TWM603645U - Auxiliary drainage structure of solar photovoltaic module - Google Patents

Abstract

This creation reveals a drainage structure, which mainly consists of a ㄩ-shaped bracket, two water tank slices, a horizontal drainage strip and several solar photovoltaic panels. The ㄩ-shaped bracket is installed on the truss of the scaffold in multiple numbers. In addition to providing support for the solar photovoltaic panels, it also serves as the collection and discharge of the longitudinal water between the solar photovoltaic panels; the sink piece can be buckled Hung on the side end of the ㄩ-shaped bracket, so that the water-receiving groove piece is attached to the ㄩ-shaped bracket; the horizontal drainage strip is a ㄩ-shaped metal strip, which can be horizontally arranged under the gap between the two solar photovoltaic panels, and its The side end is extended to the water collection trough of the water trough piece. Thereby, the horizontal drainage strip can receive the horizontal water between the solar photovoltaic panels, and guide it to the water collecting trough of the water trough plate for discharge.

Description

Auxiliary drainage structure of solar photovoltaic module

The creation of this case is an auxiliary drainage structure, especially a scaffold drainage structure connected under the scaffolding of solar photovoltaic modules to receive and evacuate rainwater.

According to the fact that the topic of green renewable energy has attracted much attention from all walks of life, among which solar power generation has attracted the most attention and favor, and the huge manpower and material resources have been invested in the solar energy industry, so that the solar photovoltaic industry gradually has mature technology and economic value. Therefore, solar photovoltaic The construction of the factory will receive more attention, and the hardware installation technology of solar photovoltaic modules will have its urgent needs.

At present, for the installation position of the aforementioned solar power modules, a hinterland is taken as a base, and a scaffolding 10 (as shown in FIG. 1) is constructed on the base. The scaffolding 10 includes a plurality of vertical columns 11, which are arranged on each column. A truss 12 is set between 11. In order to consider factors such as light-receiving area, drainage characteristics, etc., the truss 12 is usually set in an inclined shape with a low front and a high rear. The photovoltaic panel 14 is laid on the support 13 and the solar photovoltaic panel 14 absorbs solar thermal energy and converts it into electrical energy.

However, it is found that the conventional scaffold 10 is mainly used for assembling and fixing several solar photovoltaic panels 14, and there is a space between each solar photovoltaic panel 14 for installation. For installation and fixing purposes, if the distance is rainy, it will cause water seepage under the scaffolding 10. Therefore, the industry has set a trough in the aforementioned bracket 13 and the trough of the bracket 13 can be used for two The water overflowing from the longitudinal (front-to-rear) spacing of the solar photovoltaic panels 14 allows the water to be discharged to the front end (lower end) of the solar shelf 10 through the ㄩ-shaped bracket 13 as a drainage groove.

However, although the aforementioned conventional scaffolding 10 has a drainage design, it is limited to the water overflowing from the longitudinal (front-to-back) spacing of the solar photovoltaic panels 14 to collect and divert it. If the solar photovoltaic panels 14 are horizontal (left-right) The water overflowing from the gap will still drip directly under the scaffold 10, so that the scaffold 10 cannot achieve the function of sheltering the rain, which is a major defect.

In order to solve the aforementioned problem that the scaffold 10 cannot shelter from rain, a conventional method is to insert a corrugated board layer between the beams 13 of the scaffold 10 and the solar photovoltaic panels 14, so that the distance between the solar photovoltaic panels 14 is leaked. The rainwater is guided by the grooves of the corrugated board to a low source for discharge; however, the corrugated board needs to be widely installed under the solar photovoltaic panel 14 in a large area. In addition to the cost, the corrugated board is sandwiched between the scaffold and the solar photovoltaic panel 14 In the meantime, an interlayer will be formed and there will be a lack of dirt collection and ash collection. At the same time, large-area shielding will not be conducive to the maintenance and inspection of the solar photovoltaic panel 14.

The purpose of the creation of this case is to improve the drainage problems of the conventional scaffolds carrying solar photovoltaic panels, and then provide a drainage structure of the scaffolds to achieve the purpose of effectively receiving and dispersing rainwater.

In order to achieve this goal, this case is mainly an auxiliary drainage structure for solar photovoltaic modules, which mainly includes a ㄩ-shaped bracket, two water tanks, and a horizontal drainage type. It consists of strips and several solar photovoltaic panels. The ㄩ-shaped bracket is installed on the truss of the scaffold in plural to provide the supporting function of the solar photovoltaic panel; the water receiving groove sheet has a buckling part, and a water collecting groove extends beside the buckling part. The part can be buckled on the side end of the ㄩ-shaped bracket, so that the water receiving groove piece is attached to the ㄩ-shaped bracket; the horizontal drainage strip is a ㄩ-shaped metal strip, which can be horizontally arranged in the gap between the two solar photovoltaic panels Below, and its side end is extended to the water collecting trough of the water trough piece. In this way, the ㄩ-shaped bracket can collect the longitudinal water between the solar photovoltaic panels, and the horizontal drainage strip can receive the lateral water between the solar photovoltaic panels and guide it to the water collection trough of the water trough for discharge.

"Learning part"

10: Scaffolding

11: Column

12: Frame

13: beam

14: Solar photovoltaic panels

"Part of the case"

20: ㄩ type bracket

21: Card Edge

30: connect the sink piece

31: Fastening part

32: Sump

40: Horizontal drainage strip

50: Solar photovoltaic panels

51: fixed element

Figure 1 shows a three-dimensional structure diagram of a conventional scaffold;

Figure 2 shows the three-dimensional structure of this creation;

Figure 3 shows a plan view of this creative combination;

Figure 4 shows a schematic diagram of the drainage of this creation.

The technical content, features and effects of the present invention will be clearly presented in the following detailed description of the preferred embodiments with reference to the drawings. Before this case is described in detail, special explanation is needed. The attached drawings illustrate the basic structure of the case in a schematic way. Therefore, only the structures or elements related to the case are shown in these drawings, and the structural shapes, Size, ratio, or number of components, etc., the actual size of the actual implementation size or component layout form may be Can be more complicated.

Please refer to FIG. 2 for a structural diagram of a specific embodiment of the present creation; and FIG. 3 for a combined plan view of a specific embodiment of the present creation. The specific embodiment of the creation of this case includes a ㄩ-shaped bracket 20, two water tank plates 30, a horizontal drainage type bar 40 and a number of solar photovoltaic panels 50; among them:

The ㄩ-shaped brackets 20 are installed on the truss of the scaffold (not shown in the figure) in plural to provide support for the solar photovoltaic panels 50. The spacing of the ㄩ-shaped brackets 20 depends on the size specifications of the solar photovoltaic panels 50. It is set to form a scaffold accordingly; the ㄩ-shaped bracket 20 is generally ㄩ-shaped, and the two end edges form a catch edge 21.

The water receiving groove piece 30 is a metal strip with a buckling portion 31, and a water collecting groove 32 extends beside the buckling portion 31. The buckling portion 31 can be buckled on the locking edge 21 of the ㄩ-shaped bracket 20 so that the water receiving groove piece 30 is attached to the ㄩ-shaped bracket 20, and the water collecting groove 32 is adjacent to the side of the ㄩ-shaped bracket 20.

The horizontal drainage strip 40 is a ㄩ-shaped metal strip, which can be arranged transversely under the gap between the two solar photovoltaic panels 50, and can then receive the water flowing down from the gap between the two solar photovoltaic panels 50; When the profile bar 40 is horizontally arranged under the gap between the two solar photovoltaic panels 50, its two side ends extend into the water collection trough 32 of the water receiving trough plate 30.

The solar photovoltaic panel 50 is a solar panel used in solar photovoltaic modules to absorb solar thermal energy and convert it into electrical energy. The solar photovoltaic panel 50 can be laid on a number of ㄩ-shaped brackets 20 of the scaffolding 20 and fixed by a fixing element 51 .

According to the above structure and with reference to Figure 4, the ㄩ-shaped bracket 20 is provided for the solar photovoltaic panel 50 to support and is arranged in a straight manner, so that two adjacent solar panels The water overflowing from the vertical spacing of the photovoltaic panel 50 can be received by the ㄩ-shaped bracket 20 and directly collected and discharged by the ㄩ-shaped bracket 20; in particular, the buckling portion 31 of the water receiving groove piece 30 can be buckled on the ㄩ-shaped bracket The catching edge 21 of the bracket 20 makes the water collection trough 32 of the water receiving trough sheet 30 immediately adjacent to the side of the ㄩ-shaped bracket 20. Furthermore, the horizontal drainage strip 40 is arranged horizontally below the gap between the two solar photovoltaic panels 50, And the lateral end of the horizontal drainage strip 40 is located at the upper end of the water collection trough 32 of the water trough plate 30. When the horizontal drainage strip 40 receives the water flowing down from the gap between the two solar photovoltaic panels 50, it is used to guide the water. Flow into the sump 32; thus, after the solar photovoltaic panel 50 is laid on the ㄩ-shaped bracket 20, the water in the vertical gap can be directly collected and discharged by the ㄩ-shaped bracket 20, and the water in the horizontal gap can be collected and discharged from the horizontal gap. The drainage profile 40 takes over and diverts the water to the sump 32 for discharge.

Therefore, the creation of this case through the cooperation of the above components will have the following gains: the ㄩ-shaped bracket 20 continues to collect the vertical water and liquid function between the solar photovoltaic panels 50 under the existing structural frame, and this creation will receive the water trough sheet 30 is buckled on the side of the ㄩ-shaped bracket 20, so that the horizontal drainage strip 40 receives the horizontal water between the solar photovoltaic panels 50 and guides it to the water collection trough 32 of the water receiving trough plate 30 for discharge, so that it is in the original structure Next, add the design of two connecting water trough pieces 30 and horizontal drainage profile 40 to achieve a comprehensive vertical and horizontal drainage design, which is really ingenious.

In this case, the vertical ㄩ-shaped bracket 20 is used as the main drainage channel, together with the water trough piece 30 and the horizontal drainage profile 40 to collect and discharge the horizontal overflow, which not only makes it easier to drain the water and achieve effective drainage purposes, but also The simple design of the water receiving groove piece 30 and the horizontal drainage profile 40 is more convenient for installation and construction, creating excellent industrial value.

From the above description and the preferred embodiments shown in the drawings, The structure of this case provides many advantages that acquaintances cannot. The case does have significant industrial applicability, and the technical means and structural features used in it are indeed developed by the creator of the case. The case sincerely complies with the requirements of the patent. , Yan filed an application according to law. In addition, the description of the element structure in the text in this creation can be easily modified by those skilled in the art, or equivalent alternative structures should also fall within the scope of the attached patent application.

20: ㄩ type bracket

21: Card Edge

30: connect the sink piece

31: Fastening part

32: Sump

40: Horizontal drainage strip

50: Solar photovoltaic panels

Claims (1)

An auxiliary drainage structure for solar photovoltaic modules, which mainly includes a ㄩ-shaped bracket, two water tank pieces, a horizontal drainage strip and a number of solar photovoltaic panels; the ㄩ-shaped bracket is installed on the truss of the scaffold in plural, To provide the supporting function of the solar photovoltaic panel, the ㄩ-shaped bracket is generally in the shape of ㄩ, and the two side edges form a catch: the water receiving groove piece has a buckling part, and a water collecting groove extends beside the buckling part. The buckling part can be hooked on the locking edge of the ㄩ-shaped bracket, so that the water receiving groove piece is attached to the ㄩ-shaped bracket, and the water collection tank is next to the side of the ㄩ-shaped bracket; the horizontal drainage strip is a ㄩ-shaped The metal profile can be horizontally arranged under the gap between the two solar photovoltaic panels. When the horizontal drainage profile is laterally arranged under the gap between the two solar photovoltaic panels, its two side ends extend to the water collection trough of the water receiving trough sheet; In this way, the ㄩ-shaped bracket can collect the longitudinal water between the solar photovoltaic panels, and the horizontal drainage strip can receive the lateral water between the solar photovoltaic panels and guide it to the water collection trough of the water trough for discharge.

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