flow but limits movement between the outside of the foreign body and the module support cavity.
23. The method of claim 1,

    A plurality of solar cell modules including a solar cell module body for converting solar energy into electrical energy and a solar cell module frame disposed on an outer circumference of the solar cell module;

    A solar cell module array having a module support for supporting the solar cell module,

    A module mounting part formed on the module support part;

    It includes a module list rainer portion rotatably disposed on the outer side of the solar cell module frame to one surface of the module support portion and including a module list rainer for changing the coupling state of the solar cell module and the module support portion through a rotation operation. The module mounting part may include a body locking part disposed to be in contact with the solar cell module frame, and the module wrist liner may include:

    A wrist liner fastening part insertable and disposed in the module support part;

    A wrist liner body connected to the wrist liner fastening portion,

    A solar cell disposed on one surface of the wrist liner body and provided with a wrist liner foil which rotates together to support the solar cell module frame between one surface of the module support part when the wrist liner body rotates. Module array.
24. The method of claim 23,

    At least a portion of the wrist liner body is in contact with the solar cell module frame, the solar cell module array, characterized in that for holding the solar cell module frame between the body engaging portion.
25. The method of claim 24,

    The body latching unit is a solar cell module array, characterized in that detachable to the module support.
26. The method of claim 23,

    The listrainer body is:

    A listrainer main body connected to the listrainer fastening part,

    A listrainer movable body disposed relatively to the listrainer main body,

    And a wrist liner body elastic part elastically supported between the wrist liner movable body and the wrist liner main body.
27. The method of claim 26,

    The wrist liner body further includes a wrist liner movable guide for preventing separation and separation between the list liner movable body and the list liner main body and guiding relative operation.
28. The method of claim 23,

    The listrainer foil is a solar cell module array, characterized in that the elastic clip type.
29. The method of claim 1,

    The outer periphery of the module support portion is provided with a module support bumper for enhancing the rigidity in the direction perpendicular to the ground of the module support portion.
30. The method of claim 1,

    The module support part is a solar cell module array, characterized in that the through the module support portion is formed penetrating from one side to the other side.
31. A plurality of solar cell modules including a solar cell module body for converting solar energy into electrical energy and a solar cell module frame disposed on an outer circumference of the solar cell module;

    A solar cell module array having a module support for supporting the solar cell module,

    The module support has a module support cavity as an interior space,

    When the solar cell modules are arranged in a row with respect to the ground, the solar cell module collects rainwater that flows through the bottom of the solar cell module so as to have an intersection area with the solar cell module when projected with respect to the ground. And a module back gutter disposed on a rear surface of the solar cell module so as to be transferred to a support cavity.

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