A heating elevated composite ground module

By setting adjustment grooves and adjustment plates at the corners of the rectangular substrate, combined with support rods and sleeve structures, the unevenness caused by substrate warping is solved, enabling independent adjustment of the substrate corners and uniform heat transfer, thus improving construction quality and safety.

CN120759403BActive Publication Date: 2026-07-03BEIJING TAI WEI YIJU DECORATION ENG CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
BEIJING TAI WEI YIJU DECORATION ENG CO LTD
Filing Date
2025-08-14
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

In the prior art, the base plate of the heating overhead module is prone to warping after production or long-term use, resulting in overall unevenness, and the existing leveling module cannot adjust the corners of a single base plate individually.

Method used

An adjustment groove is provided at the corner of each rectangular substrate, and an adjustment plate is slidably arranged inside. The height of the corner of the substrate can be adjusted individually by changing the position of the adjustment plate. Combined with the first and second adjustment components, the substrate is abutted against the ground through the first and second support rods respectively, so as to achieve precise adjustment of the substrate.

Benefits of technology

It enables independent adjustment of the edges and corners of individual base plates, ensuring the overall flatness of the heating overhead module, improving construction quality and heat transfer efficiency, and possessing good fire resistance and strength.

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Abstract

This invention relates to a heated elevated composite floor module, comprising: multiple rectangular base plates and a first adjusting component. The first adjusting component includes a first support rod, a first sleeve, and adjusting arms. One end of the first support rod is for contact with the ground, and the first support rod has external threads. The first sleeve is fitted onto the first support rod and has internal threads that mate with the first support rod. Four adjusting arms are arranged in a circular array on the first sleeve. An adjusting groove matching the shape of the adjusting arms is provided on the bottom surface of the rectangular base plates. An adjusting plate is slidably disposed within the adjusting groove, and the adjusting plate abuts against the adjusting arms. An adjusting rod is slidably disposed on the rectangular base plates, and one end of the adjusting rod abuts against the adjusting plate. This invention, by changing the position of the adjusting plate, can change the relative position of the corners of the rectangular base plates and the adjusting arms, thereby achieving height adjustment of a single corner of the rectangular base plate.
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Description

Technical Field

[0001] This invention relates to the field of heating, and more particularly to a heating overhead composite floor module. Background Technology

[0002] Underfloor heating has become a trend in modern buildings. Heating modules typically consist of multiple base plates arrayed on the floor slab. Heating pipes are usually laid on these base plates, and then the flooring is installed on top. In existing technology, after the base plates are arrayed on the floor slab, the corners of adjacent base plates are mounted on a leveling module, meaning the corners of two base plates are held against the floor slab by the leveling module. Because base plates are prone to warping during production or prolonged use, the leveling module adjusts both base plates' corners simultaneously, rather than adjusting a single base plate's corner individually. This can easily lead to unevenness throughout the entire heating module. Summary of the Invention

[0003] (a) Technical problems to be solved

[0004] This invention provides a heating-supported composite floor module, which aims to solve the problem in the prior art that the edges and corners of a single substrate cannot be adjusted individually.

[0005] (II) Technical Solution

[0006] To address the aforementioned problems, the present invention provides a heating elevated composite floor module, the heating elevated composite floor module comprising: multiple rectangular base plates and multiple first adjustment components;

[0007] The rectangular substrates are arranged in an array along the X and Y directions, and two adjacent rectangular substrates are bonded to each other;

[0008] The first adjusting component includes a first support rod, a first sleeve, and adjusting arms; one end of the first support rod is used to abut against the ground, the first support rod is provided with external threads, the first sleeve is a hollow tube with open ends, the first sleeve is sleeved on the first support rod, and the first sleeve is provided with internal threads that cooperate with the first support rod, and four adjusting arms are arranged in a ring array on the first sleeve.

[0009] Each of the four corners of the rectangular substrate is provided with a first adjusting member, and one corner of the rectangular substrate abuts against an adjusting arm on the corresponding first adjusting member; an adjusting groove matching the shape of the adjusting arm is provided on the bottom surface of the rectangular substrate, and an adjusting plate is slidably disposed in the adjusting groove, the adjusting plate abutting against the adjusting arm; an adjusting rod is slidably disposed on the rectangular substrate, one end of the adjusting rod abutting against the adjusting plate, the adjusting rod being used to adjust the position of the adjusting plate in the adjusting groove.

[0010] Preferably, the adjusting arm is provided with an internal threaded connection hole for connecting with a rectangular base plate, and a first adjusting hole corresponding to the internal threaded connection hole is provided through the rectangular base plate.

[0011] Preferably, each of the four corners of the rectangular substrate is provided with an arc-shaped groove that matches the shape of the first sleeve, and the first sleeve is attached to the arc-shaped groove.

[0012] Preferably, the second end of the first support rod is provided with an adjustment head, which is located outside the first sleeve and above the top surface of the rectangular substrate.

[0013] Preferably, the heated elevated composite floor module further includes a second adjusting member disposed on the bottom surface of the rectangular base plate;

[0014] The second adjusting component includes a second support rod and a second sleeve. The first end of the second support rod is used to abut against the ground. The second support rod is provided with an external thread, and the end face of the second end of the second support rod is provided with an internal hexagon countersunk hole.

[0015] The second sleeve is a hollow tube open at both ends. The second sleeve is fitted onto the second support rod, and the second sleeve has an internal thread that mates with the second support rod.

[0016] The rectangular base plate is fixedly connected to the second sleeve, and a second adjustment hole is provided through the rectangular base plate, the second adjustment hole coinciding with the center line of the second sleeve.

[0017] Preferably, the second sleeve is provided with a support plate that abuts against the bottom surface of the rectangular substrate.

[0018] Preferably, the second adjustment hole is located at the center of the rectangular substrate.

[0019] Preferably, at least one of the rectangular substrates has a groove on its top surface for accommodating the underfloor heating pipe.

[0020] One of the rectangular substrates has multiple cylindrical protrusions on its top surface.

[0021] Preferably, an aerogel felt is laid on the bottom surface of the rectangular substrate, and a thermally conductive layer is provided in the groove.

[0022] Preferably, the rectangular substrate is a cement rectangular substrate, and reinforcing fibers are added to the cement rectangular substrate.

[0023] (III) Beneficial Effects

[0024] The present invention provides an adjustment groove at each corner of a rectangular substrate, and an adjustment plate is slidably disposed in the adjustment groove. By changing the position of the adjustment plate, the relative position of the corner of the rectangular substrate and the adjustment arm can be changed, thereby realizing the height adjustment of the corner of a single rectangular substrate. Attached Figure Description

[0025] Figure 1 An exploded view of the corners of the rectangular substrate and the first adjusting member in this invention;

[0026] Figure 2 This is a schematic diagram of the overall structure of the heating overhead composite ground module of the present invention;

[0027] Figure 3 This is a structural schematic diagram of the heating overhead composite ground module of the present invention from another perspective.

[0028] [Explanation of Labels in the Attached Image]

[0029] 1: Rectangular substrate; 11: Adjustment groove; 12: Adjustment plate; 13: Adjustment rod; 14: First adjustment hole; 15: Arc-shaped groove; 16: Second adjustment hole; 17: Groove; 18: Columnar protrusion;

[0030] 2: First adjusting component; 21: First support rod; 22: First sleeve; 23: Adjusting arm; 231: Internal threaded connection hole; 24: Adjusting head;

[0031] 3: Second adjusting component; 31: Second support rod; 32: Second sleeve; 33: Support plate. Detailed Implementation

[0032] To better explain and facilitate understanding of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

[0033] It should be noted that all directional indications (such as up, down, left, right, front, back, etc.) in the embodiments of the present invention are only used to explain the relative positional relationship and movement of each component in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indication will also change accordingly.

[0034] Furthermore, in this invention, descriptions involving "first," "second," etc., are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of that feature. In the description of this invention, "a plurality of" means at least two, such as two, three, etc., unless otherwise explicitly specified.

[0035] In this invention, unless otherwise explicitly specified and limited, the terms "connection," "fixed," etc., should be interpreted broadly. For example, "fixed" can mean a fixed connection, a detachable connection, or an integral part; it can mean a mechanical connection or an electrical connection; it can mean a direct connection or an indirect connection through an intermediate medium; it can mean the internal communication of two components or the interaction between two components, unless otherwise explicitly limited. Those skilled in the art can understand the specific meaning of the above terms in this invention according to the specific circumstances.

[0036] This invention provides a heated elevated composite floor module, comprising: multiple rectangular base plates 1 and a first adjusting member 2. The multiple rectangular base plates 1 are arranged in an array along the X and Y directions, and adjacent rectangular base plates 1 are attached to each other; wherein the X and Y directions are two mutually perpendicular directions in the horizontal plane.

[0037] The first adjusting component 2 includes a first support rod 21, a first sleeve 22, and adjusting arms 23. The first end of the first support rod 21 is used to abut against the ground, and the first support rod 21 has external threads. The first sleeve 22 is a hollow tube open at both ends, sleeved on the first support rod 21, and the first sleeve 22 has internal threads that mate with the first support rod 21. Four adjusting arms 23 are arranged in a circular array on the first sleeve 22. Rotating the second end of the first support rod 21 from one end of the first sleeve 22 allows for overall adjustment of the height of the four adjusting arms 23 on the first sleeve 22, thus coarsely adjusting the contact between the adjusting arms 23 and the rectangular substrate 1.

[0038] like Figure 1 As shown ( Figure 1(The grooves and cylindrical protrusions on the top surface of the rectangular substrate are not shown). A first adjusting member 2 is provided at each of the four corners of a rectangular substrate 1. One corner of the rectangular substrate 1 abuts against an adjusting arm 23 on the corresponding first adjusting member 2. An adjusting groove 11 matching the shape of the adjusting arm 23 is provided on the bottom surface of the rectangular substrate 1. An adjusting plate 12 is slidably disposed in the adjusting groove 11 and abuts against the adjusting arm 23. An adjusting rod 13 is slidably disposed on the rectangular substrate 1. One end of the adjusting rod 13 abuts against the adjusting plate 12 and is used to adjust the position of the adjusting plate 12 in the adjusting groove 11.

[0039] In the technical solution of this invention, the substrates are bonded together and arranged in an array along the X and Y directions respectively. In a room, one first adjusting member 2 supports the corners of four substrates, meaning one adjusting arm 23 corresponds to the corner of one substrate. When adjusting the height of the substrate corner, the adjusting rod 13 is first used to adjust the position of the adjusting plate 12 within the adjusting groove 11. Then, the adjusting groove 11 is engaged with the adjusting arm 23, so that the adjusting arm 23 abuts against the adjusting plate 12. Finally, the adjusting arm 23 and the corresponding rectangular substrate 1 are fixed to complete the installation. Since each rectangular substrate 1 has an adjusting groove 11 at its corner, and an adjusting plate 12 is slidably disposed within the adjusting groove 11, changing the position of the adjusting plate 12 changes the relative position of the corner of the rectangular substrate 1 and the adjusting arm 23, thereby achieving height adjustment of a single rectangular substrate 1's corner.

[0040] In a preferred embodiment, the adjusting rod 13 can be threaded to move the adjusting plate 12 through the adjusting groove 11 and to limit the displacement of the adjusting plate 12. The adjusting arm 23 is provided with an internally threaded connection hole 231 for connecting to the rectangular base plate 1, and a first adjusting hole 14 corresponding to the internally threaded connection hole 231 is provided through the rectangular base plate 1. In the above embodiment, the rectangular base plate 1 is connected to the adjusting arm 23 by fasteners.

[0041] Furthermore, each of the four corners of the rectangular substrate 1 is provided with an arc-shaped groove 15 that matches the shape of the first sleeve 22, and the first sleeve 22 is attached to the arc-shaped groove 15. When the four rectangular substrates 1 are spliced ​​together, the four arc-shaped grooves 15 can be connected at one time to form a through hole for accommodating the first sleeve 22.

[0042] Furthermore, an adjusting head 24 is provided at the second end of the first support rod 21. The adjusting head 24 is located outside the first sleeve 22 and above the top surface of the rectangular base plate 1. The adjusting head 24 is provided with a cross groove, which facilitates the rotation of the first support rod 21.

[0043] In addition, the heated elevated composite floor module also includes a second adjusting component 3 disposed on the bottom surface of the rectangular base plate 1. The second adjusting component 3 includes a second support rod 31 and a second sleeve 32. The first end of the second support rod 31 is used to abut against the ground, and the second support rod 31 is provided with external threads. The end face of the second end of the second support rod 31 is provided with an internal hexagon countersunk hole. The second sleeve 32 is a hollow tube with openings at both ends. The second sleeve 32 is sleeved on the second support rod 31, and the second sleeve 32 is provided with internal threads that mate with the second support rod 31. The rectangular base plate 1 is fixedly connected to the second sleeve 32, and a second adjusting hole 16 is provided through the rectangular base plate 1. The second adjusting hole 16 coincides with the center line of the second sleeve 32.

[0044] In a preferred embodiment, the second sleeve 32 is provided with a support plate 33 that abuts against the bottom surface of the rectangular substrate 1. The second adjustment hole 16 is located at the center of the rectangular substrate 1.

[0045] Finally, at least one of the rectangular substrates 1 has a groove 17 on its top surface for accommodating the underfloor heating pipe. One of the rectangular substrates 1 also has multiple cylindrical protrusions 18 on its top surface to facilitate the branching of the underfloor heating pipe.

[0046] An aerogel felt is laid on the bottom surface of the rectangular substrate 1, and a thermally conductive layer is disposed in the groove 17. The groove 17 area on the rectangular substrate 1 is coated with a graphene thermally conductive layer. Utilizing the ultra-high thermal conductivity of graphene, it replaces the traditional heat spreader layer, enabling rapid and uniform heat transfer from the heating element to the module surface and the entire ground surface, significantly improving heat transfer efficiency and reducing heat loss. The graphene thermally conductive layer is tightly bonded to the cement-based module using a special bonding process, preventing it from easily detaching or delaminating, ensuring long-term stable thermal conductivity. During product processing, an aerogel felt is laid under the rectangular substrate 1 and pressed together with it. The aerogel felt's excellent thermal insulation properties, combined with the module, effectively prevent heat from being conducted downwards.

[0047] The rectangular substrate 1 is a cement rectangular substrate 1, with reinforcing fibers added inside. The rectangular substrate 1 uses cement-based composite materials, with high-strength cement as the base material, and adds reinforcing fibers (such as glass fiber and carbon fiber) and additives (water-reducing agents, waterproofing agents, etc.), and is integrally molded. This integral molding method gives the module uniform density and high strength, effectively avoiding the strength weakening problem caused by gaps in traditional spliced ​​modules, while also possessing good fire resistance, meeting building fire safety standards.

[0048] The construction steps for using this invention are as follows:

[0049] Substrate preparation: Clean the installation surface to ensure it is flat, clean, and free of debris, oil stains, or other factors that may affect module installation. Based on the design drawings, mark the baseline for module installation on the ground to determine the installation position of the rectangular base plate 1.

[0050] Rectangular substrate 1 installation: Transport rectangular substrate 1 to the installation site and place it sequentially according to the baseline. Fine-tune the position of rectangular substrate 1 by adjusting the cross-slit position to ensure that the rectangular substrate 1 is installed flat and aligned, and that adjacent modules are tightly connected.

[0051] Underfloor heating pipe installation: Insert the underfloor heating pipes sequentially into the pre-reserved grooves 17 on the rectangular base plate 1 according to the designed path, ensuring that the underfloor heating pipes fit tightly and are firmly fixed in the grooves 17. When connecting the various components of the underfloor heating pipes, use special connecting fittings to ensure the sealing and reliability of the connection points and prevent water leakage.

[0052] System Debugging: After installing the rectangular base plate 1 and the underfloor heating pipes, perform a water injection and pressure test on the entire underfloor heating system to check the sealing of the pipes and whether the system pressure is normal. After passing the test, perform system debugging to ensure the underfloor heating system can operate normally and achieve the expected heating effect. Finally, lay floor covering materials, such as wood flooring or tiles, on the surface of the rectangular base plate 1 to complete the installation of the underfloor heating system.

[0053] It should be understood that the above description of specific embodiments of the present invention is only for illustrating the technical approach and features of the present invention, and is intended to enable those skilled in the art to understand the content of the present invention and implement it accordingly. However, the present invention is not limited to the specific embodiments described above. All changes or modifications made within the scope of the claims of the present invention should be covered within the protection scope of the present invention.

Claims

1. A heating elevated composite ground module, characterized in that, The heating overhead composite floor module includes: multiple rectangular base plates (1) and multiple first adjustment components (2); Multiple rectangular substrates (1) are arranged in an array along the X and Y directions, and two adjacent rectangular substrates (1) are bonded to each other; The first adjusting component (2) includes a first support rod (21), a first sleeve (22), and adjusting arms (23); one end of the first support rod (21) is used to abut against the ground, and the first support rod (21) is provided with an external thread; the first sleeve (22) is a hollow tube with openings at both ends; the first sleeve (22) is sleeved on the first support rod (21), and the first sleeve (22) is provided with an internal thread that mates with the first support rod (21); four adjusting arms (23) are arranged in a ring array on the first sleeve (22); A first adjusting member (2) is provided at each of the four corners of a rectangular substrate (1). One corner of the rectangular substrate (1) abuts against an adjusting arm (23) on the corresponding first adjusting member (2). An adjusting groove (11) matching the shape of the adjusting arm (23) is provided on the bottom surface of the rectangular substrate (1). An adjusting plate (12) is slidably disposed in the adjusting groove (11). The adjusting plate (12) abuts against the adjusting arm (23). An adjusting rod (13) is slidably disposed on the rectangular substrate (1). One end of the adjusting rod (13) abuts against the adjusting plate (12). The adjusting rod (13) is used to adjust the position of the adjusting plate (12) in the adjusting groove (11).

2. The heating elevated composite ground module as described in claim 1, characterized in that, The adjusting arm (23) is provided with an internal threaded connection hole (231) for connecting with the rectangular base plate (1), and the rectangular base plate (1) is provided with a first adjusting hole (14) corresponding to the internal threaded connection hole (231).

3. The heating elevated composite ground module as described in claim 2, characterized in that, The rectangular substrate (1) has arc-shaped grooves (15) at each of its four corners that match the shape of the first sleeve (22), and the first sleeve (22) is attached to the arc-shaped grooves (15).

4. The heating elevated composite ground module as described in claim 3, characterized in that, An adjustment head (24) is provided at the second end of the first support rod (21). The adjustment head (24) is located outside the first sleeve (22) and above the top surface of the rectangular substrate (1).

5. The heating elevated composite floor module as described in any one of claims 1-4, characterized in that, The heating overhead composite floor module also includes a second adjusting component (3) disposed on the bottom surface of the rectangular base plate (1); The second adjusting member (3) includes a second support rod (31) and a second sleeve (32). The first end of the second support rod (31) is used to abut against the ground. The second support rod (31) is provided with an external thread. The end face of the second end of the second support rod (31) is provided with an internal hexagon countersunk hole. The second sleeve (32) is a hollow tube open at both ends. The second sleeve (32) is sleeved on the second support rod (31), and the second sleeve (32) is provided with an internal thread that mates with the second support rod (31). The rectangular base plate (1) is fixedly connected to the second sleeve (32), and a second adjustment hole (16) is provided through the rectangular base plate (1), the second adjustment hole (16) and the center line of the second sleeve (32) are coincident.

6. The heating elevated composite ground module as described in claim 5, characterized in that, The second sleeve (32) is provided with a support plate (33) that abuts against the bottom surface of the rectangular base plate (1).

7. The heating elevated composite floor module as described in claim 5, characterized in that, The second adjustment hole (16) is located at the center of the rectangular substrate (1).

8. The heating elevated composite floor module as described in any one of claims 1-4, characterized in that: At least one of the rectangular substrates (1) has a groove (17) on its top surface for accommodating the underfloor heating pipe; Among the plurality of rectangular substrates (1), one of the rectangular substrates (1) has a plurality of columnar protrusions (18) on its top surface.

9. The heating elevated composite ground module as described in claim 8, characterized in that, An aerogel felt is laid on the bottom surface of the rectangular substrate (1), and a heat-conducting layer is provided in the groove (17).

10. The heating elevated composite ground module as described in any one of claims 1-4, characterized in that, The rectangular substrate (1) is a cement rectangular substrate (1), and fibers are added inside the cement rectangular substrate (1).