Energy-saving heat-insulating steel structure

By combining modular square tube frames and connectors with a friction gear linkage structure, the problem of poor thermal insulation performance of traditional steel structures is solved, achieving convenient installation, self-adaptive fastening, and energy-saving thermal insulation effect, extending material life and reducing heat conduction.

CN224495389UActive Publication Date: 2026-07-14SHANDONG CHANGYA STEEL STRUCTURE ENG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANDONG CHANGYA STEEL STRUCTURE ENG CO LTD
Filing Date
2025-06-27
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Traditional steel structures have poor thermal insulation performance. Existing insulation measures are prone to falling off, their insulation effect decays quickly, and construction is complicated, making it difficult to achieve long-term and stable energy-saving effects.

Method used

The modular design of the square tube frame and connectors, combined with the linkage structure of friction gears and binding straps, enables rapid splicing and adaptive fastening of the insulation material, ensuring that the material is stably attached to the frame.

Benefits of technology

It achieves modular and rapid installation and disassembly, provides convenient and efficient thermal insulation, extends the service life of insulation materials, reduces heat conduction loss, and continuously ensures the thermal insulation performance of steel structures.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an energy -conserving type heat -preserving and heat -insulating steel structure, it includes square tube frame, the upper end fixed connection of square tube frame has symmetrical upper connecting piece, the lower end fixed connection of square tube frame has lower connecting piece, the movable joint of heat -insulating material has in square tube frame, the lateral surface fixed connection of square tube frame has first concave -convex connecting edge, the other side fixed connection of square tube frame has second concave -convex connecting edge, the upper connecting piece swing joint is in lower connecting piece, first concave -convex connecting edge swing joint is in second concave -convex connecting edge, the friction gear of swing joint is equipped with to the corresponding limit axle, the driven gear swing joint is in friction gear, and the bundling band swing joint is in heat -insulating material. Through above -mentioned structure, realize modularization quick splicing, and installation dismounts convenient efficient, can effectively prevent its displacement, ensure heat -preserving and heat -insulating effect stable, prolong the service life of heat -insulating material, and continuously guarantee the heat -preserving and heat -insulating performance of steel structure.
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Description

Technical Field

[0001] This utility model relates to the field of thermal insulation steel structure technology, and in particular to an energy-saving thermal insulation steel structure. Background Technology

[0002] In the construction industry, steel structures are widely used due to their high strength and fast construction. However, traditional steel structures have poor thermal insulation performance. In winter, heat is easily lost through the steel structure, and in summer, external heat easily enters the room, leading to a significant increase in building energy consumption. Air conditioning and heating equipment need to operate at high loads for extended periods, which not only wastes energy but also increases operating costs.

[0003] Existing steel structure insulation measures, such as adding insulation cotton and spraying heat-insulating coatings, suffer from problems such as easy detachment of the insulation layer and rapid decay of the insulation effect, making it difficult to achieve long-term stable energy-saving effects. Moreover, some solutions are complex to construct and costly, making them difficult to promote on a large scale. Utility Model Content

[0004] The purpose of this utility model is to solve at least one of the technical problems existing in the prior art, and to provide an energy-saving thermal insulation steel structure that achieves modular rapid splicing, convenient and efficient installation and disassembly, effectively prevents displacement, ensures stable thermal insulation effect, extends the service life of insulation materials, and continuously guarantees the thermal insulation performance of the steel structure.

[0005] This utility model also provides an energy-saving thermal insulation steel structure, including a square tube frame. The upper end of the square tube frame is fixedly connected with symmetrical upper connecting pieces, and the lower end of the square tube frame is fixedly connected with a lower connecting piece. Thermal insulation material is movably connected inside the square tube frame. A first concave-convex connecting edge is fixedly connected to one side of the square tube frame, and a second concave-convex connecting edge is fixedly connected to the other side of the square tube frame.

[0006] According to the present invention, an energy-saving thermal insulation steel structure is provided, wherein the upper connecting piece is movably connected to the lower connecting piece, and the upper and lower connecting pieces are provided with symmetrical first connecting holes, and corresponding fixing buttons are movably connected in the first connecting holes.

[0007] According to the present invention, an energy-saving thermal insulation steel structure is provided, wherein the first concave-convex connecting edge is movably connected to the second concave-convex connecting edge, and the first concave-convex connecting edge and the second concave-convex connecting edge are respectively provided with second connecting holes, and a fixing rod is movably connected in the corresponding second connecting hole.

[0008] According to the present invention, an energy-saving thermal insulation steel structure is provided, wherein a plurality of openings are provided on the square tube frame, and corresponding fixed connections are made within the openings, and corresponding movable friction gears are sleeved on the limiting shafts.

[0009] According to the present invention, an energy-saving thermal insulation steel structure is provided, wherein a symmetrical rotating shaft is movably connected through the square tube frame, and a symmetrical driven gear is fixedly connected to the end of the rotating shaft, and the driven gear is movably connected to a friction gear.

[0010] According to the present invention, an energy-saving thermal insulation steel structure is provided on the square tube frame, and a corresponding sliding plate is movably connected in the sliding groove. A friction block is fixedly connected to the upper end of the sliding plate, and a fixed tip is fixedly connected to the side of the sliding plate. The fixed tip is movably connected to the friction gear.

[0011] According to the present invention, an energy-saving thermal insulation steel structure is provided, wherein a plurality of symmetrical limiting plates are fixedly connected inside the square tube frame, and the limiting plates are movably connected to the thermal insulation material.

[0012] According to the present invention, an energy-saving thermal insulation steel structure is provided on the rotating shaft, and a plurality of symmetrical fixing grooves are provided in the fixing grooves, and the fixing grooves are fixedly connected to the corresponding binding straps, which are movably connected to the thermal insulation material.

[0013] Beneficial effects:

[0014] 1. The energy-saving thermal insulation steel structure of this technical solution achieves modular and rapid assembly through the combination of upper and lower connecting plates with fixing buttons, and the first and second concave-convex connecting edges with fixing rods, making installation and disassembly convenient and efficient. The limiting plate inside the square tube frame limits the thermal insulation material, effectively preventing its displacement and ensuring stable thermal insulation performance.

[0015] 2. The linkage structure consisting of friction gears, driven gears, rotating shafts, and binding straps can adjust the tightness of the binding straps by driving a lever through friction blocks when the insulation material is deformed under pressure, thus adaptively maintaining a tight hold on the insulation material. This extends the service life of the insulation material, continuously ensuring the thermal insulation performance of the steel structure, while reducing heat conduction loss caused by material loosening, achieving energy saving and consumption reduction. Attached Figure Description

[0016] The present invention will be further described below with reference to the accompanying drawings and embodiments;

[0017] Figure 1 This is a structural diagram of an energy-saving thermal insulation steel structure according to the present invention;

[0018] Figure 2 The present utility model proposes Figure 1 Enlarged view of point A in the middle;

[0019] Figure 3 This is a cross-sectional view of a square tube frame of an energy-saving thermal insulation steel structure according to this utility model;

[0020] Figure 4 This is a cross-sectional view of the thermal insulation material of an energy-saving thermal insulation steel structure according to this utility model.

[0021] Legend:

[0022] 1. Square tube frame; 2. Upper connecting piece; 3. Lower connecting piece; 4. First connecting hole; 5. First concave-convex connecting edge; 6. Second concave-convex connecting edge; 7. Second connecting hole; 8. Thermal insulation material; 9. Binding strap; 10. Fixing button; 11. Fixing rod; 12. Friction gear; 13. Sliding groove; 14. Friction block; 15. Driven gear; 16. Paddle; 17. Fixing tip; 18. Opening; 19. Limiting shaft; 20. Rotating shaft; 21. Fixing groove; 22. Limiting plate. Detailed Implementation

[0023] This section will describe in detail the specific embodiments of the present utility model. The preferred embodiments of the present utility model are shown in the accompanying drawings. The purpose of the drawings is to supplement the textual description with graphics, so that people can intuitively and vividly understand each technical feature and the overall technical solution of the present utility model, but they should not be construed as limiting the scope of protection of the present utility model.

[0024] Reference Figure 1-4 This utility model embodiment discloses an energy-saving thermal insulation steel structure, which includes a square tube frame 1. The upper end of the square tube frame 1 is fixedly connected with symmetrical upper connecting pieces 2, and the lower end of the square tube frame 1 is fixedly connected with a lower connecting piece 3, providing an interface for the vertical splicing of modules. Thermal insulation material 8 is movably connected inside the square tube frame 1. The side of the square tube frame 1 is fixedly connected with a first concave-convex connecting edge 5, and the other side of the square tube frame 1 is fixedly connected with a second concave-convex connecting edge 6, realizing the horizontal splicing of modules.

[0025] Specifically, the upper connecting piece 2 is movably connected to the lower connecting piece 3. The upper connecting piece 2 and the lower connecting piece 3 are provided with symmetrical first connecting holes 4. The corresponding fixing buttons 10 are movably connected in the first connecting holes 4 to complete the stable connection between the upper and lower modules.

[0026] Specifically, the first concave-convex connecting edge 5 is movably connected to the second concave-convex connecting edge 6. The first concave-convex connecting edge 5 and the second concave-convex connecting edge 6 are respectively provided with second connecting holes 7. The corresponding fixing rods 11 are movably connected in the second connecting holes 7 to ensure that the overall steel structure is tightly connected.

[0027] Specifically, the square tube frame 1 has multiple openings 18, and corresponding fixed connections of limit shafts 19 are made in the openings 18. Correspondingly, friction gears 12 are sleeved on the limit shafts 19, and pushing the friction gears 12 causes the binding straps 9 to tighten or loosen.

[0028] Specifically, a symmetrical rotating shaft 20 is movably connected through the square tube frame 1, and a symmetrical driven gear 15 is fixedly connected to the end of the rotating shaft 20. The driven gear 15 is movably connected to the friction gear 12.

[0029] Specifically, the square tube frame 1 has multiple sliding grooves 13, and corresponding movable paddles 16 are connected in the sliding grooves 13. The upper end of the paddle 16 is fixedly connected to a friction block 14, and the side of the paddle 16 is fixedly connected to a fixed tip 17. The fixed tip 17 is movably connected to the friction gear 12. Moving the friction block 14 causes the fixed tip 17 to engage with the friction gear 12, causing the friction gear 12 to stop rotating. Conversely, moving the friction gear 12 disengages it from rotating.

[0030] Specifically, multiple symmetrical limiting plates 22 are fixedly connected inside the square tube frame 1, and the limiting plates 22 are movably connected to the thermal insulation material 8.

[0031] Specifically, the rotating shaft 20 has multiple symmetrical fixing grooves 21, and corresponding binding straps 9 are fixedly connected in the fixing grooves 21. The binding straps 9 are movably connected to the heat insulation material 8 to ensure that the material is always in a tight state.

[0032] Working principle:

[0033] Adjacent square tube frames 1 are joined together via upper connecting piece 2 and lower connecting piece 3, and a fixing button 10 is inserted through the first connecting hole 4 to achieve vertical fastening between modules. Simultaneously, the first concave-convex connecting edge 5 on one side is fitted with the second concave-convex connecting edge 6 on the other side, and a fixing rod 11 is inserted through the second connecting hole 7 to complete the horizontal splicing and form a complete frame structure. Thermal insulation material 8 is placed inside the square tube frame 1 and initially positioned by the limiting plate 22. When changes in ambient temperature or structural stress cause the thermal insulation material 8 to expand or contract, the material squeezing paddle 16 moves within the sliding groove 13, causing the friction block 14 to contact the friction gear 12 and generate friction, driving the friction gear 12 to rotate. The friction gear 12 drives the rotating shaft 20 to rotate synchronously via the driven gear 15, causing the binding strap 9 to tighten or loosen, adaptively adjusting the constraint force on the thermal insulation material 8. When the binding strap 9 reaches the appropriate tightness, the fixing tip 17 engages with the groove of the friction gear 12, preventing it from rotating further and locking the current state; conversely, moving the lever 16 disengages the fixing tip 17 from the friction gear 12, thus unlocking the system. This automatic adjustment mechanism ensures that the thermal insulation material 8 always fits tightly against the frame, effectively reducing the heat conduction path and improving the overall thermal insulation performance of the steel structure.

[0034] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.

Claims

1. An energy-saving thermal insulation steel structure, comprising a square tube frame (1), characterized in that: The upper end of the square tube frame (1) is fixedly connected with a symmetrical upper connecting piece (2), the lower end of the square tube frame (1) is fixedly connected with a lower connecting piece (3), the inside of the square tube frame (1) is movably connected with a heat insulation material (8), the side of the square tube frame (1) is fixedly connected with a first concave-convex connecting edge (5), and the other side of the square tube frame (1) is fixedly connected with a second concave-convex connecting edge (6).

2. The energy-saving thermal insulation steel structure according to claim 1, characterized in that, The upper connecting piece (2) is movably connected to the lower connecting piece (3). The upper connecting piece (2) and the lower connecting piece (3) are provided with symmetrical first connecting holes (4). A fixing button (10) is movably connected to the corresponding first connecting hole (4).

3. The energy-saving thermal insulation steel structure according to claim 1, characterized in that, The first concave-convex connecting edge (5) is movably connected to the second concave-convex connecting edge (6). The first concave-convex connecting edge (5) and the second concave-convex connecting edge (6) are respectively provided with second connecting holes (7). A fixing rod (11) is movably connected in the second connecting hole (7).

4. The energy-saving thermal insulation steel structure according to claim 1, characterized in that, The square tube frame (1) has multiple openings (18), and corresponding fixed connections are made within the openings (18). Correspondingly, friction gears (12) are fitted onto the limiting shafts (19).

5. The energy-saving thermal insulation steel structure according to claim 4, characterized in that, A symmetrical rotating shaft (20) is movably connected through the square tube frame (1). A symmetrical driven gear (15) is fixedly connected to the end of the rotating shaft (20). The driven gear (15) is movably connected to the friction gear (12).

6. The energy-saving thermal insulation steel structure according to claim 5, characterized in that, The square tube frame (1) has multiple sliding grooves (13), and a corresponding paddle (16) is movably connected in the sliding groove (13). A friction block (14) is fixedly connected to the upper end of the paddle (16), and a fixed tip (17) is fixedly connected to the side of the paddle (16). The fixed tip (17) is movably connected to the friction gear (12).

7. The energy-saving thermal insulation steel structure according to claim 1, characterized in that, The square tube frame (1) is fixedly connected with a plurality of symmetrical limiting plates (22), and the limiting plates (22) are movably connected to the heat insulation material (8).

8. The energy-saving thermal insulation steel structure according to claim 5, characterized in that, The rotating shaft (20) has multiple symmetrical fixing grooves (21), and the fixing grooves (21) are fixedly connected with corresponding binding straps (9), which are movably connected to the heat insulation material (8).