CN223379112U - Double-glass single crystal photovoltaic bracket - Google Patents

Abstract

The utility model discloses a double-glass single crystal photovoltaic bracket, comprising a base plate and a bracket, a mounting ear being provided at the rear end of the base plate, a hinge being provided on the mounting ear for connecting to the bracket, a first side column being provided on one side of the base plate, a second side column being provided on one side of the bracket, a hydraulic cylinder being movably connected to the first side column, a hydraulic rod being provided in the hydraulic cylinder, wherein the top end of the hydraulic rod is movably connected to the second side column; a card slot being provided above the base plate, a card tooth being provided inside the card slot, an adjustment component matching the card tooth being slidably installed on the base plate, a support block being used for supporting the bottom of the bracket, thereby stabilizing the installation position of the bracket, and this design allows the support block to slide on the base plate, thereby dynamically adjusting its support position under the bracket; when it is necessary to adjust the angle of the bracket, the position of the support block is adjusted by starting the motor; this greatly simplifies the manual adjustment process, improves the efficiency and convenience of installation and adjustment, and eliminates the need for complex mechanical operations.

Description

Double-glass single crystal photovoltaic bracket

Technical Field

The utility model belongs to the technical field of photovoltaic supports, and particularly relates to a double-glass monocrystalline photovoltaic support.

Background

Photovoltaic power generation is widely applied and rapidly developed as an environment-friendly renewable energy form. Among them, the dual-glass single-crystal photovoltaic module is a high-efficiency and durable photovoltaic product, and has been popular in the market in recent years. The double-glass single crystal photovoltaic module takes two pieces of toughened glass as a cover plate and a back plate, clamps a single crystal silicon solar cell in the middle, and seals the single crystal silicon solar cell through a composite layer (such as polyvinyl butyral resin PVB) to form an integral structure. The design not only improves the light transmittance and the power generation efficiency of the photovoltaic module, but also enhances the weather resistance and the safety of the photovoltaic module.

The installation process of photovoltaic module is more complicated than traditional photovoltaic module, and whole mechanism frame is fixed, is difficult to adjust whole photovoltaic frame angle according to the user demand, and in the adjustment process, supports photovoltaic module's component adjustment and is difficult to smoothly cause the problem that photovoltaic board damaged easily.

Disclosure of utility model

The utility model aims to provide a double-glass single crystal photovoltaic bracket so as to solve the problems of angle adjustment and support in the prior art.

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

The double-glass single crystal photovoltaic bracket comprises a bottom plate and a bracket, wherein the tail end of the bottom plate is provided with a mounting lug, the mounting lug is hinged to the bracket, one side of the bottom plate is provided with a first side column, one side of the bracket is provided with a second side column, a hydraulic cylinder is movably connected to the first side column, a hydraulic rod is arranged in the hydraulic cylinder, the top end of the hydraulic rod is movably connected with the second side column, a clamping groove is formed in the upper portion of the bottom plate, clamping teeth are arranged in the clamping groove, an adjusting component matched with the clamping teeth is slidably mounted on the bottom plate, a sliding groove is formed in the bracket, and a mounting frame is mounted on the sliding groove.

Further, the adjusting component comprises a supporting block and a motor, a concave groove matched with the bottom plate is formed in the bottom of the supporting block, the motor is fixed to the side edge of the supporting block, an output shaft is mounted at the output end of the motor, a gear in the concave groove is mounted on the output shaft, and the gear is meshed with the clamping teeth.

Further, the top of supporting shoe is equipped with the hinge piece, rotate on the hinge piece and be connected with the gyro wheel, the gyro wheel contact is in the support below. The roller is introduced to enable the support block to slide on the bottom plate more smoothly. When the motor driving gear is meshed with the latch, and then the supporting block is driven to move, the rolling action of the roller can reduce the resistance in the moving process, so that the adjusting process is easier and more efficient.

Further, the bottom of support is equipped with the stable groove, and wherein gyro wheel sliding fit is in the stable inslot. The sliding fit of the roller in the stabilizing slot provides a well-defined path of travel for the carriage. The design not only limits the horizontal offset of the supporting block in the adjusting process, but also ensures that the roller always keeps stable contact with the bracket, thereby enhancing the supporting stability of the whole bracket.

Further, the bottom of mounting bracket is equipped with the lug, lug sliding fit is in the spout, oval groove has been seted up on the lug surface, a plurality of oval mouths have been seted up to the side of support.

Further, one end of the supporting block is provided with a notch, a bridging plate is arranged on the notch, and a thread groove is formed in the notch. The bridge plate is used for installing the supporting blocks at the other end of the linkage, only one motor is needed, the two supporting blocks can be synchronously driven and adjusted, and consumption materials of fewer devices are used. The bridging plate can be fixed by installing the installation nuts in the thread grooves.

The technical scheme of the utility model has the following beneficial effects:

1. The support block is used for being supported below the support so as to stabilize the installation position of the support, the support block is allowed to slide on the bottom plate by the design so as to dynamically adjust the support position below the support, when the angle of the support needs to be adjusted, the position of the support block is adjusted by starting the motor, the manual adjustment process is greatly simplified, the installation and adjustment efficiency and convenience are improved, and complex mechanical operation is not needed.

2. When the motor driving gear is meshed with the latch, and then the supporting block is driven to move, the rolling action of the roller can reduce the resistance in the moving process, so that the adjusting process is easier and more efficient. The roller can provide stable support through rolling contact, so that the adaptability and flexibility of the photovoltaic panel support system are enhanced, and the adjustment process is stabilized.

3. The supporting point below the bracket is stably supported on the supporting block, and the supporting block is matched with the hydraulic cylinder so as to bear the weight of the photovoltaic panel.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are required to be used in the description of the embodiments will be briefly described below.

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic cross-sectional structure of the present utility model.

Fig. 3 is an enlarged view of the utility model at a.

Fig. 4 is a cross-sectional view of a support block of the present utility model.

Fig. 5 is a schematic diagram of a split structure of the present utility model.

Reference numerals 10, bottom plate, 101, clamping groove, 102, mounting lug, 103, clamping tooth, 11, bracket, 111, sliding groove, 112, oval opening, 113, stabilizing groove, 12, first side column, 121, hydraulic cylinder, 122, hydraulic rod, 13, second side column, 14, supporting block, 141, motor, 142, concave groove, 143, output shaft, 144, gear, 145, hinge block, 146, roller, 147, notch, 148, bridging plate, 15, mounting frame, 16, bump, 17, oval groove.

Detailed Description

In order to make the objects, technical solutions and advantages of the present utility model more clear, the present utility model will be further described in detail with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiment one:

Referring to fig. 1 and 2, a dual-glass single-crystal photovoltaic bracket comprises a bottom plate 10 and a bracket 11, wherein the tail end of the bottom plate 10 is provided with a mounting lug 102, the mounting lug 102 is hinged with the bracket 11, one side of the bottom plate 10 is provided with a first side column 12, one side of the bracket 11 is provided with a second side column 13, the first side column 12 is movably connected with a hydraulic cylinder 121, a hydraulic rod 122 is arranged in the hydraulic cylinder 121, and the top end of the hydraulic rod 122 is movably connected with the second side column 13;

In the above-mentioned scheme, the bottom plate 10 is used for being fixed on the ground, the tail end of the bracket 11 is hinged with the mounting lug 102, so that the angle of the bracket 11 can be freely adjusted, and in combination with the hydraulic cylinder 121 and the hydraulic rod 122, the two ends of the hydraulic cylinder 121 and the hydraulic rod 122 are respectively movably connected to the first side column 12 and the second side column 13, so that when the bracket 11 is subjected to angle adjustment, the stroke of the hydraulic rod 122 is shortened or prolonged, so that the mounting angle of the bracket 11 can be conveniently adjusted, the bracket 11 is used for supporting the whole photovoltaic panel, and meanwhile, the angle adjustment is achieved.

Referring to fig. 2-4, a clamping groove 101 is formed above a base plate 10, clamping teeth 103 are arranged in the clamping groove 101, an adjusting component matched with the clamping teeth 103 is slidably arranged on the base plate 10, the adjusting component comprises a supporting block 14 and a motor 141, a concave groove 142 matched with the base plate 11 is formed in the bottom of the supporting block 14, the motor 141 is fixed on the side edge of the supporting block 14, an output shaft 143 is arranged at the output end of the motor 141, a gear 144 in the concave groove 142 is arranged on the output shaft 143, and the gear 144 is meshed with the clamping teeth 103.

In the above scheme, the installation of the photovoltaic panel provides downward pressure, the supporting point below the bracket 11 is stably supported on the supporting block 14, the supporting block 14 is matched with the hydraulic cylinder 121 to bear the weight of the photovoltaic panel, the motor 141 is started to enable the output shaft 143 to rotate, namely the gear 144 is matched with the latch 103, at the moment, the travel distance of the supporting block 14 can be changed, the supporting block 14 is used for supporting below the bracket 11, so that the installation position of the bracket 11 is stable, and the supporting block 14 is allowed to slide on the bottom plate 10 by the design, so that the supporting position below the bracket 11 is dynamically adjusted. The dynamic adjustment capability not only can finely adjust the stability and the installation position of the bracket 11 according to the requirement, but also can adapt to different terrains and installation conditions, when the angle of the bracket 11 needs to be adjusted, the position of the supporting block 14 is adjusted by starting the motor 141, the manual adjustment process is greatly simplified, the installation and adjustment efficiency and convenience are improved, and complicated mechanical operation is not required.

With further reference to fig. 3, a hinge block 145 is provided on top of the support block 14, and a roller 146 is rotatably connected to the hinge block 145, and the roller 146 is in contact with the lower portion of the bracket 11.

In the above scheme, the roller 146 is in direct friction contact with the lower part of the bracket 11, so that friction and abrasion between the roller and the bracket are greatly reduced. The design not only prolongs the service lives of the supporting blocks 14, the rollers 146 and the support 11, but also reduces noise and vibration generated by friction and improves the overall running stability of the photovoltaic panel system. The introduction of the rollers 146 allows the support blocks 14 to slide more smoothly on the base plate 10. When the motor 141 drives the gear 144 to engage with the latch 103, and further drives the supporting block 14 to move, the rolling action of the roller 146 can reduce the resistance in the moving process, so that the adjusting process is easier and more efficient. Whether a linear bracket or a bracket with a certain curvature, the rollers 146 can provide stable support through rolling contact, thereby enhancing the adaptability and flexibility of the photovoltaic panel bracket system.

With further reference to fig. 3 and 5, the bottom of the bracket 11 is provided with a stabilizing slot 113, wherein the roller 146 is a sliding fit within the stabilizing slot 113. The sliding fit of the roller 146 in the stabilizing channel 113 provides a well-defined path of movement for the carriage 11. This design not only limits the horizontal deflection of the support blocks 14 during adjustment, but also ensures that the rollers 146 remain in constant contact with the bracket 11, thereby enhancing the support stability of the entire bracket 11.

Referring to fig. 5, a chute 111 is provided in the bracket 11, and a mounting bracket 15 is mounted on the chute 111. The bottom of the mounting frame 15 is provided with a lug 16, the lug 16 is in sliding fit in the sliding groove 111, the surface of the lug 16 is provided with an elliptical groove 17, and the side surface of the bracket 11 is provided with a plurality of elliptical openings 112.

In the above-mentioned scheme, the mounting frame 15 is used for placing and supporting the photovoltaic panel, the mounting frame 15 is slidably mounted in the chute 111 through the projection 16, and then the bolts are inserted into the two of the elliptical opening 112 and the elliptical groove 17 under the cooperation of the two to position the mounting frame 15. The position of the mounting frame 15 can be freely adjusted to facilitate placement and installation of the photovoltaic panel. The installation steps are simplified, the installation efficiency is improved, and the installation cost is reduced.

Further, a notch 147 is formed at one end of the supporting block 14, and a bridging plate 148 is mounted on the notch 147, wherein a thread groove is formed on the notch 147. The bridge plate 148 is used for installing the supporting blocks 14 at the other end of the linkage, only one motor 141 is needed, and the two supporting blocks 14 can be synchronously driven and adjusted, so that the consumption of less equipment is reduced. The bridge plate 148 is secured by installing a mounting nut in the threaded groove.

The specific implementation process of this embodiment is as follows:

the motor 141 is started to enable the output shaft 143 to rotate, that is, the gear 144 is matched with the latch 103, at this time, the travel distance of the supporting block 14 can be changed, and the roller 146 contacts below the bracket 11, so that the resistance in the moving process can be reduced, and the adjusting process is easier and more efficient.

The mounting 15 is slidably mounted in the slide groove 111 by means of the projection 16, and then bolts are inserted into both of them with the fit of the elliptical opening 112 and the elliptical groove 17 to thereby position the mounting 15. The position of the mounting frame 15 can be freely adjusted to facilitate placement and installation of the photovoltaic panel.

The above embodiments are only exemplary embodiments of the present utility model and are not intended to limit the present utility model, the scope of which is defined by the claims. Various modifications and equivalent substitutions may be made to the present utility model within the spirit and scope of the present utility model. Such modifications and equivalents are considered to fall within the scope of the utility model.

In the description of the present utility model, it should be noted that, the terms "inner", "front", "rear", "left", "right", and the like indicate an azimuth or a positional relationship based on the azimuth or the positional relationship shown in the attached circles, or the azimuth or the positional relationship in which the inventive product is conventionally put in use, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or element to be referred to must have a specific azimuth, be configured and operate in a specific azimuth. Therefore, these terms indicating an azimuth or a positional relationship are not to be construed as limiting the present utility model.

In the description of the present utility model, it is further explained that it is not explicitly stated or defined otherwise. The terms "disposed," "connected," and "connected" are to be construed broadly, and may refer to, for example, a fixed connection, a removable connection, or an integral connection between elements, or may refer to a mechanical connection, an electrical connection, or may be directly or indirectly connected through intermediaries. The specific meaning of these terms in the present utility model will be understood by those of ordinary skill in the art according to the specific circumstances.

Claims (6)

1. The double-glass single crystal photovoltaic bracket is characterized by comprising a bottom plate (10) and a bracket (11), wherein the tail end of the bottom plate (10) is provided with a mounting lug (102), the bracket (11) is hinged on the mounting lug (102), one side of the bottom plate (10) is provided with a first side column (12), one side of the bracket (11) is provided with a second side column (13), a hydraulic cylinder (121) is movably connected on the first side column (12), a hydraulic rod (122) is arranged in the hydraulic cylinder (121), and the top end of the hydraulic rod (122) is movably connected with the second side column (13);

A clamping groove (101) is formed in the upper portion of the bottom plate (10), clamping teeth (103) are arranged in the clamping groove (101), and an adjusting component matched with the clamping teeth (103) is slidably arranged on the bottom plate (10);

A sliding groove (111) is formed in the support (11), and a mounting frame (15) is mounted on the sliding groove (111).

2. The double-glass single-crystal photovoltaic bracket according to claim 1, wherein the adjusting component comprises a supporting block (14) and a motor (141), a concave groove (142) matched with the bottom plate (10) is formed in the bottom of the supporting block (14), the motor (141) is fixed on the side edge of the supporting block (14), an output shaft (143) is mounted on the output end of the motor (141), a gear (144) in the concave groove (142) is mounted on the output shaft (143), and the gear (144) is meshed with the clamping teeth (103).

3. The dual-glass single-crystal photovoltaic bracket according to claim 2, wherein a hinge block (145) is arranged at the top of the supporting block (14), a roller (146) is rotatably connected to the hinge block (145), and the roller (146) is contacted below the bracket (11).

4. A dual glass single crystal photovoltaic support according to claim 3, wherein the bottom of the support (11) is provided with a stabilizing groove (113), wherein the roller (146) is in sliding fit in the stabilizing groove (113).

5. The dual-glass single-crystal photovoltaic bracket according to claim 1, wherein the bottom of the mounting frame (15) is provided with a protruding block (16), the protruding block (16) is in sliding fit in the sliding groove (111), the surface of the protruding block (16) is provided with an elliptical groove (17), and the side surface of the bracket (11) is provided with a plurality of elliptical openings (112).

6. A dual-glass single-crystal photovoltaic bracket according to claim 3, wherein a notch (147) is arranged at one end of the supporting block (14), a bridging plate (148) is arranged on the notch (147), and a thread groove is arranged on the notch (147).