CN210536576U - Photovoltaic module mounting structure and photovoltaic system - Google Patents

Abstract

The utility model relates to a photovoltaic technology field especially relates to a photovoltaic module mounting structure and photovoltaic system. Photovoltaic module mounting structure, including frame and guide rail, the frame can be followed the length direction of guide rail slides and packs into in the guide rail, the frame surface is provided with the protective layer, be provided with the portion of punctureing on the guide rail, the portion of punctureing is provided with the edge that follows the direction of sliding into of frame extends, the edge can puncture the in-process of packing into of frame the protective layer with the frame butt, so that frame ground connection. In the photovoltaic module mounting structure, the puncture part is arranged, so that the protective layer on the surface of the frame can be damaged, and the frame is grounded conveniently; after the puncture part punctures the protective layer, the protective layer is abutted with the frame, so that the grounding effect is good; the puncture part punctures the protective layer in the process of loading the frame, and the puncture effect is good and the grounding effect is stable through the relative movement of the puncture part and the protective layer.

Description

Photovoltaic module mounting structure and photovoltaic system

Technical Field

The utility model relates to a photovoltaic technology field especially relates to a photovoltaic module mounting structure and photovoltaic system.

Background

The photovoltaic module is a core part in a solar power generation system and is also the most important part in the solar power generation system. The photovoltaic assembly comprises a laminating piece and a photovoltaic assembly frame, wherein the photovoltaic assembly frame is used for packaging and protecting the periphery of the laminating piece. The photovoltaic module frame is fixed on the guide rail, and the guide rail can protect the photovoltaic module, avoids the subassembly to be corroded or is destroyed by wind-force.

In the prior art, the photovoltaic module frame needs to be designed with a grounding structure so as to ensure the safety of the photovoltaic module. Because of photovoltaic module is applied to outdoors, the environment is abominable, and photovoltaic module frame surface generally adheres to there is the protective layer, improves the oxidation resistance and the corrosion resistance of frame, and this leads to frame ground connection difficulty, and the ground connection effect is unstable, appears the potential safety hazard easily.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a photovoltaic module mounting structure, the ground connection of frame is effectual.

To achieve the purpose, the utility model adopts the following technical proposal:

the utility model provides a photovoltaic module mounting structure, includes frame and guide rail, the frame can be followed the length direction of guide rail slides and packs into in the guide rail, the frame surface is provided with the protective layer, be provided with the portion of punctureing on the guide rail, the portion of punctureing is provided with the edge that the direction of sliding into of frame extends, the edge can puncture the in-process of packing into of frame the protective layer and with the frame butt, so that frame ground connection.

Wherein the piercing portion is formed by stamping the guide rail.

The puncturing part is a triangular protrusion, and the edge is formed on one side edge of the triangular protrusion.

Wherein, be provided with on the guide rail along length direction's extension first incision and with first incision is the second incision that the contained angle set up, the second incision is located first incision deviates from the one end of sliding in direction, the punching press the guide rail is located first incision with position formation between the second incision the portion of breaching.

Wherein the maximum height of the puncturing part is gradually increased along the sliding-in direction of the frame.

The height of the puncture part protruding out of the surface of the guide rail is larger than the distance between the frame and the guide rail along the vertical direction.

Wherein, photovoltaic module mounting structure still includes:

the support, the support includes two supporting parts that relative setting and connects two the crossbeam of supporting part, the guide rail install in on the crossbeam, and with the crossbeam is perpendicular.

Wherein the height of the bracket is adjustable.

Wherein, a first sliding part is arranged on the guide rail;

the frame includes two first frameworks that relative setting, first framework includes:

a body; and

and the second sliding part is arranged at the bottom of the body, can form sliding fit with the first sliding part along the length direction of the first frame body, and can abut against the guide rail at the bottom of the body.

The end part of the guide rail along the length direction is provided with an elastic bulge, and after the frame is installed in place, the elastic bulge can be matched with the frame to limit the position of the guide rail and the frame.

The elastic bulge is arranged on the guide rail and can be abutted against the end face, deviating from the sliding direction, of the frame.

The frame is provided with a clamping groove, and the elastic bulge can be clamped into the clamping groove.

The elastic bulge is an elastic sheet, a positioning hole is formed in the guide rail, and the elastic sheet is configured to protrude out of the positioning hole and retract into the positioning hole under stress in the sliding installation process of the frame.

Wherein, the shell fragment includes:

the fixing part is fixedly connected with the guide rail;

the protruding part is connected with the fixing part and can protrude out of the positioning hole or retract into the positioning hole.

The protruding portion comprises a first plate and a second plate, the first plate and the second plate are arranged at included angles, one end of the first plate is connected with the fixing portion, the other end of the first plate is connected with the second plate, the first plate is arranged in an inclined mode, and the height of the first plate is gradually increased along the loading direction of the frame.

The protruding portion further comprises a third plate arranged at an included angle with the second plate, and the first plate and the third plate are located on the same side of the second plate.

The guide rail is further provided with a limiting protrusion, and after the frame is installed in place, the limiting protrusion and the elastic protrusion are respectively located on two sides of the frame in the length direction.

Wherein, the limiting bulge is formed by stamping the guide rail.

The two frames are arranged on the guide rail along the length direction, and the limiting bulges corresponding to the two adjacent frames are arranged at intervals.

Another object of the utility model is to provide a photovoltaic system, the ground connection of frame is effectual.

To achieve the purpose, the utility model adopts the following technical proposal:

a photovoltaic system comprises a laminated part and a photovoltaic module mounting structure as described above, wherein the laminated part is arranged on the frame.

Has the advantages that: the utility model provides a photovoltaic module mounting structure and photovoltaic system. In the photovoltaic module mounting structure, the frame and the guide rail are mounted in a sliding fit manner, so that the frame can be quickly mounted on the guide rail without being mounted in a matched manner by using bolts or pressing blocks and the like, and the photovoltaic module mounting structure is convenient to mount and high in efficiency; bolts or pressing blocks are not needed, so that the stress concentration of the frame and the guide rail can be reduced, and the strength can be improved; the protective layer on the surface of the frame can be damaged by arranging the puncture part, so that the frame is grounded; after the puncture part punctures the protective layer, the protective layer is abutted with the frame, so that the grounding effect is good; the puncture part punctures the protective layer in the process of installing the frame through the edge extending along the length direction of the guide rail, and the puncture effect is good and the grounding effect is stable through the relative movement of the puncture part and the protective layer.

Drawings

Fig. 1 is a perspective view of a photovoltaic system according to an embodiment of the present invention;

fig. 2 is a top view of a laminated member and a frame according to an embodiment of the present invention after assembly;

fig. 3 is a side view of a photovoltaic system according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of the first frame body and the guide rail according to the first embodiment of the present invention after being assembled;

fig. 5 is a perspective view of a guide rail according to a first embodiment of the present invention;

FIG. 6 is an enlarged view of a portion of FIG. 5 at A;

fig. 7 is a front view of a spring plate according to a first embodiment of the present invention;

fig. 8 is a perspective view of a spring plate according to a first embodiment of the present invention;

fig. 9 is a perspective view of a guide rail according to a second embodiment of the present invention;

fig. 10 is a partial enlarged view at B in fig. 9.

Wherein:

1. a guide rail; 10. a first sliding section; 101. a top plate; 102. a side plate; 103. folding edges; 13. an elastic bulge; 131. a fixed part; 1311. a first mounting plate; 1312. a second mounting plate; 132. a boss portion; 1321. a first plate; 1322. a second plate; 1323. a third plate; 14. a limiting bulge; 15. a piercing section; 16. a first chute; 17. a first cut; 18. a second cut;

2. a frame; 20. a second sliding section; 21. a first frame body; 22. a second frame body; 211. a connecting plate; 212. an upper transverse plate; 213. a middle horizontal plate; 214. a second support plate; 215. a cantilever; 216. a first vertical plate; 217. a lower transverse plate; 218. a second vertical plate; 219. a second chute;

3. a support; 31. a support portion; 32. a cross beam;

4. a laminate.

Detailed Description

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Wherein the terms "first position" and "second position" are two different positions.

Unless expressly stated or limited otherwise, the terms "mounted," "connected," and "secured" are to be construed broadly and encompass, for example, both fixed and removable connections; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may include the first feature being in direct contact with the second feature, or may include the first feature being in direct contact with the second feature but being in contact with the second feature by another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

Example one

As shown in fig. 1, the present embodiment provides a photovoltaic system, which includes a laminated member 4 and a photovoltaic module mounting structure, where the photovoltaic module mounting structure includes a frame 2, a guide rail 1, and a bracket 3. Laminating piece 4 sets up on frame 2, and frame 2 is fixed on guide rail 1, and photovoltaic module mounting structure can protect laminating piece 4, avoids laminating piece 4 to be corroded or by wind-force destruction.

As shown in fig. 1 and 2, the laminate 4 has a rectangular structure, and the laminate 4 includes a front plate, a rear plate, and a battery sheet string disposed between the front plate and the rear plate. The battery piece string is composed of a plurality of battery pieces, the plurality of battery pieces are connected in series to obtain high voltage, then connected in parallel to obtain high current, and then a diode is used for preventing current from being transmitted back to realize electric energy output. Both the front and rear plates may be made of glass to protect the string of battery cells. In order to facilitate the fixation of the front plate and the rear plate with the battery piece string respectively, the front plate and the rear plate can be fixed with the battery piece string through glue layers. The front plate, the battery string and the rear plate are laminated by a laminator to form a laminate 4.

The frame 2 is a rectangular frame structure and is used for packaging and protecting the peripheral edge of the laminated part 4, so that the laminated part 4 is prevented from being damaged. Specifically, the frame 2 includes two first frame bodies 21 arranged oppositely and two second frame bodies 22 arranged oppositely, and the first frame bodies 21 and the second frame bodies 22 are sleeved on one side edge corresponding to the laminating member 4 to encapsulate and protect the laminating member 4, so that the pressure resistance of the photovoltaic system is increased, and the service life of the photovoltaic system is prolonged. The laminate 4 and the bezel 2 form a photovoltaic module.

The end portions of the first frame 21 and the second frame 22 are butted, and the first frame 21 and the second frame 22 are integrally joined by fixing the first frame 2 to the laminate 4 and fixing the second frame 3 to the laminate 4. In order to improve the butt joint effect of the first frame 21 and the second frame 22, the butt joint end surfaces of the first frame 21 and the second frame 22 may be inclined surfaces that are matched with each other, so that the contact area between the first frame 21 and the second frame 22 is increased, and the splicing effect is good.

In practical application, there are situations where a plurality of photovoltaic modules are used, and in order to ensure that the installation positions of the plurality of photovoltaic modules are accurate and highly orderly, the photovoltaic module installation structure may include two oppositely disposed guide rails 1, where each guide rail 1 is correspondingly connected to one first frame 21 or one second frame 22 of the frame 2 of the photovoltaic module. In this embodiment, the guide rails 1 extend along the length direction of the first frame body 21, and each guide rail 1 is correspondingly connected with one first frame body 21 of the photovoltaic module, so that the contact area between each photovoltaic module and the guide rail 1 is increased, and the stability of fixing the photovoltaic module is improved.

As shown in fig. 1 and 3, the bracket 3 includes two support portions 31 disposed opposite to each other and a cross beam 32 connected to the two support portions 31, the cross beam 32 is used for supporting the guide rail 1, and the support portions 31 are used for increasing the placement height of the guide rail 1. Alternatively, the guide rail 1 may be perpendicular to the cross beam 32, and the middle portion of the guide rail may be fixedly connected to the cross beam 32, so as to improve the supporting effect and stability of the cross beam 32 on the guide rail 1.

In this embodiment, the support 3 can make the photovoltaic module rotate along with the sunlight irradiation direction. Specifically, the support 3 further includes a driving assembly, the driving assembly is mounted on the support portion 31 and connected to the cross beam 32, and the driving assembly can drive the cross beam 32 to rotate around the axis of the self length direction, so as to adjust the angle of the guide rail 1 on the cross beam 32, so that the photovoltaic assembly can rotate along the sunlight irradiation direction. Optionally, the driving assembly includes an inner ring disposed coaxially with the cross beam 32 and fixedly connected to the cross beam 32, an outer ring sleeved outside the inner ring and capable of rotating relative to the inner ring, and a driving member for driving the inner ring to rotate relative to the outer ring, the outer ring may be fixedly connected to the supporting portion 31, and the driving member may be a motor, a cylinder, or another mechanism capable of realizing rotation of the inner ring.

In this embodiment, the height of support 3 is adjustable, can be according to different needs, the height of adjustment lamination piece. Alternatively, the bottom of the cross beam 32 is provided with a connecting portion, and the connecting portion may be fixedly connected with the support portion 31 by a bolt. The connecting part is provided with a strip hole extending along the vertical direction, the bolt sequentially penetrates through the strip hole and the supporting part 31 and then is locked with the nut, and the height of the support 3 is adjusted by adjusting the position of the bolt in the strip hole.

In other embodiments, the support portion 31 may be a telescopic rod structure.

In order to avoid the pollution or damage caused by the contact of the back surface of the laminated member 4 and the guide rail 1, the back surface of the laminated member 4 and the highest position of the guide rail 1 are arranged at intervals, the distance can be H, and the specific height of the H can be determined according to the actual use requirement.

In the prior art, the first frame body 21 and the guide rail 1 are fixed through a pressing block or a bolt, so that time is required to adjust the relative positions of the photovoltaic module and the guide rail 1, the installation is inconvenient, and the efficiency is low. In order to solve the above problem, in this embodiment, the frame 2 is installed in a sliding manner and in cooperation with the guide rail 1, so that the installation is light and fast, the installation position of the photovoltaic module can be limited by the sliding direction, the uniformity of the photovoltaic module after installation is ensured, and the installation efficiency of the photovoltaic module is improved. In addition, through the sliding fit installation, need not to use bolt or briquetting, can also reduce photovoltaic module frame and guide rail 1's stress concentration, can improve intensity.

Specifically, as shown in fig. 2, 3 and 4, the guide rail 1 is provided with a first sliding portion 10, the first frame 21 includes a body and a second sliding portion 20 disposed at the bottom of the body, and the second sliding portion 20 can form a sliding fit with the first sliding portion 10 along the length direction of the first frame 21, that is, is installed on the guide rail 1 in a sliding manner, so as to fix the guide rail 1 and the first frame 21; simultaneously, the bottom of body can also the butt on guide rail 1 for guide rail 1 can support first framework 21 and lamination piece 4, has increased photovoltaic module frame and guide rail 1's area of contact, is favorable to improving photovoltaic module's intensity and stability.

The body includes connecting plate 211 and from top to bottom set gradually go up diaphragm 212 and middle diaphragm 213, goes up diaphragm 212 and middle diaphragm 213 and all is connected with connecting plate 211 and is located the same one side of connecting plate 211. A receiving groove for receiving the edge of the lamination member 4 is formed between the upper transverse plate 212 and the middle transverse plate 213. In order to improve the fixing effect of the laminated part 4 and the first frame body 21, the laminated part 4 and the accommodating groove can be fixed by adhesive bonding, and the laminated part 4 is prevented from shaking between the upper transverse plate 212 and the middle transverse plate 213. Alternatively, the glue may be a silicone glue. In order to avoid the problem that the normal operation of the photovoltaic module is influenced by the overflow of the silica gel to the surface of the laminated part 4 in the gluing process, the lower surface of the upper transverse plate 212 is also provided with an overflow groove, and the excessive glue flows out through the overflow groove in the gluing process to avoid polluting the laminated part 4.

In this embodiment, the second sliding portion 20 is provided with a second sliding slot 219, and the first sliding portion 10 is in sliding fit with the second sliding slot 219. Specifically, the second sliding portion 20 includes a first vertical plate 216, a lower cross plate 217, and a second vertical plate 218. One end of the first vertical plate 216 is connected with the bottom of the middle transverse plate 213, the other end is connected with the lower transverse plate 217, the second vertical plate 218 is connected with the lower transverse plate 217, and the first vertical plate 216, the lower transverse plate 217 and the second vertical plate 218 can be U-shaped, so that a second sliding groove 219 is formed among the first vertical plate 216, the lower transverse plate 217, the second vertical plate 218 and the body.

The first sliding portion 10 includes a top plate 101, and the top plate 101 may be disposed in parallel with the lower cross plate 217. When guide rail 1 and frame cooperate, in the roof 101 level stretched into second spout 219, the bottom surface sliding fit of the top surface of roof 101 and body, the bottom surface of roof 101 and the top surface sliding fit of diaphragm 217 down can increase the cooperation area of first sliding part 10 and second sliding part 20 to gliding stability is improved.

Optionally, the first sliding portion 10 may further include a side plate 102, and the top plate 101 is disposed on top of the side plate 102. Through setting up curb plate 102, can with the cooperation of lower diaphragm 217 towards one side of curb plate 102, play the guide effect, be favorable to improving sliding fit's stability.

In order to allow the top plate 101 in the first sliding portion 10 to extend into the second sliding groove 219, the height of the second vertical plate 218 is smaller than that of the first vertical plate 216, so that a gap exists between the second vertical plate 218 and the center horizontal plate 213, and the top plate 101 can slide between the second vertical plate 218 and the center horizontal plate 213.

In order to make the second sliding portion 20 slide smoothly with the first sliding portion 10, a hem 103 may further extend downward from the inside of the top plate 101. When the second sliding portion 20 is engaged with the first sliding portion 10, the top plate 101 can slide between the center cross plate 213 and the second vertical plate 218, and the folded edge 103 can extend between the first vertical plate 216 and the second vertical plate 218, so that the folded edge 103 is engaged with the second sliding groove 219 to further limit the sliding direction of the second sliding portion 20, and the second sliding portion 20 is prevented from being jammed in the second sliding groove 219 after being deflected, and the sliding engagement can be smoother.

In addition, the top plate 101 is located between the middle cross plate 213 and the second vertical plate 218, the folded edge 103 is located between the first vertical plate 216 and the second vertical plate 218, and the position of the second sliding portion 20 can be limited in the vertical direction and the width direction of the guide rail 1, so that the position of the first frame body 21 is limited, the photovoltaic module is prevented from shaking, and the photovoltaic module is more stably mounted.

Optionally, the body may further include a cantilever arm 215, the cantilever arm 215 being located below the midplane 213. One end of the cantilever 215 is connected to the connecting plate 211, the second slider 20 is connected to the bottom of the cantilever 215, the cantilever 215 is spaced apart from the center cross plate 213, and the bottom surface of the cantilever 215 can abut against the guide rail 1. When the first housing 21 is engaged with the guide rail 1, the cantilever 215 abuts against the top plate 101. Through setting up cantilever 215, can increase the distance between holding tank and the guide rail 1, avoid leading to lamination piece 4 and guide rail 1 contact because of photovoltaic module frame or guide rail 1 warp to avoid polluting lamination piece 4 or crushing lamination piece 4.

In order to further improve the strength of the first frame body 21, a second support plate 214 may be further disposed between the cantilever 215 and the central horizontal plate 213, one end of the second support plate 214 is connected to the central horizontal plate 213, and the other end is connected to the cantilever 215, so as to prevent the first frame body 21 from being deformed by stress, thereby ensuring that the lamination member 4 is not polluted or crushed.

In order to further improve the stability of the sliding fit of the first sliding part 10 and the second sliding part 20, the distance between the second vertical plate 218 and the body can be matched with the thickness of the top plate 101, that is, the distance between the second vertical plate 218 and the body is equal to or slightly greater than the thickness of the top plate 101, so that the supporting effect of the guide rail 1 on the body can be improved, and the assembly is more stable.

Alternatively, the first riser 216 and the connecting plate 211 can be an integrally formed structure, that is, one end of the connecting plate 211 continues to extend downward from the bottom of the cantilever 215 to form the first riser 216, which can further simplify the structure of the first frame body 21.

After the photovoltaic module frame is assembled with the guide rail 1, the two ends of the second frame body 22 are overlapped on the guide rail 1, so that the photovoltaic frame is further supported.

To further improve the supporting effect of the guide rail 1 on the photovoltaic frame, the structure of the second frame 22 may be the same as that of the body of the first frame 21.

In another embodiment, the second sliding portion 20 may be provided at the bottom of the second frame 22, and it should be noted that, in the second sliding portion 20 of the second frame 22, the first vertical plate 216 is perpendicular to the longitudinal direction of the second frame 22, so that the second sliding portion 20 of the second frame 22 can be slidably engaged with the first sliding portion 10 on the guide rail 1 along the longitudinal direction of the first frame 21 similarly, and the fixing effect of the guide rail 1 and the photovoltaic module frame is further improved.

In this embodiment, the first sliding portion 10 is provided with a first sliding slot 16, and the second sliding portion 20 is shaped to fit the first sliding slot 16, so that the second sliding portion 20 can slide into the first sliding slot 16. Specifically, the guide rail 1 includes two side plates 102 disposed oppositely and connected at the bottom, the side plates 102 and the top plate 101 enclose to form a first sliding chute 16, the first sliding chute 16 extends along the length direction of the guide rail 1, and one end of the guide rail 1 along the length direction is open, and the second sliding portion 20 can slide into the first sliding chute 16 through the end opening. The bottom of the body of the first housing 2 may abut on the top plate 101. When the guide rail 1 is assembled with the frame 2, the second sliding portion 20 extends into the first sliding groove 16 on the first sliding portion 10, and the top plate 101 and the folded edge 103 extend into the second sliding groove 219 on the second sliding portion 20, so that the guide rail 1 and the frame 2 slide in an embedded manner, and the sliding fit effect of the guide rail 1 and the frame can be further improved.

Alternatively, two first frame bodies 21 may be slidably fitted on the same guide rail 1, and the two first frame bodies 21 are arranged in a mirror image manner with respect to the length direction of the guide rail 1. Two first frame bodies 21 are supported through one guide rail 1, the number of the guide rails 1 required for fixing a plurality of photovoltaic modules can be reduced, and cost reduction is facilitated.

Optionally, two first frame bodies 21 on the same guide rail 1 can be abutted to each other, so that the arrangement of a plurality of photovoltaic modules is more compact, and the stability of fixing the first frame bodies 21 can be improved, thereby improving the fixing effect of the photovoltaic modules.

In order to improve the accuracy of the mounting position of the first frame 21 on the guide rail 1, as shown in fig. 5, in this embodiment, the end of the guide rail 1 in the length direction thereof may be further provided with an elastic protrusion 13. When the first frame 21 is slidably installed on the guide rail 1, the first frame 21 can press the elastic protrusion 13, so that the elastic protrusion 13 is compressed, and the first frame 21 can smoothly slide into the guide rail 1. When the first frame body 21 is installed in place, the elastic protrusions 13 are released to bounce, and the elastic protrusions 13 cooperate with the first frame body 21 to limit the position of the first frame body 21, so that the first frame body 21 is fixed.

In this embodiment, in order to improve the matching and positioning effect between the elastic protrusion 13 and the first frame 21, a clamping groove is further disposed on the frame 2. After the first frame body 21 slides in place, the elastic protrusions 13 correspond to the clamping grooves in position, the elastic protrusions 13 are not stressed any more, so that the elastic protrusions 13 are bounced and released, the elastic protrusions 13 are clamped into the clamping grooves, the first frame body 21 is limited to continue sliding along the length direction of the guide rail 1, and the purpose of positioning is achieved. Alternatively, the card slot may be provided at the bottom of the first frame 21, or may be provided at the bottom of the second frame 22.

In other embodiments, the elastic protrusion 13 may also be disposed at the bottom of the first frame 21 or the second frame 22, and the corresponding slot is disposed at the top of the guide rail 1, so that the elastic protrusion 13 and the slot can also be engaged with each other.

Optionally, the elastic protrusion 13 may be matched with the end of the frame 2 after being released and bounced, and the sliding of the frame 2 is limited by abutting against the end of the frame 2 departing from the sliding-in mounting direction. Under this kind of circumstances, in order to avoid frame 2 to continue to slide along the installation direction that slides in, a plurality of frames 2 can be installed along its length direction on same guide rail 1, and adjacent frame 2 butt to realize frame 2 along the spacing of guide rail 1's length direction both sides.

With continued reference to fig. 5 and 6, the guide rail 1 is provided with a positioning hole 11, and the elastic protrusion 13 can protrude out of the positioning hole 11 when no external force is applied, so as to be clamped into the clamping groove.

Specifically, in order to avoid the elastic projection 13 from affecting the mounting of the first frame body 21, the top surface of the elastic projection 13 is a slope whose height gradually increases in the slide-in direction (arrow direction shown in fig. 5) of the first frame body 21. When the first frame 21 is slidably installed on the guide rail 1, the bottom surface of the first frame 21 gradually presses the elastic protrusion 13 under the guiding action of the inclined surface, so that the elastic protrusion 13 is compressed into the positioning hole 11, and the normal installation of the first frame 21 is ensured. When the first frame 21 is mounted in place, the elastic protrusion 13 is no longer stressed and automatically bounces, so as to be clamped into the clamping groove at the bottom of the first frame 21.

In this embodiment, two first frame bodies 21 may be installed on each guide rail 1 along the length direction thereof, and the two first frame bodies 21 are turned in from the corresponding end of the guide rail 1.

In this embodiment, the elastic protrusion 13 may be a spring plate, which is simple in structure and convenient to process. As shown in fig. 7 and 8, the elastic piece includes a fixing portion 131 and a protruding portion 132. The fixing portion 131 can be fixedly connected to the guide rail 1 by a fastener such as a screw or a rivet, the protruding portion 132 is connected to the fixing portion 131, and the protruding portion 132 can protrude out of the positioning hole 11 or retract into the positioning hole 11. In this embodiment, shell fragment and guide rail 1 are split type structure, and the shell fragment can adopt high strength material to make, and the shell fragment adopts different materials to make with guide rail 1, is favorable to avoiding the shell fragment to damage on the one hand, and on the other hand can reduce guide rail 1's cost.

The fixing portion 131 may include a first mounting plate 1311 and a second mounting plate 1312, and the first mounting plate 1311 and the second mounting plate 1312 are respectively close to and fixed to a side wall corresponding to the guide rail 1, so as to improve strength and fixing effect of the elastic sheet and prevent the elastic sheet from being deformed.

Alternatively, the protruding portion 132 includes a first plate 1321 and a second plate 1322 arranged at an included angle, one end of the first plate 1321 is connected to the fixing portion 131, the other end is connected to the second plate 1322, the first plate 1321 is arranged obliquely, and the height of the first plate 1321 gradually increases along the installation direction of the first frame 21. By providing the first plate 1321 obliquely, the top surface of the elastic projection 13 is inclined, and the first frame 21 is guided to be smoothly attached.

Optionally, boss 132 further includes a third plate 1323 disposed at an angle to second plate 1322, with first plate 1321 and third plate 1323 being located on the same side of second plate 1322. The elastic deformation capability of the end of the protruding portion 132 away from the fixing portion 131 can be improved by the third plate 1323, and the elastic sheet is further prevented from being deformed.

In other embodiments, the spring may be formed by stamping the side walls of the rail 1.

In this embodiment, in order to improve the positioning effect of the frame 2, the guide rail 1 is further provided with a limiting protrusion 14, and after the frame 2 is installed in place, the limiting protrusion 14 and the elastic protrusion 13 are respectively located on two sides of the frame 2 along the length direction of the guide rail 1, so that the frame 2 is fixed between the limiting protrusion 14 and the elastic protrusion 13.

Alternatively, the limiting protrusion 14 may be formed by stamping the side wall of the guide rail 1, which is beneficial to simplifying the structure of the guide rail 1 and reducing the processing cost.

Through setting up spacing arch 14 and elastic bulge 13 and mutually supporting, two frames 2 adjacent along length direction on the guide rail 1 can the interval set up, avoid adjacent frame 2 mutual interference.

Optionally, a protective layer is disposed on the surface of the frame 2, and the protective layer may be an anti-oxidation layer, which is beneficial to prolonging the service life of the frame 2 in a severe environment.

Example two

As shown in fig. 9, the present embodiment provides a photovoltaic system, which is different from the first embodiment in that a penetrating portion 15 is further disposed on the guide rail 1, and the penetrating portion 15 can penetrate the protective layer and abut against the bezel 2 during the installation process of the bezel 2, so that the bezel 2 can be reliably grounded.

As shown in fig. 10, the puncturing part 15 includes an edge extending along the direction of the peripheral frame 2, and the edge can puncture the protective layer during the sliding process of the peripheral frame 2, so that the puncturing effect is improved by the relative movement of the puncturing part 15 and the peripheral frame 2, and thus, a stable and continuous grounding effect is achieved.

In order to simplify the structure of the guide rail 1 and to improve the piercing effect of the piercing portion 15, the piercing portion 15 may be formed by punching the guide rail 1. Specifically, the guide rail 1 is provided with a first notch 17 extending along the length direction and a second notch 18 arranged at an included angle with the first notch 17, the second notch 18 is located at one end of the first notch 17 far from the sliding-in side, and the punching portion 15 is formed at a position of the punching guide rail 1 between the first notch 17 and the second notch 18. The piercing section 15 forms the above-mentioned edge after punching in a position corresponding to the first cut 17.

In this embodiment, the piercing part 15 is a triangular protrusion, and an edge is formed on one side of the triangular protrusion, so as to better pierce the protective layer.

Because the puncturing part 15 protrudes relative to the top surface of the guide rail 1, in order to avoid the puncturing part 15 from influencing the installation of the frame 2, the height of the puncturing part 15 is gradually increased along the sliding-in direction of the frame 2, on one hand, the sliding of the frame 2 is guided, and on the other hand, the abutting effect of the puncturing part 15 and the frame 2 can be ensured.

In order to ensure that the grounding effect is more reliable, the maximum height of the puncture part 15 protruding out of the surface of the guide rail 1 can be higher than the distance between the frame 2 and the guide rail 1 along the vertical direction, so that the puncture part 15 can be abutted against the frame 2, the puncture effect can be improved, and good contact between the puncture part 15 and the frame 2 after the protective layer is punctured can also be ensured.

In this embodiment, the puncturing part 15 may be disposed at an end close to the limiting protrusion 14, which is beneficial to ensure the smooth installation of the frame 2.

The above description is only for the preferred embodiment of the present invention, and for those skilled in the art, there are variations on the detailed description and the application scope according to the idea of the present invention, and the content of the description should not be construed as a limitation to the present invention.

Claims (10)

1. The utility model provides a photovoltaic module mounting structure, includes frame (2) and guide rail (1), its characterized in that, frame (2) can be followed the length direction of guide rail (1) slides and packs into in guide rail (1), frame (2) surface is provided with the protective layer, be provided with puncture portion (15) on guide rail (1), puncture portion (15) are provided with the edge that follows the direction of sliding into of frame (2) extends, the edge can puncture the in-process of packing into of frame (2) the protective layer and with frame (2) butt, so that frame (2) ground connection.

2. The photovoltaic module mounting structure according to claim 1, wherein the piercing portion (15) is formed by punching the rail (1).

3. The photovoltaic module mounting structure according to claim 2, wherein the puncture portion (15) is a triangular projection, one side of which forms the edge.

4. A photovoltaic module mounting arrangement according to claim 3, wherein the guide rail (1) is provided with a first cut-out (17) extending in the length direction and a second cut-out (18) arranged at an angle to the first cut-out (17), the second cut-out (18) being located at an end of the first cut-out (17) facing away from the sliding-in direction, and the puncture portion (15) is formed by punching the guide rail (1) at a position between the first cut-out (17) and the second cut-out (18).

5. The photovoltaic module mounting structure according to claim 1, wherein the height of the piercing portion (15) is gradually increased in a sliding-in direction of the rim (2).

6. The photovoltaic module mounting structure according to claim 5, wherein the maximum height of the puncture portion (15) protruding from the surface of the guide rail (1) is larger than the distance between the bezel (2) and the guide rail (1) in the vertical direction.

7. The photovoltaic module mounting structure according to any one of claims 1 to 6, further comprising:

the support (3), support (3) are including two supporting parts (31) that relative setting and connect two crossbeam (32) of supporting part (31), guide rail (1) install in on crossbeam (32), and with crossbeam (32) are perpendicular.

8. The photovoltaic module mounting structure according to claim 7, wherein the height of the bracket (3) is adjustable.

9. The photovoltaic module mounting structure according to any one of claims 1 to 6, wherein the guide rail (1) is provided with a first sliding portion (10);

the frame (2) comprises two first frame bodies (21) which are oppositely arranged, and each first frame body (21) comprises:

a body; and

and a second sliding part (20) which is arranged at the bottom of the body, wherein the second sliding part (20) can be in sliding fit with the first sliding part (10) along the length direction of the first frame body (21), and the bottom of the body can be abutted against the guide rail (1).

10. A photovoltaic system comprising a laminate (4), characterized in that it further comprises a photovoltaic module mounting structure according to any one of claims 1-9, said laminate (4) being arranged on said rim (2).

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