A gas film inflatable facility capable of withstanding high temperature

By designing heat dissipation windows, slopes, and through slots in the air-supported membrane inflation facility, and combining them with a cooling device, the high temperature problem caused by long-term operation of the air-supported membrane inflation facility was solved, achieving effective heat dissipation and corrosion prevention of the equipment and extending its service life.

CN224409238UActive Publication Date: 2026-06-26PEIS FILM IND (BEIJING) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
PEIS FILM IND (BEIJING) CO LTD
Filing Date
2025-07-01
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Air-supported membrane structures are prone to high temperatures during prolonged operation, which can affect their service life.

Method used

An air-supported membrane inflation device including a track and a mobile trolley was designed. The mobile trolley is equipped with heat dissipation windows, and the connecting plate is equipped with inclined surfaces and through slots. Combined with a cooling device such as dry ice, the inclined surfaces and through slots enable the effective discharge of hot air and water droplets, preventing the equipment from overheating and corroding.

Benefits of technology

It effectively reduces the internal temperature of the equipment, prevents overheating and corrosion, and extends the service life of the air-supported membrane inflation system.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to air film technical field especially relates to a high temperature air film inflation facility that bears. Adopt the following scheme: a high temperature air film inflation facility that bears, include, track and moving trolley, track includes spliced part and connecting plate, and the both ends of connecting plate are respectively inserted in spliced part, and connecting plate is suspended and sets up, and connecting plate is opened with a plurality of along its length direction equidistance arrangement's through groove, and the through groove is arranged along the connecting plate width direction, and the moving trolley is slidably arranged at the top of track, and the side portion of moving trolley is opened with the heat dissipation window, and the moving trolley is used for carrying the fan. The utility model provides a high temperature air film inflation facility that bears, solved the air film inflation structure long time work and led to the temperature to be too high and influence the service life's technical problem.
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Description

Technical Field

[0001] This utility model relates to the field of air membrane technology, and in particular to an air membrane inflation device that can withstand high temperatures. Background Technology

[0002] There are three types of air-supported membrane structures: single-layer, double-layer, and air-ribbed. Generally, air-supported membrane structures require continuous inflation over a long period of time.

[0003] Because of their large size, air-supported membrane structures are difficult to inflate. During inflation, the inflation equipment needs to work continuously, which can easily lead to high temperatures in the inflation equipment and affect the service life of the inflatable structure. Utility Model Content

[0004] This invention provides a high-temperature resistant air-supported membrane inflation device, which solves the technical problem that the air-supported membrane inflation structure will reach excessively high temperatures and affect its service life due to long-term operation.

[0005] To achieve this technical objective, the present invention adopts the following solution: a high-temperature resistant air-supported membrane inflation facility, comprising a track and a mobile trolley;

[0006] The track includes splicing components and connecting plates. The two ends of the connecting plate are respectively inserted into the splicing components. The connecting plate is suspended in the air. The connecting plate has multiple through slots that are evenly spaced along its length and arranged along the width of the connecting plate.

[0007] The mobile trolley is slidably mounted on top of the track, and has ventilation windows on its side. The mobile trolley is used to support the fan.

[0008] Furthermore, the bottom of the splice is fixed with two symmetrically arranged support feet, the side of the splice is provided with a slot for installing a connecting plate, the side of the splice is also provided with a slot, the slot is located above the slot, and the top of the splice is provided with a sliding groove.

[0009] Furthermore, the mobile trolley includes a base plate, side walls, and an arc-shaped top plate that are fixedly connected from bottom to top;

[0010] The bottom of the base plate is fixed with a slider that can slide in the groove, and the base plate has two symmetrical clearance grooves that extend along the width of the track.

[0011] The side wall is provided with heat dissipation windows, and the side wall is also provided with an air inlet pipe for connecting to the exhaust port of the fan. Connecting blocks are fixed on both opposite side walls.

[0012] The curved top plate bends upward, and has two symmetrically arranged receiving slots that extend along the width of the track.

[0013] Furthermore, the mobile trolley is equipped with two symmetrically arranged limiting mechanisms inside.

[0014] The limiting mechanism includes a drive rod, a connecting rod, a support rod, a plug rod, and a spring;

[0015] A support rod is rotatably connected to the middle of the drive rod. Both ends of the support rod are fixedly connected to the side wall. The upper part of the drive rod passes through the receiving groove. The upper parts of the two drive rods are connected by a connecting rod. The lower part of the drive rod passes through the clearance groove.

[0016] One end of the insertion rod is fixedly connected to the bottom of the drive rod, and the other end of the insertion rod is inserted into the slot, with the insertion rod abutting against the slot.

[0017] One end of the spring is fixedly connected to the upper part of the side of the drive rod, and the other end of the spring is fixedly connected to the connecting block.

[0018] Furthermore, the end of the insertion rod is provided with an anti-slip pad, which abuts against the slot.

[0019] Furthermore, the top surface of the connecting plate is provided with multiple inclined surfaces that are evenly distributed along its length, and the through groove is located at the bottom of the inclined surface.

[0020] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0021] This invention incorporates a heat dissipation window on the mobile trolley, allowing hot air to escape more easily and preventing excessive internal temperature. A cooling device (such as dry ice) can also be placed on the connecting plate to cool the bottom of the mobile trolley and consequently, the internal fan.

[0022] The connecting plate is equipped with an inclined surface and a through groove, which allows the small water droplets generated by the cooling device to flow down the inclined surface and then flow into the bottom of the connecting plate through the through groove, preventing the connecting plate from corroding and rusting. Attached Figure Description

[0023] Figure 1 A schematic diagram of a high-temperature resistant air-supported membrane inflation device provided for an embodiment of this utility model;

[0024] Figure 2 Right view of a high-temperature resistant air-supported membrane inflation device provided for an embodiment of this utility model:

[0025] Figure 3 This is another schematic diagram of a high-temperature resistant air-supported membrane inflation device provided for an embodiment of the present utility model.

[0026] Explanation of reference numerals in the attached figures:

[0027] 1. Track; 11. Assembly piece; 111. Support leg; 112. Slot; 113. Card slot; 114. Slide groove; 12. Connecting plate; 121. Through groove; 122. Inclined surface; 2. Moving trolley; 21. Heat dissipation window; 22. Base plate; 221. Slider; 222. Clearance groove; 23. Side wall; 231. Connecting block; 232. Inflation pipe; 24. Arc-shaped top plate; 241. Receiving groove; 3. Limiting mechanism; 31. Drive rod; 32. Connecting rod; 33. Support rod; 34. Insert rod; 35. Spring. Detailed Implementation

[0028] To fully understand the purpose, features and effects of this utility model, the following specific embodiments will be used to describe this utility model in detail, but this utility model is not limited thereto.

[0029] like Figures 1 to 3 As shown, this utility model provides a high-temperature resistant air-supported membrane inflation device, including a track 1 and a mobile trolley 2. The mobile trolley 2 is equipped with inflation equipment (such as a fan, not shown in the figure). The track 1 includes a splicing component 11 and a connecting plate 12. The two ends of the connecting plate 12 are respectively inserted into the splicing component 11, and the connecting plate 12 is suspended. The connecting plate 12 has a plurality of through slots 121 arranged at equal intervals along its length direction and along the width direction of the connecting plate 12.

[0030] As one embodiment of the splicing component 11, the bottom of the splicing component 11 is fixed with two symmetrically arranged support feet 111, the side of the splicing component 11 is provided with a slot 112 for installing the connecting plate 12, the side of the splicing component 11 is also provided with a slot 113, the slot 113 is provided above the slot 112, and the top of the splicing component 11 is provided with a sliding groove 114.

[0031] The mobile trolley 2 is slidably mounted on top of the track 1. A heat dissipation window 21 is provided on the side of the mobile trolley 2. The mobile trolley 2 is used to support the fan. The mobile trolley 2 includes a base plate 22, side walls 23, and an arc-shaped top plate 24, which are fixedly connected from bottom to top. A slider 221, which is slidably mounted in a slide groove 114, is fixed at the bottom of the base plate 22. The base plate 22 has two symmetrically arranged clearance grooves 222 extending along the width of the track 1. The side walls 23 have heat dissipation windows 21 and an air inlet pipe 232 for communicating with the fan's exhaust port. Connecting blocks 231 are fixed to both opposite side walls 23. The arc-shaped top plate 24 bends upward and has two symmetrically arranged receiving grooves 241 extending along the width of the track 1. The receiving grooves 241 correspond to the clearance grooves 222.

[0032] The mobile trolley 2 is equipped with two symmetrically arranged limiting mechanisms 3, which are used to fix the mobile trolley 2 to any position on the track 1. The limiting mechanism 3 includes a drive rod 31, a connecting rod 32, a support rod 33, an insert rod 34, and a spring 35. The support rod 33 is rotatably connected to the middle of the drive rod 31. Both ends of the support rod 33 are fixedly connected to the side wall 23. The upper part of the drive rod 31 passes through the receiving groove 241. The upper parts of two adjacent drive rods 31 are connected as one unit by the connecting rod 32. The lower part of the drive rod 31 passes through the clearance groove 222. One end of the insert rod 34 is fixedly connected to the bottom of the drive rod 31. The other end of the insert rod 34 is inserted into the slot 113 and abuts against the slot 113. One end of the spring 35 is fixedly connected to the upper part of the side of the drive rod 31. The other end of the spring 35 is fixedly connected to the connecting block 231.

[0033] The operating principle of the limiting mechanism 3 is as follows: Figure 3 As shown, when spring 35 is compressed, it presses the upper part of drive rod 31 against the middle of the moving trolley 2, causing insert rod 34 to press against slot 113, increasing the pressure between them and further increasing the friction between them. This fixes the moving trolley 2 on the track 1, preventing it from sliding. When the position of the moving trolley 2 needs to be adjusted, the operator needs to pull the connecting rod 32 to both sides, causing drive rod 31 to rotate about support rod 33. During this process, the top of drive rod 31 moves away from the middle of the moving trolley 2, further causing insert rod 34 to leave slot 113, at which point the moving trolley 2 can slide.

[0034] To further prevent the mobile trolley 2 from sliding randomly on the track 1, the end of the insertion rod 34 is provided with an anti-slip pad, which abuts against the slot 113, thereby increasing the friction between the insertion rod 34 and the slot 113.

[0035] When in use, when the fan inside the mobile trolley 2 needs to be cooled, the cooling device (such as a dry ice box) can be placed on the connecting plate 12 first, and then the connecting rod 32 can be pulled and the mobile trolley 2 can be moved to the top or diagonally above the cooling device. The cold air generated by the dry ice can enter the mobile trolley 2 and the fan through the negative pressure generated by the fan inlet, so as to achieve the cooling effect.

[0036] Obviously, if the humidity is high, the cooling device is prone to liquefying water vapor, causing water pools to accumulate on the connecting plate 12, leading to corrosion. To solve this technical problem, the top surface of the connecting plate 12 is provided with multiple inclined surfaces 122 evenly distributed along its length, with a through groove 121 located at the bottom of the inclined surface 122. The water that accumulates can then flow through the inclined surface 122 to the through groove 121, and then through the through groove 121 to the area below the connecting plate 12.

[0037] Finally, it should be noted that the above-listed embodiments are merely preferred embodiments of the present invention. Of course, those skilled in the art can make modifications and variations to the present invention. If such modifications and variations fall within the scope of the claims of the present invention and their equivalents, they should be considered as being within the protection scope of the present invention.

Claims

1. A high-temperature resistant air-supported membrane inflation device, characterized in that, Includes a track (1) and a moving trolley (2); The track (1) includes a splicing component (11) and a connecting plate (12). The two ends of the connecting plate (12) are respectively inserted into the splicing component (11). The connecting plate (12) is suspended. The connecting plate (12) has a plurality of through slots (121) arranged at equal intervals along its length direction. The through slots (121) are arranged along the width direction of the connecting plate (12). The mobile trolley (2) is slidably mounted on the top of the track (1), and a heat dissipation window (21) is provided on the side of the mobile trolley (2). The mobile trolley (2) is used to carry the fan.

2. The high-temperature resistant air-supported membrane inflation device according to claim 1, characterized in that, The bottom of the splicing component (11) is fixed with two symmetrically arranged support feet (111). The side of the splicing component (11) is provided with a slot (112) for installing the connecting plate (12). The side of the splicing component (11) is also provided with a slot (113), which is located above the slot (112). The top of the splicing component (11) is provided with a sliding groove (114).

3. The high-temperature resistant air-supported membrane inflation device according to claim 2, characterized in that, The mobile trolley (2) includes a base plate (22), a side wall (23), and an arc-shaped top plate (24) that are fixedly connected from bottom to top; The bottom of the base plate (22) is fixed with a slider (221) that can slide in the slide groove (114). The base plate (22) has two symmetrically arranged clearance grooves (222) that extend along the width direction of the track (1). The side wall (23) is provided with the heat dissipation window (21), and the side wall (23) is also provided with an air inlet pipe (232) for communicating with the exhaust port of the fan. Both opposite side walls (23) are fixed with connecting blocks (231). The arc-shaped top plate (24) bends upward, and the arc-shaped top plate (24) has two symmetrically arranged receiving grooves (241) that extend along the width direction of the track (1).

4. The high-temperature resistant air-supported membrane inflation device according to claim 3, characterized in that, The mobile trolley (2) is equipped with two symmetrically arranged limiting mechanisms (3) inside. The limiting mechanism (3) includes a drive rod (31), a connecting rod (32), a support rod (33), a plug rod (34), and a spring (35); The drive rod (31) is rotatably connected to the support rod (33) at the middle. Both ends of the support rod (33) are fixedly connected to the side wall (23). The upper part of the drive rod (31) passes through the receiving groove (241). The upper parts of the two drive rods (31) are connected by the connecting rod (32). The lower part of the drive rod (31) passes through the clearance groove (222). One end of the insertion rod (34) is fixedly connected to the bottom of the drive rod (31), and the other end of the insertion rod (34) is inserted into the slot (113), and the insertion rod (34) abuts against the slot (113); One end of the spring (35) is fixedly connected to the upper part of the side of the drive rod (31), and the other end of the spring (35) is fixedly connected to the connecting block (231).

5. A high-temperature resistant air-supported membrane inflation device according to claim 4, characterized in that, The end of the insertion rod (34) is provided with an anti-slip pad, which abuts against the slot (113).

6. A high-temperature resistant air-supported membrane inflation device according to any one of claims 1-5, characterized in that, The top surface of the connecting plate (12) is provided with a plurality of inclined surfaces (122) that are equally spaced along its length, and the through groove (121) is located at the bottom of the inclined surface (122).