Connecting mechanism of color steel plate wall body in clean room
By using a connection mechanism consisting of galvanized square tubes, steel plates, and bolts in the cleanroom, the problems of inconvenient installation and time-consuming disassembly of color steel plates are solved, thereby improving the airtightness and work efficiency of the cleanroom.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ELKO CONSTR ENG (JIANGSU) CO LTD
- Filing Date
- 2025-06-18
- Publication Date
- 2026-06-30
AI Technical Summary
The installation of existing color steel panels in cleanrooms is inconvenient, disassembly is time-consuming and labor-intensive, and the airtightness is poor, which affects the cleanliness.
The system employs a connection mechanism consisting of a first galvanized square tube, a second galvanized square tube, a steel plate, bolts, and aluminum edge trimming grooves. Through welding and bolting, the stability and strength of the color steel plate are enhanced, and the installation and disassembly process is simplified.
It achieves stability and robustness of color steel panels, simplifies the installation and disassembly process, and improves work efficiency.
Smart Images

Figure CN224431705U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the technical field of color steel plate wall installation, and more specifically, relates to a connection mechanism for color steel plate walls in clean rooms. Background Technology
[0002] A cleanroom is a dust-free room or clean workshop built within a building in accordance with various standards of the cleanroom industry. A cleanroom is a closed space where airborne particles, harmful gases, bacteria, and other contaminants are eliminated. The temperature, cleanliness, pressure, airflow speed and distribution, noise and vibration, lighting, and static electricity within the cleanroom are controlled within a specific range according to relevant industry standards. In other words, regardless of changes in the external air, the cleanroom can maintain the originally set requirements for cleanliness, temperature, humidity, and pressure.
[0003] In cleanrooms, color steel panels are mostly used for the walls. To ensure the overall strength of the color steel panel connections, the traditional method for installing color steel panels in cleanrooms is to start from the base point, install one color steel panel, insert a central aluminum strip, and then install the next panel, and so on. Every two color steel panels are fixedly connected by the central aluminum strip.
[0004] However, in existing technologies, some large warehouses or large cleanrooms that require a high degree of cleanliness need a large clean space to meet process requirements. Therefore, higher walls are needed to support the building structure. However, in existing technologies, most of them are fixedly connected by two color steel plates with aluminum foil. However, the color steel plates installed in this way are not only inconvenient to install, but also difficult to disassemble, which is time-consuming and labor-intensive and affects the installation efficiency. At the same time, there may also be poor airtightness, which affects the cleanliness of the cleanroom. Utility Model Content
[0005] Therefore, in order to solve the above-mentioned technical problems, this utility model proposes a connection mechanism for a color steel plate wall in a clean room, including a clean room, wherein the clean room is provided with a plurality of upper color steel plates 10 and a plurality of lower color steel plates 20, and the wall composed of the upper color steel plates 10 and the lower color steel plates 20 divides the clean room into a plurality of cleanliness zones, and a corridor formed by the upper color steel plates 10, the lower color steel plates 20 and one side of the clean room. The clean room is provided with a plurality of connection mechanisms 30 for fixing the upper color steel plates 10, and the connection mechanism 30 includes a first galvanized square tube 301, a second galvanized square tube 302, a steel plate 303, bolts 304, and edge-trimming aluminum grooves 305. The steel plate 303 is connected to a crossbeam by the bolts 304. The upper side of the first galvanized square tube 301 is welded to the steel plate 303. The upper and lower ends of the upper color steel plate 10 are both snapped together with the edge-trimming aluminum 305. The other side of the upper part of the first galvanized square tube 301 is connected to the edge-trimming aluminum 305 by bolts 304. The lower part of the first galvanized square tube 301, near the upper color steel plate 10, is welded to the second galvanized square tube 302. The edge-trimming aluminum 305 at the bottom of the upper color steel plate 10 is connected to the top of the second galvanized square tube 302 by bolts 304, and also to the lower part of the first galvanized square tube 301 by bolts 304. This makes the upper color steel plate 10 structurally stable, less prone to falling off, and easier to install or disassemble, thus improving work efficiency.
[0006] A connection mechanism for a color steel plate wall in a cleanroom includes a cleanroom with several upper color steel plates 10 and several lower color steel plates 20. A wall composed of the upper and lower color steel plates 10 divides the cleanroom into several cleanliness zones. A corridor is formed by the upper and lower color steel plates 10 and one side of the cleanroom. The cleanroom is equipped with several connection mechanisms 30 for fixing the upper color steel plates 10. Each connection mechanism 30 includes a first galvanized square tube 301, a second galvanized square tube 302, a steel plate 303, bolts 304, and edge-trimming aluminum grooves 305. The steel plate 303 is connected to a crossbeam via the bolts 304. The upper side of the first galvanized square tube 301 is welded to the steel plate 303. The upper and lower ends of the upper color steel plate 10 are both snapped together with the edge-receiving aluminum 305. The other side of the upper part of the first galvanized square tube 301 is connected to the edge-receiving aluminum 305 by bolts 304. The lower part of the first galvanized square tube 301, near the upper color steel plate 10, is welded to the second galvanized square tube 302. The edge-receiving aluminum 305 at the bottom of the upper color steel plate 10 is connected to the top of the second galvanized square tube 302 by bolts 304, and also to the lower part of the first galvanized square tube 301 by bolts 304, making the upper color steel plate 10 structurally stable and not easy to fall off.
[0007] Furthermore, a top rail 40 is connected to the top of the lower color steel plate 20, and a bottom rail 50 is connected to the bottom of the lower color steel plate 20. The top rail 40 is connected to the second galvanized square tube 302 by the bolts 304, and the bottom rail 50 is connected to the ground.
[0008] Furthermore, both the upper color steel plate 10 and the lower color steel plate 20 are made of metal rock wool wall panels.
[0009] Furthermore, the inner side of the edge-gathering groove aluminum 305 is symmetrically provided with protrusions 60, so that the upper color steel plate 10 is tightly engaged with the edge-gathering groove aluminum 305.
[0010] Furthermore, a third galvanized square tube 70 is provided at the weld joint between the first galvanized square tube 301 and the second galvanized square tube 302. One end of the third galvanized square tube 70 is welded to the first galvanized square tube 301, and the other end of the third galvanized square tube 70 is connected to one side wall of the clean room. The third galvanized square tube 70 is used to increase the lateral restraint force of the upper color steel plate 10, so that the connection between the upper color steel plate 10 and the first galvanized square tube 301 and the second galvanized square tube 302 is firm and stable.
[0011] Furthermore, a connecting plate 80 is provided at the connection between the third galvanized square tube 70 and the wall of the clean room. The connecting plate 80 is connected to the wall by the bolts 304. The third galvanized square tube 70 is welded to the connecting plate 80, which indirectly increases the contact area between the third galvanized square tube 70 and the wall of the clean room, making the third galvanized square tube 70 more secure and less likely to fall off.
[0012] Furthermore, the bolt 304 is an M10 chemical bolt 304, which has high connection strength and strong stability.
[0013] Furthermore, the first galvanized square tube 301 is evenly spaced along the beam direction, with one tube spaced every 2000mm-3000mm.
[0014] The beneficial effects of this utility model are as follows: This utility model proposes a connection mechanism for a color steel plate wall in a clean room, including a clean room. The clean room contains several upper color steel plates 10 and several lower color steel plates 20. A wall composed of the upper and lower color steel plates 10 divides the clean room into several cleanliness zones. A corridor is formed by the upper and lower color steel plates 10 and one side of the clean room. The clean room is equipped with several connection mechanisms 30 for fixing the upper color steel plates 10. Each connection mechanism 30 includes a first galvanized square tube 301, a second galvanized square tube 302, a steel plate 303, bolts 304, and edge-trimming aluminum grooves 305. The steel plate 303 is connected to a crossbeam via the bolts 304. The upper side of the first galvanized square tube 301 is welded to the steel plate 303. The upper and lower ends of the upper color steel plate 10 are both snapped together with the edge-trimming aluminum 305. The other side of the upper part of the first galvanized square tube 301 is connected to the edge-trimming aluminum 305 by bolts 304. The lower part of the first galvanized square tube 301, near the upper color steel plate 10, is welded to the second galvanized square tube 302. The edge-trimming aluminum 305 at the bottom of the upper color steel plate 10 is connected to the top of the second galvanized square tube 302 by bolts 304, and also to the lower part of the first galvanized square tube 301 by bolts 304. This makes the upper color steel plate 10 structurally stable, less prone to falling off, and easier to install or disassemble, thus improving work efficiency. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the connection mechanism for a cleanroom interior color steel plate wall according to the present invention.
[0016] Figure 2 This is a schematic diagram of the connection mechanism for a cleanroom interior color steel plate wall according to the present invention.
[0017] Figure 3 This is a partially enlarged view of the connection mechanism for a cleanroom interior color steel plate wall according to this utility model.
[0018] Figure 4 This is a partially enlarged view of the connection mechanism for a cleanroom interior color steel plate wall according to this utility model.
[0019] Figure 5 This is a partially enlarged view of the connection mechanism for a cleanroom interior color steel plate wall according to this utility model.
[0020] Figure 6 This is a partial structural schematic diagram of the connection mechanism for a cleanroom interior color steel plate wall according to this utility model.
[0021] Figure 7 This is a partial structural schematic diagram of the connection mechanism for a cleanroom interior color steel plate wall according to this utility model.
[0022] Explanation of key component symbols:
[0023] Upper color steel plate 10, lower color steel plate 20, connecting mechanism 30, first galvanized square tube 301, second galvanized square tube 302, steel plate 303, bolt 304, edge trimming aluminum 305, ceiling rail 40, floor rail 50, protrusion 60, third galvanized square tube 70, connecting plate 80.
[0024] The following detailed description, in conjunction with the accompanying drawings, will further illustrate this utility model. Detailed Implementation
[0025] The following embodiments are described to aid in understanding this application. These embodiments are not, and should not be, construed in any way as limiting the scope of protection of this application.
[0026] In the following description, those skilled in the art will recognize that throughout this discussion, components may be described as individual functional units (which may include subunits), but those skilled in the art will recognize that various components or portions thereof may be divided into individual components or may be integrated together (including integrated within a single system or component).
[0027] Furthermore, the connection between components or systems is not intended to be limited to a direct connection; on the contrary, data between these components may be modified, reformatted, or otherwise altered by intermediate components. Additionally, other or fewer connections may be used. It should also be noted that the terms "connection," "link," or "input" should be understood to include direct connections, indirect connections via one or more intermediate devices, and wireless connections. Example 1:
[0028] like Figure 1 The diagram shown is a structural schematic of the connection mechanism for a cleanroom color steel plate wall according to this utility model; as shown... Figure 2 The diagram shown is a structural schematic of the connection mechanism for a cleanroom color steel plate wall according to this utility model; as shown... Figure 3 The image shown is a partially enlarged view of the connection mechanism for a cleanroom interior color steel plate wall according to this utility model; as shown... Figure 4 The image shown is a partially enlarged view of the connection mechanism for a cleanroom interior color steel plate wall according to this utility model; as shown... Figure 5 The image shown is a partially enlarged view of the connection mechanism for a cleanroom interior color steel plate wall according to this utility model; as shown... Figure 6 The diagram shown is a partial structural schematic of the connection mechanism for a cleanroom color steel plate wall according to this utility model; as shown... Figure 7 The diagram shown is a partial structural schematic of the connection mechanism for a cleanroom color steel plate wall according to this utility model.
[0029] A connection mechanism for a color steel plate wall in a cleanroom includes a cleanroom with several upper color steel plates 10 and several lower color steel plates 20. A wall composed of the upper and lower color steel plates 10 divides the cleanroom into several cleanliness zones. A corridor is formed by the upper and lower color steel plates 10 and one side of the cleanroom. The cleanroom is equipped with several connection mechanisms 30 for fixing the upper color steel plates 10. Each connection mechanism 30 includes a first galvanized square tube 301, a second galvanized square tube 302, a steel plate 303, bolts 304, and edge-trimming aluminum grooves 305. The steel plate 303 is connected to a crossbeam via the bolts 304. The upper side of the first galvanized square tube 301 is welded to the steel plate 303. The upper and lower ends of the upper color steel plate 10 are both snapped together with the edge-receiving aluminum 305. The other side of the upper part of the first galvanized square tube 301 is connected to the edge-receiving aluminum 305 by bolts 304. The lower part of the first galvanized square tube 301, near the upper color steel plate 10, is welded to the second galvanized square tube 302. The edge-receiving aluminum 305 at the bottom of the upper color steel plate 10 is connected to the top of the second galvanized square tube 302 by bolts 304, and also to the lower part of the first galvanized square tube 301 by bolts 304, making the upper color steel plate 10 structurally stable and not easy to fall off.
[0030] The top of the lower color steel plate 20 is connected to a top rail 40, and the bottom of the lower color steel plate 20 is connected to a bottom rail 50. The top rail 40 is connected to the second galvanized square tube 302 by bolts 304, and the bottom rail 50 is connected to the ground.
[0031] Both the upper color steel plate 10 and the lower color steel plate 20 are made of metal rock wool wall panels.
[0032] The inner side of the edge-gathering groove aluminum 305 is symmetrically provided with protrusions 60, so that the upper color steel plate 10 is tightly engaged with the edge-gathering groove aluminum 305.
[0033] A third galvanized square tube 70 is provided at the welding point between the first galvanized square tube 301 and the second galvanized square tube 302. One end of the third galvanized square tube 70 is welded to the first galvanized square tube 301, and the other end of the third galvanized square tube 70 is connected to one side wall of the clean room. The third galvanized square tube 70 is used to increase the lateral restraint force of the upper color steel plate 10, so that the connection between the upper color steel plate 10 and the first galvanized square tube 301 and the second galvanized square tube 302 is firm and stable.
[0034] A connecting plate 80 is provided at the connection between the third galvanized square tube 70 and the wall of the clean room. The connecting plate 80 is connected to the wall by the bolts 304. The third galvanized square tube 70 is welded to the connecting plate 80, which indirectly increases the contact area between the third galvanized square tube 70 and the wall of the clean room, making the third galvanized square tube 70 more secure and less likely to fall off.
[0035] The bolt 304 is an M10 chemical bolt, which has high connection strength and strong stability.
[0036] The first galvanized square tube 301 is evenly spaced along the direction of the crossbeam, with one tube every 2000mm-3000mm.
[0037] The beneficial effects of this utility model are as follows: This utility model proposes a connection mechanism for a color steel plate wall in a clean room, including a clean room. The clean room contains several upper color steel plates 10 and several lower color steel plates 20. A wall composed of the upper and lower color steel plates 10 divides the clean room into several cleanliness zones. A corridor is formed by the upper and lower color steel plates 10 and one side of the clean room. The clean room is equipped with several connection mechanisms 30 for fixing the upper color steel plates 10. Each connection mechanism 30 includes a first galvanized square tube 301, a second galvanized square tube 302, a steel plate 303, bolts 304, and edge-trimming aluminum grooves 305. The steel plate 303 is connected to a crossbeam via the bolts 304. The upper side of the first galvanized square tube 301 is welded to the steel plate 303. The upper and lower ends of the upper color steel plate 10 are both snapped together with the edge-trimming aluminum 305. The other side of the upper part of the first galvanized square tube 301 is connected to the edge-trimming aluminum 305 by bolts 304. The lower part of the first galvanized square tube 301, near the upper color steel plate 10, is welded to the second galvanized square tube 302. The edge-trimming aluminum 305 at the bottom of the upper color steel plate 10 is connected to the top of the second galvanized square tube 302 by bolts 304, and also to the lower part of the first galvanized square tube 301 by bolts 304. This makes the upper color steel plate 10 structurally stable, less prone to falling off, and easier to install or disassemble, thus improving work efficiency.
[0038] The embodiments described above are merely illustrative of several implementations of this utility model, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of this utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.
Claims
1. A connection mechanism for a color steel plate wall in a clean room, comprising a clean room, wherein the clean room is provided with a plurality of upper color steel plates (10) and a plurality of lower color steel plates (20), a wall composed of the upper color steel plates (10) and the lower color steel plates (20) dividing the clean room into a plurality of cleanliness zones, and a corridor formed by the upper color steel plates (10), the lower color steel plates (20) and one side of the clean room, characterized in that: The cleanroom is equipped with several connecting mechanisms (30) for fixing the upper color steel plate (10). The connecting mechanism (30) includes a first galvanized square tube (301), a second galvanized square tube (302), a steel plate (303), bolts (304), and edge-trimming aluminum (305). The steel plate (303) is connected to the crossbeam by the bolts (304). The upper side of the first galvanized square tube (301) is welded to the steel plate (303). The upper and lower ends of the upper color steel plate (10) are both snapped into the edge-trimming aluminum (305). (301) The other side of the upper part is connected to the edge-receiving aluminum (305) by the bolt (304). The lower part of the first galvanized square tube (301) is welded to the second galvanized square tube (302) on the side close to the upper color steel plate (10). The edge-receiving aluminum (305) at the bottom of the upper color steel plate (10) is connected to the top of the second galvanized square tube (302) by the bolt (304) and to the lower part of the first galvanized square tube (301) by the bolt (304), so that the upper color steel plate (10) is structurally stable and not easy to fall off.
2. The connection mechanism for the color steel plate wall of the clean room according to claim 1, characterized in that: The top of the lower color steel plate (20) is connected to a top rail (40), and the bottom of the lower color steel plate (20) is connected to a bottom rail (50). The top rail (40) is connected to the second galvanized square tube (302) by the bolt (304), and the bottom rail (50) is connected to the ground.
3. The connection mechanism for the cleanroom interior color steel plate wall according to claim 2, characterized in that: The upper color steel plate (10) and the lower color steel plate (20) are both made of metal rock wool wall panels.
4. The connection mechanism for the cleanroom interior color steel plate wall according to claim 3, characterized in that: The inner side of the edge-gathering groove aluminum (305) is symmetrically provided with protrusions (60), so that the upper color steel plate (10) and the edge-gathering groove aluminum (305) are tightly engaged.
5. The connection mechanism for the cleanroom interior color steel plate wall according to claim 4, characterized in that: A third galvanized square tube (70) is provided at the welding point between the first galvanized square tube (301) and the second galvanized square tube (302). One end of the third galvanized square tube (70) is welded to the first galvanized square tube (301), and the other end of the third galvanized square tube (70) is connected to one side wall of the clean room. The third galvanized square tube (70) is used to increase the lateral constraint force of the upper color steel plate (10), so that the connection between the upper color steel plate (10) and the first galvanized square tube (301) and the second galvanized square tube (302) is firm and stable.
6. The connection mechanism for the color steel plate wall of the clean room according to claim 5, characterized in that: A connecting plate (80) is provided at the connection between the third galvanized square tube (70) and the wall of the clean room. The connecting plate (80) is connected to the wall by the bolt (304). The third galvanized square tube (70) is welded to the connecting plate (80), which indirectly increases the contact area between the third galvanized square tube (70) and the wall of the clean room, making the third galvanized square tube (70) more secure and less likely to fall off.
7. The connection mechanism for the cleanroom interior color steel plate wall according to claim 1, characterized in that: The bolt (304) is an M10 chemical bolt (304), which has high connection strength and strong stability.
8. The connection mechanism for the cleanroom color steel plate wall according to claim 5, characterized in that: The first galvanized square tube (301) is evenly spaced along the direction of the crossbeam, with one tube every 2000mm-3000mm.