CN215907230U - BIPV photovoltaic support - Google Patents

Abstract

The utility model relates to the technical field of photovoltaics. The BIPV photovoltaic bracket comprises a transverse water tank, a longitudinal water tank, a pressing block and a supporting plate; at least two supporting plates are clamped in the length direction of the longitudinal water tank, supporting ribs which extend downwards to abut against the longitudinal water tank are arranged on the supporting plates, two limiting ribs which extend upwards are arranged at the tops of the supporting plates, and the two limiting ribs are located between every two adjacent photovoltaic modules; a limiting groove for fixing the bolt is arranged in the center of the longitudinal water tank; the pressing block and the supporting plate are provided with through holes for penetrating through bolts; the transverse water tanks are erected above the longitudinal water tanks, and gaps between adjacent transverse water tanks are positioned right above the longitudinal water tanks. A waterproof cover plate is clamped above the pressing block. Through structural design such as horizontal basin, vertical basin, waterproof apron, have excellent waterproof and thermal insulation performance, realized BIPV photovoltaic and building integration, can install on the roof that has various steel tile, still can replace various steel tile to use as the roof.

Description

BIPV photovoltaic support

Technical Field

The utility model relates to the technical field of photovoltaics, in particular to a BIPV photovoltaic support.

Background

BIPV, Building Integrated PV, is a Building Integrated photovoltaic. PV, i.e. Photovaltaic. BIPV technology is a technology that integrates solar power (photovoltaic) products into buildings.

In order to facilitate drainage, the conventional BIPV photovoltaic support effectively drains water infiltrated into the transverse gap of the solar photovoltaic panel into the longitudinal water channel through the arrangement of the transverse water channel, and then effectively drains the water drained from the transverse water channel and the water infiltrated into the longitudinal gap of the solar photovoltaic panel through the longitudinal water channel. Such as a building integrated photovoltaic mounting system disclosed in publication number CN 111371385A. The structure of the photovoltaic bracket has the defects that 1) the longitudinal water tank is fixed in a clamping mode, and the operation is inconvenient. 2) The longitudinal water tank is bent in a W shape, is easy to deform after being used for a long time, and is not easy to ensure the bearing effect.

SUMMERY OF THE UTILITY MODEL

Aiming at the problems in the prior art, the utility model provides a BIPV photovoltaic bracket to solve the technical problem that the existing photovoltaic bracket is poor in installation strength.

In order to achieve the purpose, the utility model provides a BIPV photovoltaic bracket, which comprises a transverse water tank, a longitudinal water tank and a pressing block positioned between two adjacent photovoltaic modules, and is characterized by also comprising a supporting plate;

at least two supporting plates are clamped in the length direction of the longitudinal water tank, supporting ribs which extend downwards to abut against the longitudinal water tank are arranged on the supporting plates, two limiting ribs which extend upwards are arranged at the tops of the supporting plates, and the two limiting ribs are located between every two adjacent photovoltaic modules;

a limiting groove for fixing a bolt is arranged in the center of the longitudinal water tank;

the pressing block and the supporting plate are provided with through holes for penetrating through the bolts;

the transverse water tanks are arranged above the longitudinal water tanks, and gaps between adjacent transverse water tanks are positioned right above the longitudinal water tanks.

This patent is through optimizing BIPV photovoltaic support's structure, through the layer board, has realized the support intensity to photovoltaic module. The longitudinal water tank and the pressing block are relatively fixed through bolts. The whole installation and fixation are convenient, and the operation is simple.

Preferably, the support rib comprises a vertical plate and a horizontal plate, and the vertical plate and the horizontal plate are fixedly connected to form an inverted T-shaped support rib;

the transverse plate is abutted against the longitudinal water tank.

Further preferably, the top surface of the supporting plate is provided with a tooth-shaped protrusion. The length direction of the dentate projections is parallel to the length direction of the longitudinal support bars. The dentations are formed by strip-shaped grooves arranged along the length direction of the transverse supporting bar. The section of the strip-shaped groove is V-shaped.

Further preferably, the longitudinal water tank comprises a bottom plate, and two oppositely arranged supporting plates are fixed on the bottom plate;

the limiting groove is positioned between the two supporting plates;

the bottom plate is located the outside of two backup pads and has seted up the mounting hole.

Through the structural optimization of vertical basin, be convenient for fixed, and guarantee intensity.

Preferably, the adjacent sides of the two support plates are provided with protrusions for clamping the push plate;

and clamping grooves for clamping the protrusions are formed in the opposite sides of the supporting plate.

The clamping connection between the supporting plate and the supporting plate is convenient to realize.

Preferably, the pressing block comprises a U-shaped bent middle part, and a through hole for a bolt to pass through is formed in the middle part;

the pressing block further comprises an extension pressing edge positioned on the outer side, and the extension pressing edge is used for being buckled and pressed on two adjacent photovoltaic modules;

the top joint of briquetting has a waterproof apron, waterproof apron cover is established the periphery of briquetting.

Further preferably, the transverse water tank comprises a U-shaped tank body, and the top of the U-shaped tank body is provided with a right-angle flange bent towards the same side.

The limiting of the roof ridge fixed cover is realized through the right-angle flanging conveniently.

Further preferably, the photovoltaic module comprises a front photovoltaic group positioned at the front side of the roof of the house and a rear photovoltaic group positioned at the rear side of the roof of the house;

the front photovoltaic group is obliquely laid downwards from back to front;

the rear photovoltaic group is obliquely laid downwards from front to rear;

a ridge top cover is clamped between the rear side of the front photovoltaic group and the front side of the rear photovoltaic group, and sealing parts are arranged between the ridge top cover and the rear side of the front photovoltaic group as well as the front side of the rear photovoltaic group;

the front end and the rear end of the roof ridge top cover are limited and supported by a transverse water tank;

the direction of the right-angle flanging of the transverse water tank supporting the front end of the roof ridge top cover faces forwards, and the direction of the flanging of the transverse water tank supporting the rear end of the roof ridge top cover faces backwards;

and the front end and the rear end of the roof ridge top cover are provided with limiting flanges.

The relative limit of the transverse water channel and the roof top cover is convenient to realize.

Further preferably, roof top cap includes the bending part that front and back mirror symmetry set up, the bending part is from last to down in proper order for the first kink that the slope that connects set up, the second kink of vertical setting, the third kink of 90 bendings to the inboard, the fourth kink of 90 bendings upwards.

The relative limit of the bent part and the flanging of the transverse water tank is convenient to realize.

Further preferably, a sealing strip for sealing a longitudinal gap between adjacent photovoltaic modules is installed right above the transverse water channel, and the length direction of the sealing strip is parallel to the length direction of the transverse water channel.

The sealing strip comprises a main strip body which is vertically arranged;

the two sides of the bottom of the main strip body are connected with extending strips which extend upwards in an inclined mode;

the two sides of the top of the main strip body are both connected with arc-shaped sealing strips, and two ends of each arc-shaped sealing strip are connected with the main strip body to form a hole in an enclosing mode.

This patent is through the structure of optimizing the sealing strip, has realized multiple sealed step by step. The collection of infiltration can also be realized through the extension strip when being convenient for realize the clearance of the vertical insertion between the photovoltaic module of sealing strip. Through the design of the arc-shaped sealing strip, double-stage sealing can be realized.

Further preferably, the sealing strip is an ethylene propylene diene monomer rubber strip.

Further preferably, the photovoltaic module comprises a frame and a photovoltaic panel, and the U-shaped groove body of the transverse water tank is sleeved on the outer side of the adjacent side of the frame of the adjacent photovoltaic module.

The collection and the discharge of infiltration between the photovoltaic module are convenient to realize.

Preferably, the longitudinal water tank is connected with the roof purline through self-tapping screws;

and a shockproof gasket is arranged between the longitudinal water tank and the roof purline.

The shockproof gasket is made of ethylene propylene diene monomer.

Or the longitudinal water tank is connected with the first section bar through a tapping screw, and a shockproof gasket is arranged between the longitudinal water tank and the first section bar;

the first section bars and the second section bars are arranged in a criss-cross mode and connected through bolts;

the second section bar passes through the color steel tile and the roof purline which are arranged up and down through self-tapping screws.

Drawings

FIG. 1 is a cross-sectional view of a longitudinal water tank in accordance with an embodiment 1 of the present invention;

FIG. 2 is a schematic structural view of a ridge cap according to embodiment 1 of the present invention;

FIG. 3 is a schematic structural view of a cross-section of a transverse trough in accordance with embodiment 1 of the present invention;

FIG. 4 is a sectional view of a weather strip according to embodiment 1 of the present invention;

fig. 5 is another schematic structural view of a cross section of a longitudinal water tank according to embodiment 1 of the present invention.

Wherein: 1 is the briquetting, 2 is waterproof apron, 3 is photovoltaic module, 4 is horizontal basin, 5 is the layer board, 6 is vertical basin, 7 is the bolt, 8 is first section bar, 9 is the second section bar, 10 is various steel tile, 11 is the roofing purlin, 12 is the sealing strip, 13 is the roof top cap, 14 is shockproof gasket, 15 is the footboard.

Detailed Description

The utility model is further described below with reference to the accompanying drawings.

Referring to fig. 1 to 5, embodiment 1: the BIPV photovoltaic bracket comprises a transverse water tank 4, a longitudinal water tank 6, a pressing block 1 and a supporting plate 5, wherein the pressing block 1 is used for being positioned in a transverse gap between two adjacent photovoltaic modules 3; at least two supporting plates 5 are clamped in the length direction of the longitudinal water tank 6, and supporting ribs which extend downwards and abut against the longitudinal water tank 6 are arranged on the supporting plates 5; the top of the supporting plate is provided with two limiting ribs extending upwards, and the two limiting ribs are positioned between two adjacent photovoltaic modules; a limiting groove for fixing the bolt 7 is arranged in the center of the longitudinal water tank 6; the pressing block 1 and the supporting plate 5 are provided with through holes for penetrating through the bolts 7; the transverse water tanks 4 are erected above the longitudinal water tanks 6, and gaps between adjacent transverse water tanks 4 are located right above the longitudinal water tanks 6. This patent is through optimizing BIPV photovoltaic support's structure, through layer board 5, has realized the support intensity to photovoltaic module. The longitudinal water tank 6 and the pressing block 1 are fixed relatively through bolts. The whole installation and fixation are convenient, and the operation is simple. Transverse is the length direction of the transverse water tank. For example, the longitudinal direction of the horizontal water tank is the left-right direction. The longitudinal water tank has a longitudinal direction in the front-rear direction.

The connection between the outermost photovoltaic module and the tread 15 is, for example, a connection between the longitudinal directions of the adjacent photovoltaic modules. And a pressing block, a supporting plate and a longitudinal water tank are sequentially arranged between the photovoltaic module at the edge and the pedal 15 from top to bottom. And a transverse water tank is arranged between the adjacent longitudinally arranged pedals.

The top surface of the supporting plate is provided with dentations. Increasing the roughness. The length direction of the dentate projections is parallel to the length direction of the longitudinal support bars. The dentations are formed by strip-shaped grooves arranged along the length direction of the transverse supporting bar. The section of the strip-shaped groove is V-shaped. The strip-shaped grooves comprise first strip-shaped grooves and second strip-shaped grooves, and the first strip-shaped grooves are larger than the sections of the second strip-shaped grooves. At least one first strip-shaped groove is arranged among the at least five second strip-shaped grooves. The support rib comprises a vertical plate and a horizontal plate, wherein the vertical plate and the horizontal plate are vertically arranged, and the vertical plate and the horizontal plate are fixedly connected to form an inverted T-shaped support rib; the transverse plate is abutted against the longitudinal water tank 6. The layer board includes the roof, and the thickness of roof thickness is greater than the thickness of brace rod, and the thickness of brace rod is greater than the thickness of spacing muscle. The thickness of the top plate is preferably 4 mm. The thickness of the support ribs is preferably 2.5 mm. The thickness of spacing muscle is preferably 2 mm. Two support ribs are preferably provided. The two supporting ribs are arranged in a mirror symmetry mode.

The longitudinal water tank 6 comprises a bottom plate, and two oppositely arranged supporting plates are fixed on the bottom plate; the limiting groove is positioned between the two supporting plates; the bottom plate is located the outside of two backup pads and has seted up the mounting hole. Through the structural optimization of the longitudinal water tank 6, the fixing is convenient, and the strength is ensured. The limiting groove can be a T-shaped groove. And a T-shaped nut matched with the T-shaped groove is arranged in the limiting groove. The T-shaped nut is detachably connected with the bolt. Or, the limiting groove internal rotation joint has the bolt, and the pole portion of bolt passes push pedal and briquetting 1 in proper order to screw up through the nut. The adjacent sides of the two supporting plates are provided with protrusions for clamping the push plate; the opposite side of the supporting plate 5 is provided with a clamping groove for clamping the protrusion. The clamping connection between the supporting plate and the supporting plate 5 is convenient to realize.

The pressing block 1 comprises a U-shaped bent middle part, and a through hole for a bolt to pass through is formed in the middle part; the pressing block 1 further comprises an extension pressing edge positioned on the outer side, and the extension pressing edge is used for being buckled and pressed on two adjacent photovoltaic assemblies; the upper joint of briquetting 1 has a waterproof apron 2, and waterproof apron 2 covers the periphery of establishing at briquetting 1.

Referring to fig. 3, the transverse water tank 4 includes a U-shaped tank body, and the top of the U-shaped tank body is provided with a right-angle flange bent to the same side. The limiting of the roof ridge fixed cover is realized through the right-angle flanging conveniently. On the cross section of horizontal basin, the length of right angle turn-ups is 10 mm. The height of the U-shaped groove is 25 mm. The width of the U-shaped groove is 80 mm. The wall thickness of the transverse water tank is 1 mm. The photovoltaic modules comprise frames and photovoltaic panels, and the U-shaped groove bodies of the transverse water grooves are sleeved on the outer sides of the adjacent sides of the frames of the adjacent photovoltaic modules. The collection and the discharge of infiltration between the photovoltaic module are convenient to realize.

Referring to fig. 2, the photovoltaic module includes a front photovoltaic group located at the front side of the roof of the house and a rear photovoltaic group located at the rear side of the roof of the house; the front photovoltaic group is laid downwards from back to front inclined; the rear photovoltaic group is obliquely laid downwards from front to rear; a ridge top cover 13 is clamped between the rear side of the front photovoltaic group and the front side of the rear photovoltaic group, and sealing parts are arranged between the ridge top cover 13 and the rear side of the front photovoltaic group as well as the front side of the rear photovoltaic group; the front end and the rear end of the roof top cover 13 are limited and supported by a transverse water tank; the direction of the right-angle flanging of the transverse water tank at the front end of the supporting ridge top cover 13 faces forwards, and the direction of the flanging of the transverse water tank at the rear end of the supporting ridge top cover 13 faces backwards; the front end and the rear end of the ridge top cover 13 are provided with limiting flanges. The relative limit of the transverse water channel and the roof top cover is convenient to realize. Roof top cap 13 includes the bending part that mirror symmetry set up around, and the bending part is from last to the first kink that is the slope setting of connecting gradually down, the second kink of vertical setting, the third kink of 90 bendings to inside side, the fourth kink of 90 bendings upwards. The relative limit of the bent part and the flanging of the transverse water tank is convenient to realize. The included angle of the first bending part of the two bending parts is 150-160 degrees. On the cross section of roof ridge top cap, the length of first kink is 140mm, and the length of second kink is 35mm, and the length of third kink is 35mm, and the length of fourth kink is 13 mm.

Referring to fig. 3 and 4, a sealing strip 12 for sealing a longitudinal gap between adjacent photovoltaic modules is installed right above the transverse water channel 4, and the length direction of the sealing strip 12 is parallel to the length direction of the transverse water channel. The sealing tape 12 includes a vertically arranged main tape body; the two sides of the bottom of the main strip body are connected with extending strips which extend upwards in an inclined mode; the two sides of the top of the main strip body are both connected with arc-shaped sealing strips, and the two ends of each arc-shaped sealing strip are connected with the main strip body to form a hole in an enclosing mode. This patent is through the structure of optimizing the sealing strip, has realized multiple sealed step by step. The collection of infiltration can also be realized through the extension strip when being convenient for realize the clearance of the vertical insertion between the photovoltaic module of sealing strip. Through the design of the arc-shaped sealing strip, double-stage sealing can be realized. The sealing strip is an ethylene propylene diene monomer rubber strip.

The two sides of the main strip body in the thickness direction are connected with extension strips and arc-shaped sealing strips. And the photovoltaic module is contacted by the extension strip and the arc-shaped sealing strip.

Referring to fig. 5, the longitudinal water tank 6 is connected with the roof purline 11 through self-tapping screws; and a shockproof gasket is arranged between the longitudinal water tank 6 and the roof purline 11. The shockproof gasket is made of ethylene propylene diene monomer. The photovoltaic can be used as a roof, and the BIPV is integrated with a building.

Alternatively, referring to fig. 1, the longitudinal water channel 6 is connected to the first profile 8 by self-tapping screws. And a shockproof gasket 14 is arranged between the longitudinal water tank 6 and the first section bar 8. The shockproof gasket is made of ethylene propylene diene monomer. First section bar 8 sets up with second section bar 9 vertically and horizontally staggered, and links to each other through the bolt, and the various steel tile 10 and the roofing purlin 11 that set up about the self-tapping screw passed through to the second section bar. The second section bar is positioned below the first section bar. The first profile 8 is a rectangular hollow tube. Such as rectangular steel tubing. The second section bar 9 is galvanized C-shaped steel 41 x 21 x 2.0. The length direction of the first section bar is parallel to the length direction of the transverse water tank. The opening of the second section bar 9 is upward, and a plastic wing nut connected with the bolt thread is installed in the second section bar 9.

Has the advantages that:

the longitudinal water tank is used as a main supporting beam of the whole system and has the functions of collecting rainwater, guiding the rainwater into a ditch and discharging the rainwater; a transverse water tank is arranged between every two adjacent photovoltaic modules, and has the functions of collecting rainwater and guiding the rainwater into the longitudinal main beam to be discharged together. The photovoltaic modules are transversely arranged and erected above the adjacent longitudinal water channels and are fixed by bolts and pressing blocks. A waterproof cover plate is arranged above the longitudinal water tank to reduce the inflow of rainwater and dust, and the blockage in the longitudinal main beam is avoided. And a sealing strip is arranged above the transverse water tank.

The whole device has compact structure, convenient installation and strong stability.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that it is obvious to those skilled in the art that various modifications and improvements can be made without departing from the principle of the present invention, and these modifications and improvements should also be considered as the protection scope of the present invention.

Claims (10)

1. The BIPV photovoltaic bracket comprises a transverse water tank, a longitudinal water tank and a pressing block which is used for being positioned in a transverse gap between two adjacent photovoltaic modules, and is characterized by further comprising a supporting plate;

   at least two supporting plates are clamped in the length direction of the longitudinal water tank, and supporting ribs which extend downwards to abut against the longitudinal water tank are arranged on the supporting plates; the top of the supporting plate is provided with two limiting ribs extending upwards, and the two limiting ribs are positioned between two adjacent photovoltaic modules;

   a limiting groove for fixing a bolt is arranged in the center of the longitudinal water tank;

   the pressing block and the supporting plate are provided with through holes for penetrating through the bolts;

   the transverse water tanks are arranged above the longitudinal water tanks, and gaps between adjacent transverse water tanks are positioned right above the longitudinal water tanks.
2. 2. The BIPV photovoltaic scaffold of claim 1, wherein: the supporting ribs comprise vertical plates and horizontal plates, and the vertical plates and the horizontal plates are fixedly connected to form inverted T-shaped supporting ribs;

   the transverse plate is abutted against the longitudinal water tank.
3. 3. The BIPV photovoltaic scaffold of claim 1, wherein: the longitudinal water tank comprises a bottom plate, and two oppositely arranged supporting plates are fixed on the bottom plate;

   the limiting groove is positioned between the two supporting plates;

   the bottom plate is located the outside of two backup pads and has seted up the mounting hole.
4. 4. The BIPV photovoltaic scaffold of claim 1, wherein: the pressing block comprises a U-shaped bent middle part, and a through hole for a bolt to pass through is formed in the middle part;

   the pressing block further comprises an extension pressing edge positioned on the outer side, and the extension pressing edge is used for being buckled and pressed on two adjacent photovoltaic modules;

   the top joint of briquetting has a waterproof apron, waterproof apron cover is established the periphery of briquetting.
5. 5. The BIPV photovoltaic scaffold of claim 1, wherein: the transverse water tank comprises a U-shaped tank body, and the top of the U-shaped tank body is provided with a right-angle flange bent towards the same side.
6. 6. The BIPV photovoltaic support of claim 5, wherein: the photovoltaic assembly comprises a front photovoltaic group positioned on the front side of the top of the house and a rear photovoltaic group positioned on the rear side of the top of the house;

   the front photovoltaic group is obliquely laid downwards from back to front;

   the rear photovoltaic group is obliquely laid downwards from front to rear;

   a ridge top cover is clamped between the rear side of the front photovoltaic group and the front side of the rear photovoltaic group, and sealing parts are arranged between the ridge top cover and the rear side of the front photovoltaic group as well as the front side of the rear photovoltaic group;

   the front end and the rear end of the roof ridge top cover are limited and supported by a transverse water tank;

   the direction of the right-angle flanging of the transverse water tank supporting the front end of the roof ridge top cover faces forwards, and the direction of the flanging of the transverse water tank supporting the rear end of the roof ridge top cover faces backwards;

   and the front end and the rear end of the roof ridge top cover are provided with limiting flanges.
7. 7. The BIPV photovoltaic support of claim 6, wherein: roof top cap includes the bending part that front and back mirror symmetry set up, bending part is from last to the first kink that is the slope setting of connecting in proper order down, the second kink of vertical setting, the third kink of 90 bendings to inside side, the fourth kink of 90 bendings upwards.
8. 8. The BIPV photovoltaic scaffold of claim 1, wherein: a sealing strip for sealing a longitudinal gap between adjacent photovoltaic modules is arranged right above the transverse water tank, and the length direction of the sealing strip is parallel to the length direction of the transverse water tank;

   the sealing strip comprises a main strip body which is vertically arranged;

   the two sides of the bottom of the main strip body are connected with extending strips which extend upwards in an inclined mode;

   the two sides of the top of the main strip body are both connected with arc-shaped sealing strips, and two ends of each arc-shaped sealing strip are connected with the main strip body to form a hole in an enclosing mode.
9. 9. The BIPV photovoltaic scaffold of claim 1, wherein: the longitudinal water tank is connected with the roof purline through self-tapping screws;

   and a shockproof gasket is arranged between the longitudinal water tank and the roof purline.
10. 10. The BIPV photovoltaic scaffold of claim 1, wherein: the longitudinal water tank is connected with the first section bar through a self-tapping screw, and a shockproof gasket is arranged between the longitudinal water tank and the first section bar;

    the first section bars and the second section bars are arranged in a criss-cross mode and connected through bolts;

    the second section bar passes through the color steel tile and the roof purline which are arranged up and down through self-tapping screws.

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