Assembled steel column radiator

Abstract

The utility model belongs to radiator technical field, especially relate to an assemblable steel column radiator, it includes: a plurality of warm group subassembly, set up in turn, a plurality of live joint connect adjacent a plurality of warm group subassembly, wherein each warm group subassembly includes: a plurality of warm column, adjacent warm column is connected through welding fixedly. Through live joint connection adjacent warm group subassembly, have solved the problem that the size of traditional integral type radiator is fixed and is not easy to install, and meet the free selection of user to product column number, and the user can order the product column number that oneself wants according to own demand, and need no longer be worried about the fixed product column number.

Description

Technical Field

[0001] This utility model belongs to the field of radiator technology, and in particular relates to an assemblable steel column radiator. Background Technology

[0002] Traditional radiators are mostly modular structures that rely on a central heating system. If the central system stops working, they cannot store heat, resulting in low thermal efficiency. Furthermore, the modular design lacks the flexibility to be assembled, making installation and customization difficult and hard to adapt to different spaces. Utility Model Content

[0003] The purpose of this utility model is to address the aforementioned technical problems by providing an assemblable steel column radiator that achieves high heating efficiency, modularity, and adaptability to any size or configuration requirements.

[0004] In view of this, the present invention provides an assemblable steel column radiator, comprising:

[0005] Several heating components are installed sequentially;

[0006] Several unions are used to connect adjacent heating components;

[0007] The aforementioned heating components include:

[0008] Several heating columns are connected by welding to each other.

[0009] In the above technical solution, the heating column further includes:

[0010] Two connecting blocks are arranged symmetrically to each other and have a through connecting hole in their middle;

[0011] The heat dissipation unit is integrally formed between the two connecting blocks, and its two ends are respectively connected to the connecting holes at their respective ends.

[0012] Furthermore, the above technical solution also includes:

[0013] Several threaded holes are provided on the connecting blocks on both sides of the heating component, and the threaded holes are coaxially arranged with the connecting holes and located outside the connecting holes;

[0014] The adjacent heating components are connected to the union joint via threaded holes.

[0015] Furthermore, the above technical solution also includes:

[0016] Several combined seals are disposed in the middle of the union;

[0017] The combined seal makes sealing contact with the connecting blocks on both sides.

[0018] Furthermore, the above technical solution also includes:

[0019] Several sealing grooves are coaxially arranged on the outside of the threaded hole, with the two sides of the combined seal extending into the sealing groove respectively.

[0020] In the above technical solution, the combined seal further includes:

[0021] Two external seals are symmetrically arranged and located in the sealing grooves on their respective sides, and their material is flexible.

[0022] The central seal is located between the two outer seals and is made of a flexible material.

[0023] In the above technical solution, the outer sealing element further includes:

[0024] The sealing element body is in contact with the end face of the sealing groove;

[0025] The sealing part is arc-shaped and formed on the side where the sealing body contacts the central sealing part;

[0026] In the above technical solution, the outer sealing element further includes:

[0027] Deformation groove, which is formed in the middle of the sealing part.

[0028] In the above technical solution, the central seal further includes:

[0029] Two sealing wings are symmetrically arranged in a "V" shape, and each sealing wing makes sealing contact with the sealing part on its respective side.

[0030] The central seal is connected to each other by two sealing wings in an "X" shape.

[0031] Furthermore, the above technical solution also includes a connector, which is located at the lower part of the heating column and communicates with the inside of the heating column.

[0032] The beneficial effects of this utility model are as follows:

[0033] 1. By connecting adjacent heating components through a union joint, the problem of fixed size and difficult installation of traditional monolithic radiators is solved, and users can freely choose the number of product columns. Users can order the desired number of product columns according to their own needs without having to worry about a fixed number of product columns.

[0034] 2. The heat sink design increases the heat exchange area and ensures uniform heat dissipation. Attached Figure Description

[0035] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0036] Figure 2 This is a schematic diagram of the heating column structure of this utility model;

[0037] Figure 3 This is an overall sectional view of the present invention;

[0038] Figure 4 yes Figure 3 A magnified view of a section at point I;

[0039] Figure 5 yes Figure 4 Enlarged view of a section at point II;

[0040] The markings in the diagram are as follows: heating component 1, union 2, heating column 11, connecting block 111, heat dissipation part 112, combined seal 3, outer seal 31, middle seal 32, sealing groove 4, seal body 311, sealing part 312, deformation groove 313, sealing wing 321, and plug 5. Detailed Implementation

[0041] The technical solutions of the embodiments of this application will be clearly described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this application. All other embodiments obtained by those skilled in the art based on the embodiments of this application are within the scope of protection of this application.

[0042] Example 1:

[0043] This embodiment provides an assemblable steel column radiator, comprising:

[0044] Several heating components 1 are installed sequentially;

[0045] Several union joints 2 are used to connect adjacent heating components;

[0046] The plurality of heating components 1 mentioned above include:

[0047] Several heating columns 11 are connected by welding to each other.

[0048] In this embodiment, the union 2 connects to the heating assembly 1 and serves as a detachable connection, allowing users to assemble radiators with different numbers of columns according to their actual needs; the heating column 11 is fixedly connected to enhance the overall stability; for ease of installation, the hole inside the union can be set as a regular hexagon.

[0049] Example 2:

[0050] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0051] Heating column 11 includes:

[0052] Two connecting blocks 111 are symmetrically arranged and have a through connecting hole in their middle;

[0053] The heat dissipation part 112 is integrally formed between two connecting blocks 111, and its two ends are respectively connected to the connecting holes at their respective ends.

[0054] In this embodiment, the fluid flows through the connecting block 111 on one side, then into the heat dissipation section 112, and finally out through the connecting block 111 on the other side. The circulating heat-conducting fluid radiates heat into the indoor space through the heat dissipation section 112. The fluid can carry a large amount of heat energy and has small temperature fluctuations, thus achieving stable and uniform heating. The middle of the connecting block 111 is open to receive a large amount of fluid, and the bottom of the connecting block 111 is connected to the heat dissipation section 112, distributing the input fluid to the heat dissipation section 112 and playing a role in heat energy distribution.

[0055] Example 3:

[0056] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0057] Several threaded holes are provided on the connecting blocks 111 on both sides of the heating component 1, and the threaded holes are coaxially arranged with the connecting holes and located outside the connecting holes;

[0058] The adjacent heating component 1 is connected to the union 2 through a threaded hole.

[0059] In this embodiment, only the connecting blocks 111 on both sides of the heating component 1 need to be provided with threaded holes for threaded connection; the other connecting blocks 111 are connected by welding and have no thread requirement. The threaded holes are provided with positive and negative threads that are compatible with the live joint 2.

[0060] Example 4:

[0061] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0062] Several combined seals 3 are disposed in the middle of the union 2;

[0063] The combined seal 3 is in sealing contact with the connecting blocks 111 on both sides.

[0064] In this embodiment, the union 2 is screwed into the threaded hole on the connecting block 111, so that the connecting blocks on both sides press against the combined seal, thereby improving the overall sealing performance.

[0065] Example 5:

[0066] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0067] Several sealing grooves 4 are coaxially arranged on the outside of the threaded hole, wherein the two sides of the combined seal 3 extend into the sealing grooves 4 respectively.

[0068] In this embodiment, the sealing groove 4 facilitates the sealing connection of the combined seal 3. The combined seal 3 extends and deforms on both sides to fill the tiny gap between the sealing groove 4 and its contact surface, thereby forming an effective sealing barrier in two directions to prevent fluid leakage.

[0069] Example 6:

[0070] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0071] Two external seals 31 are symmetrically arranged in the sealing groove 4 of the combined seal 3, and their material is flexible material;

[0072] The central seal 32 is disposed between the two outer seals 31 and is made of a flexible material.

[0073] In this embodiment, the middle seal 32 and the outer seal 31 fit together to improve the sealing effect. The flexible material has a wide range of applications and good fitting performance.

[0074] Example 7:

[0075] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0076] The outer seal 31 includes:

[0077] The sealing element body 311 is in contact with the end face of the sealing groove 4;

[0078] The sealing part 312 is arc-shaped and formed on the side of the sealing body 311 that contacts the central sealing part 32.

[0079] In this embodiment, the sealing body 311 directly abuts against the end face of the sealing groove 4 after installation, which is one of the keys to achieving basic sealing. The sealing part 312 is arc-shaped and fits against the central sealing part 32. The arc-shaped structure reduces the concentration of contact stress, and the arc surface is more conducive to forming line contact, increasing the contact pressure per unit area, which is beneficial to sealing.

[0080] Example 8:

[0081] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0082] The outer seal 31 also includes:

[0083] Deformation groove 313 is formed in the middle of sealing part 312.

[0084] In this embodiment, the deformation groove 313 guides the sealing part 312 to deform evenly to both sides around the groove, avoiding stress concentration, enhancing pressure adaptability and improving sealing reliability.

[0085] Example 9:

[0086] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0087] The central seal 32 includes:

[0088] Two sealing wings 321 are arranged symmetrically in a "V" shape, and each sealing wing 321 is in sealing contact with the sealing part 312 on its respective side.

[0089] The central seal 32 is interconnected by two sealing wings 321 in an "X" shape.

[0090] In this embodiment, the V-shaped sealing wings 321 on both sides achieve a double sealing effect. The contact area with the sealing part 312 is small, the frictional resistance is reduced, the energy consumption and wear are reduced, and the structure of the symmetrical V-shaped sealing wings 321 evenly distributes the pressure, avoids unilateral extrusion, and has good extrusion resistance.

[0091] Example 10:

[0092] This embodiment provides an assemblable steel column radiator, which, in addition to the technical solutions of the above embodiments, also has the following technical features.

[0093] Also includes:

[0094] The connector 5 is located at the lower part of the heating column 11 and is connected to the inside of the heating column 11.

[0095] In this embodiment, an electric heating rod can be inserted into the heating column 11 through the connector 5. When not connected to the external heating pipe, the electric heating rod can provide electric heating. If the electric heating rod fails, it can be disassembled and replaced through the connector 5 without affecting the main body.

[0096] One installation method for radiators: During installation, plugs are installed on the threaded holes of two connecting blocks 111 on both sides of the assemblable steel column radiator. A heating pipe is connected to each of the other two connecting blocks 111 for connection to the external heating pipe. A valve is installed on each heating pipe. When heating is provided through the heating pipe, the valves on both heating pipes are open. When heating is provided through the electric heating rod, the valves on both heating pipes are closed.

[0097] Another installation method for radiators: During installation, plugs are installed on the threaded holes of the four connecting blocks 111 on both sides of the assemblable steel column radiator. This installation method is only suitable for electric heating rod heating.

[0098] The embodiments of this application have been described above with reference to the accompanying drawings. Unless otherwise specified, the embodiments and features in the embodiments of this application can be combined with each other. This application is not limited to the specific embodiments described above. The specific embodiments described above are merely illustrative and not restrictive. Those skilled in the art can make many other forms under the guidance of this application without departing from the spirit and scope of the claims, and all of these forms are within the protection scope of this application.

Claims

1. An assemblable steel column radiator, characterized in that, include: Several heating components (1) are installed sequentially; Several unions (2) are used to connect several adjacent heating components (1); Each of the aforementioned heating components (1) includes: Several heating columns (11) are fixedly connected to each other.

2. The assemblable steel column radiator according to claim 1, characterized in that, The heating column (11) includes: Two connecting blocks (111) are symmetrically arranged and have a through connecting hole in their middle; The heat dissipation part (112) is integrally formed between the two connecting blocks (111), and both ends are connected to the connecting holes at their respective ends.

3. The assemblable steel column radiator according to claim 2, characterized in that, Also includes: Several threaded holes are provided on the connecting blocks (111) on both sides of the heating component (1), and the threaded holes are coaxially arranged with the connecting holes and located outside the connecting holes; The adjacent heating components (1) are connected to the union (2) through threaded holes.

4. The assemblable steel column radiator according to claim 3, characterized in that, Also includes: Several combined seals (3) are provided in the middle of the union (2); The combined seal (3) is in sealing contact with the connecting blocks (111) on both sides.

5. The assemblable steel column radiator according to claim 4, characterized in that, Also includes: Several sealing grooves (4) are coaxially arranged on the outside of the threaded hole, wherein the combined seal (3) extends into the sealing grooves (4) on both sides respectively.

6. The assemblable steel column radiator according to claim 5, characterized in that, The combined seal (3) includes: Two external seals (31) are symmetrically arranged and located in the sealing grooves (4) on their respective sides; The middle seal (32) is disposed between the two outer seals (31).

7. The assemblable steel column radiator according to claim 6, characterized in that, The outer seal (31) includes: The sealing body (311) is in contact with the end face of the sealing groove (4); The sealing part (312) is arc-shaped and formed on the side of the sealing body (311) that contacts the central sealing part (32).

8. The assemblable steel column radiator according to claim 7, characterized in that, The outer seal (31) further includes: Deformation groove (313) is formed in the middle of sealing part (312).

9. An assemblable steel column radiator according to claim 8, characterized in that, The central seal (32) includes: Two sealing wings (321) are symmetrically arranged and have a "V" shape, and each sealing wing (321) is in sealing contact with the sealing part (312) on its side. The central seal (32) is connected to each other by two sealing wings (321) in an "X" shape.

10. An assemblable steel column radiator according to claim 1, characterized in that, It also includes: a connector (5), which is located at the lower part of the heating column (11) and communicates with the inside of the heating column (11).

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