Elevator shaft enclosure panel mounting member
By designing a connector with ventilation gaps between the elevator shaft enclosure panels, the problems of environmentally unfriendly glass sealant and poor ventilation are solved, achieving efficient ventilation and physical drainage of the elevator shaft, and reducing construction costs and safety hazards.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- EILIAN (CHENGDU) TECH CO LTD
- Filing Date
- 2025-07-28
- Publication Date
- 2026-07-14
AI Technical Summary
The use of silicone sealant to seal the gaps in the glass curtain wall of elevator shafts in the current technology is not environmentally friendly, and the silicone sealant ages and cracks, leading to safety hazards and poor ventilation, especially affecting the safe operation of elevators in high-temperature environments.
The design employs connectors, leaving ventilation gaps between the wall panels. The wall panels are fixed by the upper and lower slots of the connectors, forming a ventilation gap of not less than 5mm, which allows the elevator shaft to connect with the outside world, avoids the use of silicone sealant, and utilizes the inclined design of the wall panels to achieve physical drainage.
It effectively solved the problem of high temperature inside the elevator shaft, reduced the amount of silicone sealant used, lowered construction costs, and improved the ventilation and safety of the elevator shaft.
Smart Images

Figure CN224495519U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of elevator installation technology, specifically relating to an elevator shaft enclosure wall panel installation component. Background Technology
[0002] Currently, some older residential communities or factories, due to their age, did not have elevators in their initial design, leading to inconvenience for residents going up and down stairs and moving goods. Since these older communities and factories did not consider reserving elevator shafts during the initial design, the installation of elevators has gradually become a demand. By designing (adding) elevators separately on the exterior of the building walls, the mobility needs of the elderly can be met, and the handling of goods can be facilitated. Conventional steel structure elevator shafts are transported to the site in the form of components for assembly. The elevator shaft mainly consists of a shaft frame composed of columns and beams, as well as enclosing wall panels. Depending on the required height of the elevator shaft, different height shaft frames need to be constructed. After the shaft frame is installed, enclosing wall panels (glass curtain walls) need to be added around the outside of the shaft frame to protect it from rainwater erosion.
[0003] Chinese patent document CN207686084U discloses an elevator shaft exterior wall glass installation structure, including a shaft frame and a glass wall installed on the outside of the shaft frame via a fixing structure. The glass wall is composed of at least two glass panels spliced together. The fixing structure includes a supporting beam and a pressure plate. The supporting beam is disposed in the gap between two adjacent glass panels and is fixedly connected to the shaft frame. The pressure plate is fixedly connected to the supporting beam and abuts against the outer surfaces of the two adjacent glass panels. This elevator shaft exterior wall glass installation structure is simple in structure and easy to install. The glass panels can be fixed to the outside of the shaft frame using the pressure plate. In this design, the glass panels do not require drilling, and each glass panel is supported by a supporting beam, increasing the stability of the installation structure.
[0004] In existing technologies, the gap between the upper and lower glass curtain walls needs to be sealed with silicone sealant. However, the amount of sealant used during installation is very large, and the sealant emits odors, making it environmentally unfriendly. Furthermore, the sealant ages and cracks after a few years, affecting the stability of the glass curtain wall. Rainwater can also seep into the elevator shaft, corroding and damaging electrical components and posing safety hazards. In addition, existing elevator shafts have poor ventilation, especially in hot summer conditions, leading to high internal temperatures and compromising the safe operation of the elevator. Utility Model Content
[0005] The purpose of this utility model is to provide an elevator shaft enclosure wall panel installation component to solve the above-mentioned problems existing in the prior art.
[0006] To achieve the above objectives, the present invention adopts the following technical solution: an elevator shaft enclosure wall panel installation component, including a connector, wherein the connector is disposed between the elevator shaft frame and the enclosure wall panel; the connector is provided with an upper slot and a lower slot, wherein the bottom of the enclosure wall panel located above the connector is engaged in the upper slot, and the top of the enclosure wall panel located below the connector is engaged in the lower slot, and there is an overlapping area between the enclosure wall panel above the connector and the enclosure wall panel below the connector, wherein the overlapping area has a ventilation gap, and the ventilation gap is used to connect the interior of the elevator shaft with the outside.
[0007] As an optional implementation of the above technical solution, the upper and lower slots are staggered, the enclosure wall panel is inclined between the two connectors, and the top of the enclosure wall panel is locked in the lower slot of one of the connectors, while the bottom of the enclosure wall panel is locked in the upper slot of the other connector.
[0008] As an optional embodiment of the above technical solution, the connector includes a connecting part and a partition plate. The connecting part is connected to the shaft frame, and the partition plate is connected to the connecting part. A first locking plate and a second locking plate are respectively provided on both sides of the partition plate. The upper locking groove is formed between the first locking plate and the partition plate, and the lower locking groove is formed between the second locking plate and the partition plate.
[0009] As an optional implementation of the above technical solution, the connecting part includes a first connecting plate and a second connecting plate, which are detachably connected by a connecting structure. The first connecting plate or the second connecting plate is connected to the shaft frame, the partition plate is connected to the first connecting plate, and the second clamping plate is connected to the second connecting plate.
[0010] As an optional implementation of the above technical solution, the first card plate is L-shaped, and the first card plate, the partition plate and the first connecting plate are integrally formed.
[0011] As an optional implementation of the above technical solution, the second card plate is straight, and the second card plate and the second connecting plate are integrally formed or welded together.
[0012] As an optional implementation of the above technical solution, the connection structure includes a connecting bolt and a connecting nut, wherein the connecting bolt passes through the first connecting plate and the second connecting plate and is connected to the connecting nut.
[0013] As an optional implementation of the above technical solution, one end of the second connecting plate abuts against the partition plate, and the other end of the second connecting plate extends to the outside of the first connecting plate and is fixed to the shaft frame by welding or bolts.
[0014] As an optional implementation of the above technical solution, the ventilation gap is not less than 5mm.
[0015] As an optional implementation of the above technical solution, the enclosure wall panel is tempered glass or decorative panel.
[0016] The beneficial effects of this utility model are as follows:
[0017] This utility model provides an elevator shaft enclosure wall panel installation component. A ventilation gap is formed between the middle of the upper enclosure wall panel and the middle of the lower enclosure wall panel. The ventilation gap allows the interior of the elevator shaft to communicate with the outside, enabling the exhaust of hot air from inside the elevator shaft and effectively solving the problem of high temperature inside the elevator shaft. In addition, no sealant is needed between the upper and lower enclosure wall panels, reducing the amount of silicone sealant used, reducing the number of elevator shaft construction steps, and effectively reducing the cost of elevator installation. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the connector structure in one embodiment of the present invention;
[0019] Figure 2 This is a schematic diagram of the installation of the connector in one embodiment of the present invention;
[0020] Figure 3 This is a schematic diagram of the installation of the enclosure wall panel in one embodiment of this utility model;
[0021] Figure 4 This is a diagram showing the stacked state of the upper and lower enclosure wall panels in one embodiment of this utility model.
[0022] In the diagram: 1-Connector; 2-Hydraulic frame; 3-Enclosure wall panel; 4-Column; 5-Upper slot; 6-Lower slot; 7-Ventilation gap; 8-Separator plate; 9-First card plate; 10-Second card plate; 11-First connecting plate; 12-Second connecting plate; 13-Connecting bolt; 14-Connecting nut. Detailed Implementation
[0023] like Figures 1-4 As shown, this embodiment provides an elevator shaft enclosure wall panel installation component, including a connector 1, such as... Figure 2 As shown, the connector 1 is disposed between the elevator shaft frame 2 and the enclosure wall panel 3. The connector 1 is fixedly mounted on the column 4 of the shaft frame 2 to fix the enclosure wall panel 3 to the outside of the shaft frame 2. The enclosure wall panel 3 is usually made of tempered glass, but decorative panels or other materials can also be used.
[0024] like Figure 1As shown, the connector 1 has an upper slot 5 and a lower slot 6. The bottom of the enclosure wall panel 3 located above the connector 1 is engaged in the upper slot 5, and the top of the enclosure wall panel 3 located below the connector 1 is engaged in the lower slot 6. There is an overlapping area between the upper and lower enclosure wall panels 3 of the connector 1, and a ventilation gap 7 is provided in the overlapping area to allow communication between the elevator shaft interior and the outside. To improve ventilation, the ventilation gap 7 is not less than 5mm.
[0025] The upper enclosure wall panel 3 above connector 1 is the upper enclosure wall panel, and the lower enclosure wall panel 3 below connector 1 is the lower enclosure wall panel. The bottom ends of the upper enclosure wall panel are fixed in two upper slots 5 of the same height, with the bottom center of the upper enclosure wall panel 3 suspended. The top ends of the lower enclosure wall panel are fixed in two lower slots 6 of the same height, with the top center of the lower enclosure wall panel 3 suspended, creating an overlapping area between the middle of the upper and lower enclosure wall panels. A ventilation gap 7 is left between the middle of the upper and lower enclosure wall panels, allowing hot air from inside the elevator shaft to escape, effectively solving the high temperature problem inside the elevator shaft. Furthermore, no sealant is needed between the upper and lower enclosure wall panels, reducing the amount of silicone sealant used, simplifying elevator shaft construction procedures, and effectively lowering the elevator installation cost.
[0026] like Figure 3 As shown, to facilitate drainage in the elevator, the upper slot 5 and lower slot 6 are staggered. The enclosure wall panel 3 is inclined between the two connectors 1, with the top of the enclosure wall panel 3 locked in the lower slot 6 of one connector 1 and the bottom of the enclosure wall panel 3 locked in the upper slot 5 of the other connector 1. Each enclosure wall panel 3 is inclined outward, with the middle of the upper enclosure wall panel overlapping the outside of the lower enclosure wall panel to guide water flow outward. The lower and upper enclosure wall panels of this utility model are stacked sequentially to achieve the function of physical drainage in the elevator.
[0027] In this embodiment, the connector 1 includes a connecting part and a partition plate 8. The connecting part is connected to the shaft frame 2, and the partition plate 8 is connected to the connecting part. A first locking plate 9 and a second locking plate 10 are respectively provided on both sides of the partition plate 8. The upper locking groove 5 is formed between the first locking plate 9 and the partition plate 8, and the lower locking groove 6 is formed between the second locking plate 10 and the partition plate 8.
[0028] Specifically, the connecting part includes a first connecting plate 11 and a second connecting plate 12. The first connecting plate 11 and the second connecting plate 12 are detachably connected by a connecting structure. The first connecting plate 11 or the second connecting plate 12 is connected to the shaft frame 2. The partition plate 8 is connected to the first connecting plate 11, and the second clamping plate 10 is connected to the second connecting plate 12. The first connecting plate 11 or the second connecting plate 12 can be fixed to the shaft frame 2 by welding or bolts. The detachable connection of the first connecting plate 11 and the second connecting plate 12 facilitates the installation of the enclosure wall panel 3. Preferably, one end of the second connecting plate 12 abuts against the partition plate 8, and the other end of the second connecting plate 12 extends to the outside of the first connecting plate 11 and is fixed to the column 4 of the shaft frame 2 by welding or bolts.
[0029] like Figure 1 As shown, the first card plate 9 is L-shaped, and the first card plate 9, the partition plate 8, and the first connecting plate 11 are integrally formed. The first card plate 9 and the partition plate 8 form a U-shaped upper card slot 5, and the partition plate 8 is perpendicular to the first connecting plate 11. The second card plate 10 is straight, and the second card plate 10 and the second connecting plate 12 are integrally formed or welded together. The second card plate 10 and the second connecting plate 12 form a T-shaped structure, and the second card plate 10, the second connecting plate 12, and the partition plate 8 form a U-shaped lower card slot 6.
[0030] like Figure 3 As shown, in one specific embodiment, the connection structure includes a connecting bolt 13 and a connecting nut 14. The connecting bolt 13 passes through the first connecting plate 11 and the second connecting plate 12 and is connected to the connecting nut 14. Both the first connecting plate 11 and the second connecting plate 12 are provided with through holes. By using the connecting bolt 13 to pass through the through holes of the first connecting plate 11 and the second connecting plate 12 and connect to the connecting nut 14, the first connecting plate 11 and the second connecting plate 12 are fixed.
[0031] This utility model adopts the above-mentioned technical solution, which eliminates the need for sealant in the horizontal gap of tempered glass installation, thus solving the problem of sealant application in the horizontal gap of tempered glass installation. Moreover, each tempered glass has an angle, and the upper and lower tempered glass layers are stacked sequentially to achieve physical drainage. The ventilation gap 7 formed between the upper and lower tempered glass layers is not less than 5mm. This ventilation gap 7 will increase the ventilation effect inside the elevator shaft and effectively solve the problem of high temperature inside the elevator shaft.
[0032] In this description of the utility model, the terms "installation," "connection," "linking," and "fixing," etc., should be interpreted broadly. They can refer to fixed connections, detachable connections, or integral connections; they can refer to mechanical or electrical connections; they can refer to direct connections or indirect connections through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art will understand the specific meanings of these terms in this utility model. Furthermore, the specific features and structures described in the embodiments are included in at least one implementation method. Those skilled in the art can combine features from different implementation methods without contradiction. The scope of protection of this utility model is not limited to the specific implementation methods described above. Based on the basic technical concept of this utility model, implementation methods that can be conceived by those skilled in the art without creative effort are all within the scope of protection of this utility model.
Claims
1. A component for installing an elevator shaft enclosure wall panel, characterized in that, Includes a connector (1), which is disposed between the shaft frame (2) and the enclosure wall panel (3) of the elevator shaft; the connector (1) is provided with an upper slot (5) and a lower slot (6), which are staggered along the thickness direction of the wall panel and configured to form an overlapping area between the bottom of the enclosure wall panel (3) above the connector (1) and the upper part of the enclosure wall panel (3) below the connector (1) after installation in the installation state, and to form a ventilation gap (7) in the overlapping area.
2. The elevator shaft enclosure wall panel installation component according to claim 1, characterized in that, The connector (1) includes a connecting part and a partition plate (8). The partition plate (8) is connected to the connecting part. A first card plate (9) and a second card plate (10) are respectively provided on both sides of the partition plate (8). The upper card groove (5) is formed between the first card plate (9) and the partition plate (8), and the lower card groove (6) is formed between the second card plate (10) and the partition plate (8).
3. The elevator shaft enclosure wall panel installation component according to claim 2, characterized in that, The connecting part includes a first connecting plate (11) and a second connecting plate (12). The first connecting plate (11) and the second connecting plate (12) are detachably connected by a connecting structure. The partition plate (8) is connected to the first connecting plate (11), and the second clamping plate (10) is connected to the second connecting plate (12).
4. The elevator shaft enclosure wall panel installation component according to claim 3, characterized in that, The first card plate (9) is L-shaped, and the first card plate (9), the partition plate (8) and the first connecting plate (11) are integrally formed.
5. The elevator shaft enclosure wall panel installation component according to claim 3, characterized in that, The second card plate (10) is straight, and the second card plate (10) and the second connecting plate (12) are integrally formed or welded together.
6. The elevator shaft enclosure wall panel installation component according to claim 3, characterized in that, The connection structure includes a connecting bolt (13) and a connecting nut (14). The connecting bolt (13) passes through the first connecting plate (11) and the second connecting plate (12) and is connected to the connecting nut (14).
7. The elevator shaft enclosure wall panel installation component according to claim 1, characterized in that, The bottom of the enclosure wall panel (3) located above the connector (1) is locked in the upper slot (5), and the top of the enclosure wall panel (3) located below the connector (1) is locked in the lower slot (6).
8. The elevator shaft enclosure wall panel installation component according to claim 7, characterized in that, The enclosure wall panel (3) is inclined between the two connectors (1).
9. The elevator shaft enclosure wall panel installation component according to claim 1, characterized in that, The ventilation gap (7) shall not be less than 5 mm.
10. The elevator shaft enclosure wall panel installation component according to claim 1, characterized in that, The enclosure wall panel (3) is made of tempered glass or decorative panel.