A guard rail frame for a power-generating glass installation
By designing the inclined section and installation cavity of the guardrail frame, the problem of mismatch between the position and orientation of the power generation glass during installation was solved, which improved the power generation efficiency and facilitated maintenance, thus achieving the dual effect of protection and power generation of the guardrail.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 中晖建润(重庆)科技有限公司
- Filing Date
- 2025-06-30
- Publication Date
- 2026-06-26
AI Technical Summary
The existing guardrails are misaligned in position and orientation during the installation of the power generation glass, affecting power generation efficiency and failing to consider long-term maintenance needs.
Design a guardrail frame including mounting posts and connectors. By setting the obtuse angle of the inclined section and designing the mounting cavity, ensure that the power-generating glass is laid at the optimal lighting angle, and fix it with connectors to provide stable installation and convenient maintenance.
Improve the power generation efficiency of the power-generating glass, reduce shading, achieve the dual functions of protection and high-efficiency power generation of the railing, and facilitate long-term maintenance.
Smart Images

Figure CN224413328U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of glass guardrail technology, specifically relating to a guardrail frame for installing power generation glass. Background Technology
[0002] Photovoltaic glass, also known as solar cell glass, is a special type of glass that integrates solar cell technology. Its specific structure uses glass as a substrate, covered with a TCO transparent conductive film to allow light to pass through and conduct current. After passing through a window layer and an absorption layer, the internal structure is sealed and protected by a back panel. Current is collected and output through electrical connectors contained in the junction box. The generated direct current can be converted into alternating current by an inverter for use in homes or commercial facilities.
[0003] Due to the characteristics of power-generating glass, it is mostly installed at an angle to match the optimal angle of sunlight intake, reduce shading, and improve power generation efficiency. Existing guardrails primarily serve a protective function, and their location and orientation do not take into account the installation of power-generating glass, nor do they consider the long-term maintenance needs of the glass. Utility Model Content
[0004] In view of the problems mentioned in the background art above, the present invention provides a guardrail frame for the installation of power generation glass.
[0005] The technical solution adopted by this utility model is as follows: a guardrail frame for installing power-generating glass includes mounting posts, a plurality of mounting posts are equidistantly arranged, the bottom of the mounting posts are connected to the ground, and the mounting posts are integrally formed from bottom to top with a first vertical section, a first inclined section, a second inclined section and a second vertical section, wherein the first inclined section and the second inclined section are set at an obtuse angle between the first vertical section and the second vertical section; an installation cavity is opened on the second inclined section, the installation cavity is used to install power-generating glass between two adjacent mounting posts, and the power-generating glass is locked by a connector.
[0006] Furthermore, the connector includes a connecting block and connecting bolts. One end of the mounting cavity passes through the mounting column. Bolt holes are provided on both sides of the end of the mounting cavity on the second inclined section. The connecting block is connected to the second inclined section through the connecting bolts and seals the end of the mounting cavity. The end of the connecting block abuts against the bottom of the power generation glass.
[0007] Furthermore, a wire passage cavity communicating with the mounting cavity is provided on the first inclined section, and a wire passage hole is provided at the end of the wire passage cavity, which is used to connect the wire passage cylinder.
[0008] Furthermore, an inspection plate is inserted into the cable cavity.
[0009] Furthermore, a connecting beam is provided below the cable tray, and both ends of the connecting beam are fixed to the mounting column by bolts.
[0010] Furthermore, a rubber gasket is provided inside the mounting cavity.
[0011] Furthermore, the second vertical segment is located inside the first vertical segment.
[0012] Furthermore, handrails are provided between two adjacent second vertical segments.
[0013] The beneficial effects of this utility model are:
[0014] By setting the first and second inclined sections of the mounting post at obtuse angles, the power-generating glass can be laid at the angle to receive sunlight, serving as a guardrail while improving its power generation efficiency. Secondly, the second inclined section has an installation cavity for fixing the power-generating glass, and the glass is locked in place using connectors. This ensures the safe and stable installation of the power-generating glass and facilitates maintenance during long-term use. The overall design effectively solves the problem of mismatch between the guardrail position and orientation and the installation requirements of the power-generating glass in the existing technology. It takes into account the optimal light intake angle of the power-generating glass and the need to reduce shadow shading, achieving the dual purpose of guardrail protection and efficient power generation. Attached Figure Description
[0015] This utility model can be further illustrated by the non-limiting embodiments given in the accompanying drawings;
[0016] Figure 1 This is a schematic diagram of the inner side of the guardrail frame of this utility model;
[0017] Figure 2 This is a schematic diagram of the outer side of the guardrail frame of this utility model;
[0018] Figure 3 This is a schematic diagram of the explosion of the column of this utility model;
[0019] The attached diagram is labeled as follows:
[0020] Mounting column 1, first vertical section 11, first inclined section 12, second inclined section 13, bolt hole 131, second vertical section 14, handrail 15, mounting cavity 2, connecting block 21, connecting bolt 22, rubber gasket 23, wire passage cavity 3, wire passage through hole 31, wire passage cylinder 32, inspection plate 33, connecting beam 4, power generation glass 5. Detailed Implementation
[0021] like Figures 1-3As shown, a guardrail frame for installing power-generating glass includes mounting posts 1, a plurality of mounting posts 1 are equidistantly arranged, the bottom of the mounting posts 1 is connected to the ground, and each mounting post 1 is integrally formed from bottom to top with a first vertical section 11, a first inclined section 12, a second inclined section 13 and a second vertical section 14, wherein the first inclined section 12 and the second inclined section 13 are set at an obtuse angle between the first vertical section 11 and the second vertical section 14; the second inclined section 13 has a mounting cavity 2, the mounting cavity 2 is used to install power-generating glass 5 between two adjacent mounting posts 1, and the power-generating glass 5 is locked by a connector.
[0022] By adopting the above technical solution, the obtuse angle setting of the first inclined section 12 and the second inclined section 13 on the mounting column 1 ensures that the power generation glass 5 can be laid at the angle of receiving sunlight, thereby improving its power generation efficiency. Secondly, the second inclined section 13 is provided with a mounting cavity 2 for fixing the power generation glass 5, and the power generation glass 5 is locked with connectors. This not only ensures the safe and stable installation of the power generation glass 5, but also facilitates maintenance needs during long-term use. The overall design effectively solves the problem of the mismatch between the position and orientation of the guardrail and the installation requirements of the power generation glass 5 in the prior art. It takes into account the optimal light intake angle of the power generation glass 5 and the need to reduce shadow shading, thus achieving the dual purpose of guardrail protection and efficient power generation.
[0023] As a preferred embodiment, the connector includes a connecting block 21 and connecting bolts 22. One end of the mounting cavity 2 penetrates the mounting post 1. Bolt holes 131 are provided on both sides of the end of the mounting cavity 2 on the second inclined section 13. The connecting block 21 is connected to the second inclined section 13 via the connecting bolts 22 and seals the end of the mounting cavity 2. The end of the connecting block 21 abuts against the bottom of the power-generating glass 5. During installation, the power-generating glass 5 slides into the mounting cavity 2 from the side penetrating the mounting post 1. The connecting block 21 and connecting bolts 22 support the power-generating glass 5 to prevent it from falling out. Simultaneously, the overall installation and disassembly are convenient, facilitating inspection and maintenance.
[0024] As a preferred embodiment, the first inclined section 12 is provided with a wire-passing cavity 3 communicating with the mounting cavity 2. A wire-passing hole 31 is provided at the end of the wire-passing cavity 3, which is used to connect the wire-passing tube 32. The wire-passing hole 31 and the wire-passing tube 32 facilitate the routing of wires in the power generation glass 5 and the installation of electrical components.
[0025] As a preferred embodiment, the cable passage cavity 3 is fitted with an inspection plate 33. The inspection plate 33 allows for easy removal during maintenance and inspection to check for wiring problems.
[0026] As a preferred embodiment, a connecting beam 4 is provided below the cable tray 32, and both ends of the connecting beam 4 are fixed to the mounting posts 1 by bolts. The connecting beam 4 improves the connection stability of the overall guardrail frame.
[0027] As a preferred embodiment, a rubber gasket 23 is provided inside the mounting cavity 2. The rubber gasket 23 increases friction and provides a certain degree of shock absorption and protection for the power generation glass 5, thereby extending its service life.
[0028] As a preferred embodiment, the second vertical segment 14 is located inside the first vertical segment 11. This reduces pedestrian risk and lowers the probability of accidental climbing. The boundary is based on the second vertical segment 14 and is closer to the inside.
[0029] As a preferred embodiment, a handrail 15 is provided between two adjacent second vertical segments 14. The handrail 15 further enhances safety.
[0030] The present invention has been described in detail above. The specific embodiments are provided only to help understand the method and core idea of the present invention. It should be noted that those skilled in the art can make various improvements and modifications to the present invention without departing from its principles, and these improvements and modifications also fall within the protection scope of the claims of the present invention.
Claims
1. A guardrail frame for installing power-generating glass, characterized in that: include Mounting column (1), a plurality of mounting columns (1) are equidistantly arranged, the bottom of the mounting column (1) is connected to the ground, the mounting column (1) is integrally formed from bottom to top with a first vertical section (11), a first inclined section (12), a second inclined section (13) and a second vertical section (14), wherein the first inclined section (12) and the second inclined section (13) are set at an obtuse angle between the first vertical section (11) and the second vertical section (14); The second inclined section (13) is provided with an installation cavity (2), which is used to install a power generation glass (5) between two adjacent installation columns (1), and the power generation glass (5) is locked by a connector.
2. The guardrail frame for installing power-generating glass according to claim 1, characterized in that: The connector includes a connecting block (21) and a connecting bolt (22). One end of the mounting cavity (2) passes through the mounting post (1). The second inclined section (13) has bolt holes (131) located on both sides of the end of the mounting cavity (2). The connecting block (21) is connected to the second inclined section (13) through the connecting bolt (22) and seals the end of the mounting cavity (2). The end of the connecting block (21) abuts against the bottom of the power generation glass (5).
3. A guardrail frame for installing power-generating glass according to claim 2, characterized in that: The first inclined section (12) has a wire passage cavity (3) that communicates with the mounting cavity (2). The end of the wire passage cavity (3) has a wire passage hole (31) for connecting the wire passage cylinder (32).
4. A guardrail frame for installing power-generating glass according to claim 3, characterized in that: An inspection plate (33) is inserted into the wire passage cavity (3).
5. A guardrail frame for installing power-generating glass according to claim 3, characterized in that: A connecting beam (4) is provided below the cable tray (32), and the two ends of the connecting beam (4) are fixed to the mounting column (1) by bolts.
6. A guardrail frame for installing power-generating glass according to claim 1, characterized in that: A rubber gasket (23) is provided inside the mounting cavity (2).
7. A guardrail frame for installing power-generating glass according to claim 1, characterized in that: The second vertical segment (14) is located inside the first vertical segment (11).
8. A guardrail frame for installing power-generating glass according to claim 1, characterized in that: A handrail (15) is provided between two adjacent second vertical segments (14).