CN210985993U - But angle of adjustment's installing support for solar panel concatenation - Google Patents

Abstract

The utility model discloses an angle-adjustable mounting bracket for splicing a solar panel, which mainly comprises a supporting square box and a supporting sleeve component, wherein the top surface and the bottom surface of the supporting square box are provided with large screw holes, the side wall of the supporting square box is provided with a round hole, a limiting steel ball is arranged near the round hole, the limiting steel ball is connected with the inner wall of the supporting square box through a spring, and a spring barrel is sleeved outside the spring; the supporting sleeve component comprises a rotating shaft and a shaft sleeve, annular grooves are formed in two ends of the rotating shaft, and the limiting steel balls are clamped in the annular grooves; the outer wall of the shaft sleeve is connected with a first supporting rod and a first triangular plate, the rotating shaft is connected with a second supporting rod and a second triangular plate, and the first supporting rod and the second supporting rod are distributed at equal intervals and symmetrically. The utility model constructs a flexible supporting structure, the supporting square box is used as a fixed mounting node, and the supporting sleeve component is used as an angle adjusting structure of the solar panel, so that the solar panel supporting structure is suitable for assembling solar panels in different terrain areas; adopt the utility model discloses the solar panel overall structure of concatenation has the anti external force performance of preferred, and the security is high.

Description

But angle of adjustment's installing support for solar panel concatenation

Technical Field

The utility model relates to a solar panel installs technical field, especially relates to an angle of adjustment's solar panel installing support for concatenation.

Background

The current single-block packaged solar panel is generally low in voltage and current, the highest voltage is 12V or 24V, and the current is generally 4A or 8A, so that the solar panels are generally spliced before practical application or grid connection in order to improve the power transformation efficiency of an inverter, and the splicing comprises parallel splicing and series splicing.

In the prior art, a plurality of solar panels are directly installed and used through a bracket, faults frequently occur in the using process, and the service life is short; the angle is adjusted in a mode that the whole support structure is adjusted, so that the support structure is not suitable for being paved on various roofs or floors with uneven surfaces; in addition, the laying mode of a hippeastrum makes the appearance of a photovoltaic roof or an eave more common, and is not favorable for the aesthetic degree of roof design.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the shortcoming that exists among the prior art, but the solar panel concatenation of an angle of adjustment installing support is used.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a mounting bracket for splicing a solar panel with adjustable angle mainly comprises a supporting square box and a supporting sleeve component, wherein the top surface and the bottom surface of the supporting square box are provided with corresponding large screw holes, a plurality of large screw holes are symmetrically distributed at four corners, the central positions of four outer side walls of the supporting square box are provided with round holes, eight limiting steel balls are annularly distributed near the round holes, the limiting steel balls are connected with springs, the springs are sleeved with spring barrels, and the outer diameters of the limiting steel balls are smaller than the inner diameter of the spring barrels;

the two groups of spring barrels and the two springs are fixedly connected to the top inner wall of the supporting square box, the two groups of spring barrels and the two springs are fixedly connected to the bottom inner wall of the supporting square box, and the other four groups of spring barrels and the two springs are fixedly connected to the two symmetrical inner side walls of the supporting square box; a gap is reserved between the outer wall of the spring cylinder and the side wall of the supporting square box, the two symmetrical round holes form a virtual cylinder, the initial position of the limiting steel ball is positioned in the cylindrical range of the round holes, and one end, far away from the inner wall of the supporting square box, of the spring cylinder is positioned outside the cylindrical range of the round holes;

the supporting sleeve component comprises a rotating shaft and a shaft sleeve sleeved outside the rotating shaft, two ends of the rotating shaft extend out of the shaft sleeve, annular grooves are formed in two ends of the rotating shaft, the cross section of each annular groove is semicircular, a limiting steel ball is clamped in each annular groove, a large screw penetrates through each large screw hole, each large screw has the function of limiting the rotating shaft, the rotating shafts in all directions are guaranteed not to be in contact with each other, the limiting steel balls are also guaranteed not to be over-positioned, and the limiting steel balls are just clamped in the annular grooves;

the outer wall of the shaft sleeve barrel is vertically connected with a first supporting rod, the first supporting rod is connected with a first triangular plate, a small screw hole is formed in the first triangular plate, arc-shaped strip holes are further formed in the outer wall of the shaft sleeve barrel at equal intervals, a second supporting rod is movably clamped in the arc-shaped strip holes, one end of the second supporting rod is vertically connected to the shaft wall of the rotating shaft, the other end of the second supporting rod is connected with a second triangular plate, and the second triangular plate is also provided with a small screw hole;

the first support rod and the second support rod are distributed at equal intervals along the length direction of the shaft sleeve;

the outer diameter of the shaft sleeve is larger than the diameter of the round hole and larger than the outer diameter of the rotating shaft.

Preferably, the included angle between the first triangular plate and the first supporting rod is 55-90 degrees, and the included angle between the second supporting rod and the second triangular plate is also 55-90 degrees.

Preferably, the supporting square box is a cast iron piece, and the end surface of the shaft sleeve is fixedly lined with an iron absorption ring.

Preferably, the contact surface of the rotating shaft and the shaft sleeve is filled with lubricating oil.

Preferably, the first triangular plate or the second triangular plate is respectively connected with the bottom surface of one solar panel through screws.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses a support square box and support sleeve subassembly and connect, as the bearing structure of solar panel concatenation usefulness, support square box as fixed mounting node for arrange whole solar panel mosaic structure in established mounted position, support sleeve subassembly as the support spool of solar panel, before each solar panel concatenation, all can be through the rotation of pivot in the axle sleeve, adjust the contained angle of first bracing piece and second bracing piece, the gradient of first bracing piece and second bracing piece itself of arranging again, the contained angle between the adjacent solar panel has been decided; and according to the clearance between the solar panel, adjust first set-square and second set-square and be located solar panel's mounted position, consequently the utility model provides a bearing structure can be fit for the solar panel equipment of different region topography.

2. In the solar panel overall structure that has assembled, because the pivot cup joints in the activity of axle sleeve, so there is certain nimble variability in the contained angle between the adjacent solar panel, forms similar space broken line plate structure, has certain wrench movement possibility between each board, is experiencing torrential rain, heavy snow or high wind weather, produces certain wrench movement between each board, can let out the positive external force that receives of solar panel for a large part, the whole mosaic structure's of being convenient for external force resistance performance improves the security.

Drawings

Fig. 1 is a schematic view of an assembly structure of an installation bracket for splicing a solar panel with adjustable angle provided by the present invention;

fig. 2 is a schematic perspective view of a supporting sleeve assembly of an angle-adjustable mounting bracket for splicing a solar panel according to the present invention;

fig. 3 is a schematic view of an internal structure of a supporting sleeve component of an installation bracket for splicing a solar panel with adjustable angle provided by the utility model;

fig. 4 is a side view of the internal structure of the supporting square box of the mounting bracket for splicing the solar panel with adjustable angle provided by the utility model;

fig. 5 is a top view of the internal structure of the supporting square box of the mounting bracket for splicing the solar panel with adjustable angle according to the present invention;

FIG. 6 is a simple diagram of the angle adjustment principle of the mounting bracket for splicing the solar panel with adjustable angle provided by the present invention;

in the figure: the supporting square box 1, a large screw hole 101, a round hole 102, a limiting steel ball 103, a spring 104, a spring barrel 105, a supporting sleeve component 2, a rotating shaft 201, a shaft sleeve 202, an annular groove 203, a first supporting rod 204, a first triangular plate 205, a small screw hole 206, an arc-shaped strip hole 207, a second supporting rod 208, a second triangular plate 209 and an iron absorbing ring 210.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-6, an angle-adjustable mounting bracket for splicing a solar panel mainly comprises a supporting square box 1 and a supporting sleeve component 2, wherein the top surface and the bottom surface of the supporting square box 1 are provided with corresponding large screw holes 101, the large screw holes 101 are symmetrically distributed at four corners, round holes 102 are formed in the center positions of four outer side walls of the supporting square box 1, eight limiting steel balls 103 are annularly distributed near the round holes 102, the limiting steel balls 103 are connected with springs 104, the springs 104 are sleeved with spring barrels 105, and the outer diameters of the limiting steel balls 103 are smaller than the inner diameter of the spring barrels 105; two groups of spring barrels 105 and two springs are fixedly connected to the top inner wall of the supporting square box 1, two groups of spring barrels 105 and two springs are fixedly connected to the bottom inner wall of the supporting square box 1, and the other four groups of spring barrels 105 and two springs are fixedly connected to two symmetrical inner side walls of the supporting square box 1; a gap is reserved between the outer wall of the spring cylinder 105 and the side wall of the supporting square box 1, the two symmetrical round holes 102 form a virtual cylinder, the initial position of the limiting steel ball 103 is positioned in the cylindrical range of the round holes 102, and one end, far away from the inner wall of the supporting square box 1, of the spring cylinder 105 is positioned outside the cylindrical range of the round holes 102; the support sleeve component 2 comprises a rotating shaft 201 and a shaft sleeve 202 sleeved outside the rotating shaft 201, two ends of the rotating shaft 201 extend out of the shaft sleeve 202, two ends of the rotating shaft 201 are provided with annular grooves 203, the sections of the annular grooves 203 are semicircular, and the limiting steel balls 103 are clamped in the annular grooves 203; a first supporting rod 204 is vertically connected to the outer wall of the shaft sleeve 202, the first supporting rod 204 is connected with a first triangular plate 205, a small screw hole 206 is formed in the first triangular plate 205, arc-shaped bar holes 207 are further formed in the outer wall of the shaft sleeve 202 at equal intervals, a second supporting rod 208 is movably clamped in the arc-shaped bar holes 207, one end of the second supporting rod 208 is vertically connected to the shaft wall of the rotating shaft 201, the other end of the second supporting rod 208 is connected with a second triangular plate 209, and a small screw hole 206 is also formed in the second triangular plate 209; the first support bar 204 and the second support bar 208 are symmetrically distributed at equal intervals along the length direction of the shaft sleeve 202; the outer diameter of the shaft sleeve 202 is larger than the diameter of the round hole 102 and the outer diameter of the rotating shaft 201.

Referring to fig. 1 to 6, an included angle between the first triangular plate 205 and the first supporting rod 204 is 55 to 90 °, an included angle between the second supporting rod 208 and the second triangular plate 209 is also 55 to 90 °, so as to form a standard component, and as the rotating shaft 201 rotates in the shaft sleeve 202, the included angle between the first supporting rod 204 and the second supporting rod 208 is matched with the self-inclination of the first supporting rod 204 and the second supporting rod 208, so as to determine the included angle between adjacent solar panels; and according to the clearance between the solar panel, adjust the first set square 205 and the second set square 209 and be located the mounted position of solar panel, as shown in fig. 6, can be fit for the solar panel assembly of different regional topography.

Referring to fig. 6, the supporting square box 1 is specifically an iron casting, the end surface of the shaft sleeve 202 is fixedly lined with an iron absorbing ring 210 to provide a certain attraction force, when the supporting square box 1 is installed, the shaft sleeve 202 can be fixed on the supporting square box 1, the inclination of the first triangular plate 205 can be adjusted, then the rotating shaft 201 is rotated to adjust the angle of the second triangular plate 209, and the solar panel is fastened through screws.

Referring to fig. 1, a contact surface between a rotating shaft 201 and a shaft sleeve 202 is filled with lubricating oil.

Referring to fig. 1, a first triangular plate 205 or a second triangular plate 209 is respectively connected with the bottom surface of a solar panel by screws, the size and the distribution position of the solar panel are limited according to a topographic angle drawing by adopting a method of drilling screw holes on the site of the solar panel, the fixed position of the first triangular plate 205 or the second triangular plate 209 is determined, and small screw holes 206 are drilled on the solar panel; when the solar panel splicing assembly is installed, all solar panels are assembled firstly, and then the supporting square boxes 1 are fixed through the large screws and the large screw holes 101 according to the requirements of stability and terrain, so that the solar panels are spliced and assembled.

The angle adjustment principle of the utility model is as shown in fig. 6: the rotation shaft 201 is rotated to adjust the tilt angle of the second triangle 209, and the position of the second triangle 209 on the solar panel is adjusted to make the sides of the adjacent solar panels contact and abut against each other.

The utility model discloses a concatenation installation example one (wave dogleg shape): adopt several groups of support sleeve subassemblies 2 that the space is parallel, every group supports sleeve subassembly 2 and passes through the straight line form mounting structure that support square box 1 and connect gradually and form by a plurality of parallel pivot 201 and axle sleeve 202, according to the angle requirement of topography (like tile roof), sets for the little screw hole position at each solar panel back, assembles according to above-mentioned method in proper order, obtains the solar panel mosaic structure of wave dogleg shape.

The utility model discloses a concatenation installation example two (space dogleg shape): adopt several groups of parallel in space to support the axle subassembly 2, every group supports axle subassembly 2 and passes through the straight line shape mounting structure that supports square box 1 and connect gradually and form by a plurality of parallel pivot 201 and axle sleeve 202, and wherein two middle support axle subassemblies 2 are high different to form a spill broken line and a convex broken line, and the limit of two broken lines is connected, also is the solar panel mosaic structure of a holistic space broken line shape.

The utility model discloses a concatenation installation example is three (trapezoidal): adopt two sets of right angle structure support sleeve subassembly 2 collocation several straight line structures's support sleeve subassembly 2, form the connecting rod structure of a plane door type, make the solar panel symmetry slope at both ends, the solar panel at middle part is located the coplanar to form trapezoidal solar panel mosaic structure.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (5)

1. The mounting support for splicing the solar panel with the adjustable angle is mainly composed of a supporting square box (1) and a supporting sleeve component (2), and is characterized in that the top surface and the bottom surface of the supporting square box (1) are provided with corresponding large screw holes (101), the large screw holes (101) are symmetrically distributed in four corners, round holes (102) are formed in the center positions of four outer side walls of the supporting square box (1), eight limiting steel balls (103) are annularly distributed near the round holes (102), the limiting steel balls (103) are connected with springs (104), spring barrels (105) are sleeved outside the springs (104), and the outer diameters of the limiting steel balls (103) are smaller than the inner diameter of the spring barrels (105);

the two groups of spring cylinders (105) and the two springs are fixedly connected to the top inner wall of the supporting square box (1), the two groups of spring cylinders (105) and the two springs are fixedly connected to the bottom inner wall of the supporting square box (1), and the other four groups of spring cylinders (105) and the two springs are fixedly connected to two symmetrical inner side walls of the supporting square box (1); a gap is reserved between the outer wall of the spring cylinder (105) and the side wall of the supporting square box (1), the two symmetrical round holes (102) form a virtual cylinder, the initial position of the limiting steel ball (103) is located in the cylindrical range of the round holes (102), and one end, far away from the inner wall of the supporting square box (1), of the spring cylinder (105) is located outside the cylindrical range of the round holes (102);

the supporting sleeve component (2) comprises a rotating shaft (201) and a shaft sleeve (202) sleeved outside the rotating shaft (201), two ends of the rotating shaft (201) extend out of the shaft sleeve (202), two ends of the rotating shaft (201) are provided with annular grooves (203), the cross sections of the annular grooves (203) are semicircular, and the limiting steel balls (103) are clamped in the annular grooves (203);

the outer wall of the shaft sleeve (202) is vertically connected with a first supporting rod (204), the first supporting rod (204) is connected with a first triangular plate (205), a small screw hole (206) is formed in the first triangular plate (205), arc-shaped bar holes (207) are further formed in the outer wall of the shaft sleeve (202) at equal intervals, a second supporting rod (208) is movably clamped in the arc-shaped bar holes (207), one end of the second supporting rod (208) is vertically connected to the shaft wall of the rotating shaft (201), the other end of the second supporting rod (208) is connected with a second triangular plate (209), and the second triangular plate (209) is also provided with a small screw hole (206);

the first support rod (204) and the second support rod (208) are distributed at equal intervals along the length direction of the shaft sleeve (202);

the outer diameter of the shaft sleeve (202) is larger than the diameter of the round hole (102) and larger than the outer diameter of the rotating shaft (201).

2. The mounting bracket for splicing an angle-adjustable solar panel according to claim 1, wherein the angle between the first triangular plate (205) and the first supporting rod (204) is 55-90 °, and the angle between the second supporting rod (208) and the second triangular plate (209) is 55-90 °.

3. The mounting bracket for splicing an angle-adjustable solar panel according to claim 1, wherein the supporting square box (1) is made of iron casting, and the end surface of the shaft sleeve (202) is fixedly lined with an iron-absorbing ring (210).

4. The mounting bracket for splicing an angle-adjustable solar panel according to claim 1, wherein the contact surface between the rotating shaft (201) and the shaft sleeve (202) is filled with lubricating oil.

5. The mounting bracket for splicing an angle-adjustable solar panel according to claim 1, wherein the first triangular plate (205) or the second triangular plate (209) is respectively connected with a bottom surface screw of a solar panel.

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