CN209817299U - Solar photovoltaic power generation shed - Google Patents

Abstract

The utility model discloses a solar photovoltaic power generation shed, including the stand, locate the girder on the stand, locate secondary joist, V type basin, U type basin on the girder and a plurality of photovoltaic board laid on the secondary joist, along the secondary joist direction, form first clearance between the adjacent photovoltaic board, along the girder direction, form the second clearance between the adjacent photovoltaic board, V type basin sets up in the below of first clearance, and the infiltration of first clearance gets into V type basin, U type basin sets up in the below of second clearance, and the infiltration of second clearance gets into U type basin; the V-shaped water tank is characterized in that the edges of two sides of the V-shaped water tank are outwards provided with a first extension plate and a second extension plate, the first extension plate is hung on the secondary keel, and the U-shaped water tank is erected on the adjacent second extension plates. This application is through the setting of moving about freely and quickly of V type basin and U type basin, can effectively receive the infiltration in photovoltaic board clearance to will seep water and discharge away from the edge of electricity generation canopy.

Description

Solar photovoltaic power generation shed

Technical Field

The utility model relates to a photovoltaic power generation technical field especially relates to a solar photovoltaic power generation canopy.

Background

With the advocation of green energy, solar power generation is gradually popularized. The solar photovoltaic power generation shed is an important facility in a solar photovoltaic power generation system.

In order to effectively utilize available space to carry out photovoltaic power generation, some bus stations, bicycle sheds or park corridors all adopt solar photovoltaic power generation sheds, when keeping out the sun and rain for people, can also have and generate electricity. However, when the existing solar photovoltaic power generation shed is raining, rainwater can accumulate in gaps between the photovoltaic plate and the main beams of the fixing plates and permeate, and the water dripping phenomenon is caused.

Disclosure of Invention

The utility model aims to solve the technical problem that a solar photovoltaic power generation canopy is provided, can carry out effective water conservancy diversion to the rainwater, avoid the rainwater to accumulate at the canopy top, prevent the rainwater seepage.

The utility model discloses the technical problem who still remains to solve lies in, provides a solar photovoltaic power generation canopy, the inclination of adjustable girder.

In order to solve the technical problem, the utility model provides a solar photovoltaic power generation shed, which comprises a stand column, a main beam arranged on the stand column, a secondary keel arranged on the main beam, a V-shaped water tank, a U-shaped water tank and a plurality of photovoltaic plates paved on the secondary keel, wherein a first gap is formed between the adjacent photovoltaic plates along the direction of the secondary keel, a second gap is formed between the adjacent photovoltaic plates along the direction of the main beam, the V-shaped water tank is arranged below the first gap, the seepage water of the first gap enters the V-shaped water tank, the U-shaped water tank is arranged below the second gap, and the seepage water of the second gap enters the U-shaped water tank; the V-shaped water tank is characterized in that the edges of two sides of the V-shaped water tank are outwards provided with a first extension plate and a second extension plate, the first extension plate is hung on the secondary keel, and the U-shaped water tank is erected on the adjacent second extension plates.

As the improvement of above-mentioned scheme, the surface of secondary joist is equipped with first mounting groove along its length direction, the secondary joist top is located first mounting groove both sides and is equipped with the pterygoid lamina, the photovoltaic grillage is established go up the pterygoid lamina is last, the opening in V type basin is located the below of last pterygoid lamina.

As an improvement of the scheme, the photovoltaic panel is fixed on the secondary keel through the mounting fixture, the mounting fixture comprises an upper pressing piece used for pressing the photovoltaic panel, a lower clamping block clamped in the first mounting groove and a bolt for connecting the upper pressing piece and the lower clamping block, two clamping pieces are respectively arranged on two sides of the upper pressing piece, and the photovoltaic panel is fixed between the clamping pieces and the upper wing plate.

As the improvement of above-mentioned scheme, the bottom of secondary joist is equipped with down the pterygoid lamina along its length direction, the surface of girder is equipped with the second mounting groove along its length direction, and first briquetting compresses tightly on the pterygoid lamina down, first briquetting passes through first connecting piece sliding connection in the second mounting groove to make the secondary joist fix on the girder.

As an improvement of the scheme, the second mounting groove is a T-shaped clamping groove, the first connecting piece is a bolt, and the screw head of the bolt is clamped in the second mounting groove.

As an improvement of the scheme, the U-shaped water tank is provided with at least two ribs, and the U-shaped water tank is divided into at least three drainage grooves by the ribs.

As an improvement of the above scheme, the main beam is connected to the stand through a main beam connecting piece, the main beam connecting piece is provided with a clamping groove and a third mounting groove below the clamping groove, the main beam is clamped in the clamping groove, and the top of the stand is inserted into the third mounting groove.

As an improvement of the scheme, the main beam is provided with a rounded corner, and the shape of the clamping groove is matched with that of the main beam, so that the main beam can rotate in the clamping groove.

As an improvement of the scheme, a cross brace is connected between the connected upright posts and is fixed on the upright posts through a cross brace connecting plate.

As an improvement of the scheme, the upright post is also connected with at least one inclined strut, one end of the inclined strut is connected to the upright post through an inclined strut connecting piece, the other end of the inclined strut is supported on the ground, and the inclined strut and the upright post form a triangle.

Implement the utility model discloses, following beneficial effect has:

the utility model provides a solar photovoltaic power generation shed, which comprises a stand column, a main beam arranged on the stand column, a secondary keel arranged on the main beam, a V-shaped water tank, a U-shaped water tank and a plurality of photovoltaic plates paved on the secondary keel, wherein a first gap is formed between the adjacent photovoltaic plates along the direction of the secondary keel, and a second gap is formed between the adjacent photovoltaic plates along the direction of the main beam; wherein,

the V-shaped water tank is arranged below the first gap, the water seepage of the first gap enters the V-shaped water tank, the U-shaped water tank is arranged below the second gap, and the water seepage of the second gap enters the U-shaped water tank. This application is through the setting of moving about freely and quickly of V type basin and U type basin, can effectively receive the infiltration in photovoltaic board clearance to will seep water and discharge away from the edge of electricity generation canopy.

The edge of V type basin both sides outwards is equipped with first extension board and second extension board, first extension board articulates on the secondary joist, U type basin erects on adjacent second extension board. This application has realized the erection joint of V type basin and U type basin through the structure design to the V type basin.

The girder passes through girder connection spare and connects on the stand, girder connection spare is equipped with draw-in groove and the third mounting groove that is located the draw-in groove below, the girder joint is in the draw-in groove, the top of stand inserts in the third mounting groove. Wherein, the girder is equipped with the radius angle to make the girder can be at the draw-in groove internal rotation to can adjust the inclination of girder, and then increase the area of contact of secondary joist and girder. Specifically, the angle that the girder 2 can incline is 0-10 degrees, can satisfy the needs of electricity generation canopy in different areas.

Drawings

Fig. 1 is a perspective view of the solar photovoltaic power generation shed of the present invention;

FIG. 2 is a schematic view of the cross brace of the present invention mounted on the vertical column;

FIG. 3 is a schematic view of the diagonal brace of the present invention mounted on a vertical post;

FIG. 4 is a schematic view of the main beam of the present invention mounted on the column;

fig. 5 is a perspective view of the main beam connector of the present invention;

figure 6 is a schematic view of the installation jig of the present invention installed on a cross runner;

figure 7 is a schematic view of the secondary joist of the present invention mounted on the main beam;

fig. 8 is a schematic view of the V-shaped water tank of the present invention mounted on the secondary joist;

fig. 9 is a schematic view of the V-shaped water tank of the U-shaped water tank installation layer of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, the utility model provides a pair of solar photovoltaic power generation canopy, including stand 1, locate girder 2 on the stand 1, locate the secondary joist 3 on girder 2, connect V type basin 4, U type basin 5 on the 3 lateral walls of secondary joist and a plurality of lay the photovoltaic board 6 on secondary joist 3.

In order to enhance the overall strength of the power generation shed, cross braces 101 are connected between the connected upright posts 1, and the cross braces 101 are fixed on the upright posts 1 through cross brace connecting plates 102. Further, the upright post 1 is also connected with at least one inclined strut 201, one end of the inclined strut 201 is connected to the upright post 1 through an inclined strut connecting piece 202, the other end of the inclined strut 201 is supported on the ground, and the inclined strut 201 and the upright post 1 form a triangle.

Specifically, referring to fig. 2 and 3, a self-tapping screw passes through the wale connecting plate 102 and the column 1 to fix the wale connecting plate 102 to the column 1, and further, passes through the wale connecting plate 102 and the wale 101 to fix the wale 101 to the column 1. The self-tapping screw passes through the sprag connection member 202 and the column 1 to fix the sprag connection member 202 to the column 1, and further, the self-tapping screw passes through the sprag connection member 202 and the sprag 201 to fix the sprag 201 to the column 1.

The photovoltaic power generation mainly depends on solar energy, namely irradiation of sunlight. Since the sun has a law of east rising west falling, in order to utilize the irradiation of sunlight as much as possible, the installation angle of the photovoltaic panel needs to be adjusted. Referring to fig. 4 and 5, the main beam 2 is connected to the column 1 by a main beam connection 301. Specifically, girder connection spare 301 is equipped with draw-in groove 3011 and the third mounting groove 3012 that is located draw-in groove 3011 below, girder 2 joint is in draw-in groove 3011, the top of stand 1 inserts in the third mounting groove 3012, wherein, the bolt passes second draw-in groove 3012 and stand 1 to fix girder connection spare 301 on stand 1. It should be noted that the utility model discloses a girder 2 is equipped with the fillet, draw-in groove 3011's shape with girder 2's shape matches, so that girder 2 can be at draw-in groove 3011 internal rotation to can adjust girder 2's inclination, and then increase the area of contact of secondary joist 3 and girder 2. Specifically, the angle that the girder 2 can incline is 0-10 degrees, can satisfy the needs of electricity generation canopy in different areas.

In order to increase the sunlight receiving area of the photovoltaic panel 6, the photovoltaic panel 6 is generally arranged obliquely and has a certain inclination angle, so the cross runners 3 need to be arranged on the main beams 2 obliquely, and since the surfaces of the main beams 2 and the bottom surfaces of the cross runners 3 are both flat, the contact area between the main beams 2 and the cross runners 3 needs to be increased in order to bear the weight of the photovoltaic panel 6.

Referring to fig. 6, a first installation groove 31 is formed in the surface of the secondary joist 3 along the length direction thereof, upper wing plates 32 are arranged on the top of the secondary joist 3 at both sides of the first installation groove 31, and the photovoltaic panel 6 is erected on the upper wing plates 32. Preferably, the upper surface of the upper wing plate 32 is provided with anti-slip lines, so that the friction force between the upper wing plate and the photovoltaic panel can be increased, and the photovoltaic panel is prevented from sliding.

Specifically, photovoltaic board 6 is fixed on keel 3 through sectional fixture 401, sectional fixture 401 is including the last casting die 4011 that is used for compressing tightly photovoltaic board 6, and the lower fixture block 4012 of joint in first mounting groove 31 connects the bolt 4013 of casting die 4011 and lower fixture block 4012, go up casting die 4011 both sides and respectively be equipped with a clamping piece 4014, and photovoltaic board 6 is fixed between clamping piece 4014 and last aerofoil 32. Wherein, the lower fixture block 4012 can slide in the first installation groove 31.

Referring to fig. 7, a second installation groove 21 is formed in the surface of the main beam 2 along the length direction thereof, and the cross runner 3 is fixed to the main beam 2 by a first pressing block 501. Specifically, the bottom of the secondary joist 3 is provided with a lower wing plate 33 along the length direction thereof, the first pressing block 501 is pressed on the lower wing plate 33, and the first pressing block 501 is slidably connected in the second mounting groove 21 through the first connecting member 502, so that the secondary joist 3 can move along the second mounting groove 21. It should be noted that the second mounting groove 21 is a T-shaped slot, the first connecting member 502 is a bolt, a screw head of the bolt is clamped in the second mounting groove 21, and the bolt can be fixed at any position of the second slot, so that the distance between the secondary keels can be freely adjusted as required, thereby improving the applicability. Preferably, the upper surface of the lower wing plate 32 and the lower surface of the first pressing block 501 are both provided with anti-slip lines, so that the friction force between the lower wing plate and the first pressing block can be increased, and the secondary keel is prevented from sliding.

Referring to fig. 1, 8 and 9, a first gap 61 is formed between adjacent photovoltaic panels 6 along the direction of the secondary joist 3, a second gap 62 is formed between adjacent photovoltaic panels 6 along the direction of the primary joist 2, the V-shaped water tank 4 is located below the first gap 61, and water seepage from the first gap 61 enters the V-shaped water tank 4; the U-shaped water tank 5 is positioned below the second gap 62, and the seepage water of the second gap 62 enters the U-shaped water tank 5. This application is through the setting of moving about freely and quickly of V type basin and U type basin, can effectively receive the infiltration in photovoltaic board clearance to will seep water and discharge away from the edge of electricity generation canopy. Preferably, the opening of the V-shaped water tank 4 is located below the upper wing plate 32. Since the first installation groove 31 is located between the first gaps 61 of the photovoltaic panel 6, the water permeating through the first gaps may enter the V-shaped water tank 4 along the upper wing plate 33.

Specifically, the edges of the two sides of the V-shaped water tank 4 are outwardly provided with a first extending plate 41 and a second extending plate 42, the first extending plate 41 extends to the side wall of the first installation groove 31 of the secondary keel, and the self-tapping screw penetrates through the V-shaped water tank and the secondary keel 3 to fix the V-shaped water tank 4 on the secondary keel 3. The U-shaped water tank 5 is erected on the adjacent second extension plate 42, wherein the self-tapping screw penetrates through the U-shaped water tank 5 and the second extension plate 42 to fix the U-shaped water tank 5 on the V-shaped water tank 4.

Preferably, the U-shaped water tank 5 is provided with at least two ribs 51, and the ribs 51 divide the U-shaped water tank 5 into at least three drainage grooves 52. Because U type basin 5 is located between second clearance 62, photovoltaic board 6 has the stranded rivers to get into U type basin 5, and in order to avoid the stranded rivers to get into simultaneously and take place to spill over, this application divides into many water drainage tank 52 with U type basin 5 to the infiltration is discharged better.

The above disclosure is only a preferred embodiment of the present invention, and certainly should not be taken as limiting the scope of the invention, which is defined by the claims and their equivalents.

Claims (10)

1. The solar photovoltaic power generation shed is characterized by comprising a stand column, a main beam arranged on the stand column, a secondary keel arranged on the main beam, a V-shaped water tank, a U-shaped water tank and a plurality of photovoltaic plates paved on the secondary keel, wherein a first gap is formed between every two adjacent photovoltaic plates along the direction of the secondary keel, a second gap is formed between every two adjacent photovoltaic plates along the direction of the main beam, the V-shaped water tank is arranged below the first gap, the water seepage of the first gap enters the V-shaped water tank, the U-shaped water tank is arranged below the second gap, and the water seepage of the second gap enters the U-shaped water tank; the V-shaped water tank is characterized in that the edges of two sides of the V-shaped water tank are outwards provided with a first extension plate and a second extension plate, the first extension plate is hung on the secondary keel, and the U-shaped water tank is erected on the adjacent second extension plates.

2. The solar photovoltaic power generation shed as claimed in claim 1, wherein the surface of the secondary keel is provided with a first installation groove along the length direction thereof, the top of the secondary keel is provided with upper wing plates at two sides of the first installation groove, the photovoltaic panel is erected on the upper wing plates, and the opening of the V-shaped water tank is positioned below the upper wing plates.

3. The solar photovoltaic power generation shed as claimed in claim 2, wherein the photovoltaic panel is fixed on the secondary keel by a mounting fixture, the mounting fixture comprises an upper pressing member for pressing the photovoltaic panel, a lower clamping block clamped in the first mounting groove, and a bolt for connecting the upper pressing member and the lower clamping block, two clamping pieces are respectively arranged on two sides of the upper pressing member, and the photovoltaic panel is fixed between the clamping pieces and the upper wing plate.

4. The solar photovoltaic power generation shed as claimed in claim 2, wherein the bottom of the secondary joist is provided with a lower wing plate along the length direction thereof, the surface of the main beam is provided with a second installation groove along the length direction thereof, the first pressing block is pressed against the lower wing plate, and the first pressing block is slidably connected in the second installation groove through a first connecting member so that the secondary joist is fixed on the main beam.

5. The solar photovoltaic power generation shed as claimed in claim 4, wherein the second mounting groove is a T-shaped clamping groove, the first connecting piece is a bolt, and a screw head of the bolt is clamped in the second mounting groove.

6. The solar photovoltaic power generation shed as claimed in claim 1, wherein the U-shaped water trough is provided with at least two ribs, and the ribs divide the U-shaped water trough into at least three drainage troughs.

7. The solar photovoltaic power generation shed as claimed in claim 1, wherein the main beam is connected to the vertical column through a main beam connecting piece, the main beam connecting piece is provided with a clamping groove and a third mounting groove positioned below the clamping groove, the main beam is clamped in the clamping groove, and the top of the vertical column is inserted into the third mounting groove.

8. The solar photovoltaic power generation shed as claimed in claim 7, wherein the main beam is provided with a rounded corner, and the shape of the slot is matched with the shape of the main beam so that the main beam can rotate in the slot.

9. The solar photovoltaic power generation shed as claimed in claim 1, wherein cross braces are connected between the connected upright posts, and the cross braces are fixed on the upright posts through cross brace connecting plates.

10. The solar photovoltaic power generation shed as claimed in claim 9, wherein the vertical columns are further connected with at least one inclined strut, one end of the inclined strut is connected to the vertical columns through an inclined strut connecting piece, the other end of the inclined strut is supported on the ground, and the inclined strut and the vertical columns form a triangle.