CN214411220U - Frameless photovoltaic module building integration support and integrated structure - Google Patents

Abstract

The utility model discloses a frameless photovoltaic module building integration support and integral structure. A frameless photovoltaic module building integrated structure comprises an integrated support, a frameless photovoltaic module and a purline, wherein the frameless photovoltaic module is positioned on the purline; the frameless photovoltaic module consists of photovoltaic cell pieces which are arranged in a grid shape; the integrated bracket comprises a transverse bracket and a longitudinal bracket; two adjacent rows of photovoltaic cells are connected by a transverse support, and two adjacent rows of photovoltaic cells are connected by a longitudinal support. The frameless photovoltaic module building integrated structure has high structural strength, good stability and high safety; the frameless photovoltaic module is used for directly replacing a color steel tile structure, so that the cost is reduced; the full utilization of light energy is realized, and energy is saved; the frameless photovoltaic module has a good heat insulation effect, light energy irradiated on the frameless photovoltaic module is converted into electric energy to be stored or reflected, and the comfort of the indoor environment is improved.

Description

Frameless photovoltaic module building integration support and integrated structure

Technical Field

The utility model relates to a frameless photovoltaic module building integration support and integral structure belongs to frameless photovoltaic module building technical field.

Background

Under the trend of increasingly shortage of energy, photovoltaic power generation provides an infinite development space for the electric power demand of people. With the continuous maturity of solar power generation technology and the reduction of manufacturing cost, people have continuously improved the acceptance of solar roof power generation systems, and people begin to consider how to integrate solar power generation and building roofs. Although the related reports on photovoltaic and building roof integration are also reported in the prior art, the sealing property, the structural stability and the like still need to be further improved.

SUMMERY OF THE UTILITY MODEL

The utility model provides a frameless photovoltaic module building integration support and integral structure for leakproofness and structural stability have all had obvious promotion, the cost is reduced simultaneously.

For solving the technical problem, the utility model discloses the technical scheme who adopts as follows:

a frameless photovoltaic module building integrated bracket comprises a transverse bracket and a longitudinal bracket;

the transverse bracket comprises a transverse sealing strip and a transverse water chute; the transverse sealing strip comprises a splicing strip, the top of the splicing strip is provided with a baffle arranged along the length direction, two sides of the baffle exceed the splicing strip, the longitudinal section of the top of the baffle is triangular, and the bottoms of the baffles on two sides of the splicing strip are in a planar structure; the transverse water chute comprises a first rectangular groove, the notch of the first rectangular groove is upwards arranged right below the splicing strip, the length direction of the first rectangular groove is consistent with that of the splicing strip, the bottom of the splicing strip extends into the first rectangular groove, the outer sides of two sides of the top of the notch of the first rectangular groove are respectively provided with a first side wing, the heights of the first side wings at two sides are equal, and the first side wings are perpendicular to the side walls of the first rectangular groove where the first side wings are arranged;

the longitudinal support comprises a longitudinal pressing block and a longitudinal water chute; the longitudinal pressing block comprises a second rectangular groove, second side wings are arranged on the outer sides of two sides of the top of a notch of the second rectangular groove, the heights of the second side wings on the two sides are equal, and the second side wings are perpendicular to the side walls of the second rectangular groove where the second side wings are located; the longitudinal water chute comprises a third rectangular groove and a fourth rectangular groove, third side wings are arranged on the outer sides of two sides of the top of a notch of the third rectangular groove, the heights of the third side wings on the two sides are equal, and the third side wings are perpendicular to the side walls of the third rectangular groove where the third side wings are located; the two fourth rectangular grooves are of the same structure, the notches of the third rectangular grooves face downwards, the notches of the two fourth rectangular grooves face upwards and are symmetrically arranged on two sides of the third rectangular grooves, the third side wing and the top of the side wall of the adjacent fourth rectangular groove are connected into a whole, a fourth side wing is arranged on the outer side of the top of one side, which is not connected with the third side wing, of the fourth rectangular groove, the fourth side wing is perpendicular to the side wall of the fourth rectangular groove where the fourth side wing is located, and the third side wing is flush with the upper surface of the fourth side wing; the second rectangular groove notch covers the top of the third rectangular groove downwards, and the top of the third rectangular groove is positioned on the inner side of the second rectangular groove.

The top of each part corresponds to the upper surface, and the bottom corresponds to the lower surface.

A frameless photovoltaic module building integrated structure comprises the frameless photovoltaic module building integrated bracket, a frameless photovoltaic module and a purline, wherein the frameless photovoltaic module is positioned on the purline; the frameless photovoltaic module consists of photovoltaic cell pieces which are arranged in a grid shape; two adjacent rows of photovoltaic cell pieces are connected by a transverse support, and two adjacent rows of photovoltaic cell pieces are connected by a longitudinal support; the connection between two adjacent rows of photovoltaic cells is as follows: the splicing strips are positioned between two adjacent rows of photovoltaic cell pieces, and the side edges of the two adjacent rows of photovoltaic cell pieces are respectively clamped between the baffle on the side where the splicing strips are positioned and the first side wing; the connection between two adjacent photovoltaic cell pieces is: the second rectangular groove is positioned between two adjacent rows of photovoltaic cell pieces, the top of the second rectangular groove exceeds the photovoltaic cell pieces, and the side edges of the two adjacent rows of photovoltaic cell pieces are respectively clamped between the second side wing and the third side wing on the side where the two adjacent rows of photovoltaic cell pieces are positioned; at the vertical connection position of the transverse bracket and the longitudinal bracket, the first rectangular groove is vertically communicated with the fourth rectangular groove; the third rectangular grooves in the same row are connected and communicated, and the fourth rectangular grooves in the same row are connected and communicated.

According to the device, the top of the transverse sealing strip is triangular and completely covers the photovoltaic cell pieces on the two sides, so that the sealing performance of the top of the photovoltaic cell piece is ensured as much as possible; the transverse water chute is arranged at the bottom of the splicing strip, and the bottom of the splicing strip extends into the first rectangular groove, so that in case of water seepage, the seepage water can flow into the first rectangular groove along the splicing strip; the first rectangular groove is vertically communicated with the fourth rectangular groove, namely water in the first rectangular groove flows into the fourth rectangular groove and is discharged from two ends of the fourth rectangular groove; meanwhile, the first side wings on the first rectangular grooves can clamp the photovoltaic cell with the baffle plate to ensure sealing, and can support the photovoltaic cell to improve structural strength; the second rectangular groove and the third rectangular groove form clamping fixation for the photovoltaic cell, the arrangement of the second side wings ensures the sealing property of the top of the photovoltaic cell, and the fourth rectangular grooves are symmetrically arranged at two sides of the third rectangular groove, so that in case of water seepage, the seepage water can flow into the fourth rectangular groove along the third rectangular groove and the third side wings; the arrangement of the fourth side wings improves the clamping stability of the photovoltaic cell on one hand, and forms further support for the photovoltaic cell on the other hand, so that the structural strength of the whole device is further improved; the notch of the second rectangular groove covers the top of the third rectangular groove downwards, and the top of the third rectangular groove is positioned at the inner side of the second rectangular groove, namely the second rectangular groove forms pressing fixation on the third rectangular groove, so that the photovoltaic cell is better fixed.

In order to further improve the stability of the frameless photovoltaic module building integrated structure, the frameless photovoltaic module building integrated structure further comprises a fixing screw rod, and the fixing screw rod penetrates through the second rectangular groove and the third rectangular groove to be connected with the purline.

In order to further improve the sealing performance of the whole structure, a sealing gasket is arranged between the first side wing and the photovoltaic cell; a sealing gasket is arranged between the third side wing and the photovoltaic cell; and a sealing gasket is arranged between the four side wings and the photovoltaic cell.

The transverse support and the longitudinal support are arranged in a vertical cross mode, and the first rectangular groove is vertically communicated with the fourth rectangular groove at the vertical connection position of the transverse support and the longitudinal support. So that the water in the first rectangular recess flows into the fourth rectangular recess and is then discharged from both ends of the fourth rectangular recess.

In order to further improve the sealing performance of the structure, one side edge of the first rectangular groove is higher than the other side edge, one side higher than the upper side edge of the first rectangular groove is defined as a high side edge, the other side is defined as a bottom side edge, and the heights of the upper surfaces of the side wings of the bottom side edge are consistent with those of the bottom side edge; the height of the high side wing is the same as that of the bottom side wing.

To further improve the structural stability, the width of the high side flaps is more than twice the width of the bottom side flaps.

In order to further improve the supporting strength of the structure, one end of the fourth side wing is vertically connected with the side wall of the fourth rectangular groove, and the other end of the fourth side wing is vertically bent downwards to form the supporting structure with the 7-shaped longitudinal section.

In order to further improve the sealing performance of the structure, the outer width of the third rectangular groove is equal to the inner width of the second rectangular groove. So that the second rectangular groove can be tightly clamped at the top of the third rectangular groove.

The technology not mentioned in the present invention refers to the prior art.

The frameless photovoltaic module building integrated structure has high structural strength, good stability and high safety; the frameless photovoltaic module is used for directly replacing a color steel tile structure, so that the cost is reduced; the full utilization of light energy is realized, and energy is saved; the frameless photovoltaic module has a good heat insulation effect, light energy irradiated on the frameless photovoltaic module is converted into electric energy to be stored or reflected, and the comfort of the indoor environment is improved.

Drawings

Fig. 1 is a top view of a frameless photovoltaic module building integrated structure according to the present invention;

FIG. 2 is a schematic diagram of the connection of two adjacent rows of photovoltaic cells in FIG. 1;

FIG. 3 is an enlarged view of the point A in FIG. 2;

fig. 4 is a schematic connection diagram of two adjacent rows of photovoltaic cells in fig. 1;

FIG. 5 is an enlarged view of the point B in FIG. 4;

in the figure, 1 is a transverse support, 11 is a transverse sealing strip, 111 is a splicing strip, 112 is a baffle, 12 is a transverse water guiding groove, 121 is a first rectangular groove, 122 is a first side wing, 2 is a longitudinal support, 21 is a longitudinal pressing block, 211 is a second rectangular groove, 212 is a second side wing, 22 is a longitudinal water guiding groove, 221 is a third rectangular groove, 222 is a third side wing, 223 is a fourth rectangular groove, 224 is a fourth side wing, 3 is a frameless photovoltaic module, 4 is a purlin, 5 is a sealing gasket, and 6 is a fixing screw rod.

Detailed Description

For a better understanding of the present invention, the following examples are provided to further illustrate the present invention, but the present invention is not limited to the following examples.

The terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used herein as terms of orientation or positional relationship with respect to one another as shown in the drawings or in use, and are used for convenience in describing the present application and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be considered as limiting the present application.

Example 1

A frameless photovoltaic module building integrated bracket comprises a transverse bracket and a longitudinal bracket;

the transverse bracket comprises a transverse sealing strip and a transverse water chute; the transverse sealing strip comprises a splicing strip, the top of the splicing strip is provided with a baffle arranged along the length direction, two sides of the baffle exceed the splicing strip, the longitudinal section of the top of the baffle is triangular, and the bottoms of the baffles on two sides of the splicing strip are in a plane structure, so that the transverse sealing strip can be tightly attached to the photovoltaic cell; the transverse water chute comprises a first rectangular groove, the notch of the first rectangular groove is upwards arranged right below the splicing strip, the length direction of the first rectangular groove is consistent with that of the splicing strip, the bottom of the splicing strip extends into the first rectangular groove, the outer sides of two sides of the top of the notch of the first rectangular groove are respectively provided with a first side wing, the heights of the first side wings at two sides are equal, and the first side wings are perpendicular to the side walls of the first rectangular groove where the first side wings are arranged;

the longitudinal support comprises a longitudinal pressing block and a longitudinal water chute; the longitudinal pressing block comprises a second rectangular groove, second side wings are arranged on the outer sides of two sides of the top of a notch of the second rectangular groove, the heights of the second side wings on the two sides are equal, and the second side wings are perpendicular to the side walls of the second rectangular groove where the second side wings are located; the longitudinal water chute comprises a third rectangular groove and a fourth rectangular groove, third side wings are arranged on the outer sides of two sides of the top of a notch of the third rectangular groove, the heights of the third side wings on the two sides are equal, and the third side wings are perpendicular to the side walls of the third rectangular groove where the third side wings are located; the two fourth rectangular grooves are of the same structure, the notches of the third rectangular grooves face downwards, the notches of the two fourth rectangular grooves face upwards and are symmetrically arranged on two sides of the third rectangular grooves, the third side wing and the top of the side wall of the adjacent fourth rectangular groove are connected into a whole, a fourth side wing is arranged on the outer side of the top of one side, which is not connected with the third side wing, of the fourth rectangular groove, the fourth side wing is perpendicular to the side wall of the fourth rectangular groove where the fourth side wing is located, and the third side wing is flush with the upper surface of the fourth side wing; the second rectangular groove notch covers the top of the third rectangular groove downwards, and the top of the third rectangular groove is positioned on the inner side of the second rectangular groove.

A frameless photovoltaic module building integrated structure comprises the frameless photovoltaic module building integrated bracket, a frameless photovoltaic module and a purline, wherein the frameless photovoltaic module is positioned on the purline; the frameless photovoltaic module consists of photovoltaic cell pieces which are arranged in a grid shape; two adjacent rows of photovoltaic cell pieces are connected by a transverse support, and two adjacent rows of photovoltaic cell pieces are connected by a longitudinal support; the connection between two adjacent rows of photovoltaic cells is as follows: the splicing strips are positioned between two adjacent rows of photovoltaic cell pieces, and the side edges of the two adjacent rows of photovoltaic cell pieces are respectively clamped between the baffle on the side where the splicing strips are positioned and the first side wing; the connection between two adjacent photovoltaic cell pieces is: the second rectangular groove is positioned between two adjacent rows of photovoltaic cell pieces, the top of the second rectangular groove exceeds the photovoltaic cell pieces, and the side edges of the two adjacent rows of photovoltaic cell pieces are respectively clamped between the second side wing and the third side wing on the side where the two adjacent rows of photovoltaic cell pieces are positioned; at the vertical connection position of the transverse bracket and the longitudinal bracket, the first rectangular groove is vertically communicated with the fourth rectangular groove; the third rectangular grooves in the same row are connected and communicated, and the fourth rectangular grooves in the same row are connected and communicated.

According to the device, the top of the transverse sealing strip is triangular and completely covers the photovoltaic cell pieces on the two sides, so that the sealing performance of the top of the photovoltaic cell piece is ensured as much as possible; the transverse water chute is arranged at the bottom of the splicing strip, and the bottom of the splicing strip extends into the first rectangular groove, so that in case of water seepage, the seepage water can flow into the first rectangular groove along the splicing strip; the first rectangular groove is vertically communicated with the fourth rectangular groove, namely water in the first rectangular groove flows into the fourth rectangular groove and is discharged from two ends of the fourth rectangular groove; meanwhile, the first side wings on the first rectangular grooves can clamp the photovoltaic cell with the baffle plate to ensure sealing, and can support the photovoltaic cell to improve structural strength; the second rectangular groove and the third rectangular groove form clamping fixation for the photovoltaic cell, the arrangement of the second side wings ensures the sealing property of the top of the photovoltaic cell, and the fourth rectangular grooves are symmetrically arranged at two sides of the third rectangular groove, so that in case of water seepage, the seepage water can flow into the fourth rectangular groove along the third rectangular groove and the third side wings; the arrangement of the fourth side wings improves the clamping stability of the photovoltaic cell on one hand, and forms further support for the photovoltaic cell on the other hand, so that the structural strength of the whole device is further improved; the notch of the second rectangular groove covers the top of the third rectangular groove downwards, and the top of the third rectangular groove is positioned at the inner side of the second rectangular groove, namely the second rectangular groove forms pressing fixation on the third rectangular groove, so that the photovoltaic cell is better fixed.

Example 2

On the basis of the embodiment 1, the following improvements are further made: in order to further improve the stability of the frameless photovoltaic module building integrated structure, the frameless photovoltaic module building integrated structure further comprises a fixing screw rod, and the fixing screw rod penetrates through the second rectangular groove and the third rectangular groove to be connected with the purline.

Example 3

On the basis of the embodiment 2, the following improvements are further made: in order to further improve the sealing performance of the whole structure, a sealing gasket is arranged between the first side wing and the photovoltaic cell; a sealing gasket is arranged between the third side wing and the photovoltaic cell; and a sealing gasket is arranged between the four side wings and the photovoltaic cell.

Example 4

On the basis of the embodiment 3, the following improvements are further made: in order to further improve the sealing performance of the structure, one side edge of the first rectangular groove is higher than the other side edge, one side higher than the upper side edge of the first rectangular groove is defined as a high side edge, the other side is defined as a bottom side edge, and the heights of the upper surfaces of the side wings of the bottom side edge are consistent with those of the bottom side edge; the height of the high side wing is the same as that of the bottom side wing.

Example 5

On the basis of the embodiment 4, the following improvements are further made: to further improve the stability of the structure, the width of the high side flaps is twice the width of the bottom side flaps. In order to further improve the supporting strength of the structure, one end of the fourth side wing is vertically connected with the side wall of the fourth rectangular groove, and the other end of the fourth side wing is vertically bent downwards to form the supporting structure with the 7-shaped longitudinal section.

Example 6

On the basis of the embodiment 5, the following improvements are further made: in order to further improve the sealing performance of the structure, the outer width of the third rectangular groove is equal to the inner width of the second rectangular groove. So that the second rectangular groove can be tightly clamped at the top of the third rectangular groove.

Practice shows that the frameless photovoltaic module building integrated structure of each example is high in structural strength, good in stability and high in safety; the frameless photovoltaic module is used for directly replacing a color steel tile structure, so that the cost is reduced; the full utilization of light energy is realized, and energy is saved; the frameless photovoltaic module has a good heat insulation effect, light energy irradiated on the frameless photovoltaic module is converted into electric energy to be stored or reflected, and the comfort of the indoor environment is improved.

Claims (9)

1. The utility model provides a frameless photovoltaic module building integration support which characterized in that: comprises a transverse bracket and a longitudinal bracket;

the transverse bracket comprises a transverse sealing strip and a transverse water chute; the transverse sealing strip comprises a splicing strip, the top of the splicing strip is provided with a baffle arranged along the length direction, two sides of the baffle exceed the splicing strip, the longitudinal section of the top of the baffle is triangular, and the bottoms of the baffles on two sides of the splicing strip are in a planar structure; the transverse water chute comprises a first rectangular groove, the notch of the first rectangular groove is upwards arranged right below the splicing strip, the length direction of the first rectangular groove is consistent with that of the splicing strip, the bottom of the splicing strip extends into the first rectangular groove, the outer sides of two sides of the top of the notch of the first rectangular groove are respectively provided with a first side wing, the heights of the first side wings at two sides are equal, and the first side wings are perpendicular to the side walls of the first rectangular groove where the first side wings are arranged;

the longitudinal support comprises a longitudinal pressing block and a longitudinal water chute; the longitudinal pressing block comprises a second rectangular groove, second side wings are arranged on the outer sides of two sides of the top of a notch of the second rectangular groove, the heights of the second side wings on the two sides are equal, and the second side wings are perpendicular to the side walls of the second rectangular groove where the second side wings are located; the longitudinal water chute comprises a third rectangular groove and a fourth rectangular groove, third side wings are arranged on the outer sides of two sides of the top of a notch of the third rectangular groove, the heights of the third side wings on the two sides are equal, and the third side wings are perpendicular to the side walls of the third rectangular groove where the third side wings are located; the two fourth rectangular grooves are of the same structure, the notches of the third rectangular grooves face downwards, the notches of the two fourth rectangular grooves face upwards and are symmetrically arranged on two sides of the third rectangular grooves, the third side wing and the top of the side wall of the adjacent fourth rectangular groove are connected into a whole, a fourth side wing is arranged on the outer side of the top of one side, which is not connected with the third side wing, of the fourth rectangular groove, the fourth side wing is perpendicular to the side wall of the fourth rectangular groove where the fourth side wing is located, and the third side wing is flush with the upper surface of the fourth side wing; the second rectangular groove notch covers the top of the third rectangular groove downwards, and the top of the third rectangular groove is positioned on the inner side of the second rectangular groove.

2. The frameless photovoltaic module building integrated support of claim 1, wherein: the transverse support and the longitudinal support are arranged in a vertical cross mode, and the first rectangular groove is vertically communicated with the fourth rectangular groove at the vertical connection position of the transverse support and the longitudinal support.

3. The frameless photovoltaic module building integrated support of claim 1 or 2, wherein: one side of the first rectangular groove is higher than the other side, the side higher than the upper side of the first rectangular groove is defined as a high side, the other side is defined as a bottom side, and the heights of the upper surfaces of the side wings of the bottom side are consistent with that of the bottom side; the height of the high side wing is the same as that of the bottom side wing.

4. The frameless photovoltaic module building integrated support of claim 1 or 2, wherein: the width of the high side wing is more than twice of the width of the bottom side wing.

5. The frameless photovoltaic module building integrated support of claim 1 or 2, wherein: one end of the fourth side wing is vertically connected with the side wall of the fourth rectangular groove, and the other end of the fourth side wing is vertically bent downwards to form a supporting structure with a 7-shaped longitudinal section.

6. The frameless photovoltaic module building integrated support of claim 1 or 2, wherein: the outer width of the third rectangular groove is equal to the inner width of the second rectangular groove.

7. A frameless photovoltaic module building integration structure, comprising the frameless photovoltaic module building integration support, the frameless photovoltaic module and the purlins of any one of claims 1-6, wherein: the frameless photovoltaic assembly is positioned on the purline; the frameless photovoltaic module consists of photovoltaic cell pieces which are arranged in a grid shape; two adjacent rows of photovoltaic cell pieces are connected by a transverse support, and two adjacent rows of photovoltaic cell pieces are connected by a longitudinal support; the connection between two adjacent rows of photovoltaic cells is as follows: the splicing strips are positioned between two adjacent rows of photovoltaic cell pieces, and the side edges of the two adjacent rows of photovoltaic cell pieces are respectively clamped between the baffle on the side where the splicing strips are positioned and the first side wing; the connection between two adjacent photovoltaic cell pieces is: the second rectangular groove is positioned between two adjacent rows of photovoltaic cell pieces, the top of the second rectangular groove exceeds the photovoltaic cell pieces, and the side edges of the two adjacent rows of photovoltaic cell pieces are respectively clamped between the second side wing and the third side wing on the side where the two adjacent rows of photovoltaic cell pieces are positioned; at the vertical connection position of the transverse bracket and the longitudinal bracket, the first rectangular groove is vertically communicated with the fourth rectangular groove; the third rectangular grooves in the same row are connected and communicated, and the fourth rectangular grooves in the same row are connected and communicated.

8. The frameless photovoltaic module building integrated structure of claim 7, wherein: the fixing screw rod penetrates through the second rectangular groove and the third rectangular groove to be connected with the purline.

9. The frameless photovoltaic module building integrated structure of claim 7 or 8, wherein: a sealing gasket is arranged between the first side wing and the photovoltaic cell; a sealing gasket is arranged between the third side wing and the photovoltaic cell; and a sealing gasket is arranged between the four side wings and the photovoltaic cell.

Images