RU46081U1 - RADIATOR FOR WATER CENTRAL HEATING SYSTEMS - Google Patents

Abstract

The utility model relates to heating radiators used in water central heating systems of residential, public and industrial buildings. The radiator consists of sections, each of which includes at least one vertical pipe for the heat carrier to pass through the radiator section, to which at least two horizontal pipelines are connected to supply and exit the heat carrier, respectively, ensuring its passage between the radiator sections and a heat dissipating element consisting of at least one rib to increase the heat transfer area, and the ends of the horizontal pipelines of each section are interconnected using a nipple, with containing in the central part an element capable of bending. The bendable member may be a bellows made of stainless steel or a heat-resistant polymer material. The proposed radiator can be installed in rooms with convex-concave walls and / or decorative and functional architectural elements (bay windows, pilasters, niches); It is easy to use, can be mounted immediately in place.

Description

The utility model relates to the field of heating technology, in particular to heating radiators used in water central heating systems of residential, public and industrial buildings.

Known heating radiator containing sections with vertical heat exchange channels of a given length and width, equipped with coaxial hollow inserts, fastened together by nipples with the formation of a gap between adjacent sections (RF Patent No. 2024800, F 24 H 3/06, publ. 15.12.1994 g.). The aim of the invention is the intensification of heat transfer. However, the rigid system of fastenings between sections does not allow the use of such radiators along walls that have a non-standard shape.

A known heating system comprising a heating device to which are connected pipelines of the supply and exhaust flow of a coolant, while the pipelines may contain a telescopic assembly (see Utility Model Certificate No. 22528, F 24 H 3/06, published on 04/10/2002) . The telescopic unit provides the connection of pipelines with each other with the possibility of changing their length and spatial location relative to each other. In this case, a change in the spatial arrangement of pipelines can occur by turning them relative to each other.

This technical solution allows you to create spatial structures at the design stage of the heating system, taking into account the specific placement of the system of pipes and heating devices in the premises and the distance between them. However, the use of the indicated telescopic unit in sectional central heating radiators will not allow bending of pipelines between sections and, therefore, the possibility of placing the radiator along non-planar surfaces, in particular, having some curvature. In addition, for the normal functioning of the telescopic assembly, a sealing device is required that is placed in the union nut and contains a bandage with o-rings and an end seal, which complicates the design.

A known radiator (see Patent RU 2180423, F 24 H 3/06, publ. 10.03.2002), consisting of sections including vertical pipelines for the passage of the coolant through the radiator section and horizontal pipelines for the passage of the coolant between the radiator sections. The sections of the horizontal piping sections are interconnected using threaded nipples.

The specified technical solution is taken as a prototype.

The main disadvantage of such a radiator is the lack of a flexible connection between the sections, which does not allow to give it a shape that repeats the profile of the walls during the installation of the radiator.

The problem that is solved by the proposed utility model is to create a radiator for central heating systems, which can be installed in rooms with convex-concave walls and / or decorative and functional architectural elements (bay windows, pilasters, niches).

The technical result achieved by the implementation of the claimed technical solution consists in creating a radiator with a flexible connection between sections, which allows us to solve the problem. Such radiators are easy to use, fit well into the interior of the room. This provides thermal performance not worse than in the prototype.

The design of the radiator for water central heating systems, ensuring the achievement of the above technical result in all cases to which the requested amount of legal protection applies, can be characterized by the following set of features.

A radiator for water central heating systems, consisting of sections in which each section includes at least one vertical pipe for the heat carrier to pass through the radiator section, to which at least two horizontal pipelines are connected for supply and exit of the heat carrier, respectively providing its passage between the sections of the radiator, and a heat-dissipating element consisting of at least one rib to increase the area of heat transfer, moreover, according to the proposed technical solution the ends, the horizontal piping of each section

interconnected by means of a nipple containing in the central part an element capable of bending.

In the particular case of the radiator, the element capable of bending is a bellows, and it can be made of stainless steel.

In another particular case, the element capable of bending can be made of heat-resistant polymer material that provides the required thermal characteristics and durability of the radiator.

A horizontal pipeline for supplying coolant may contain inside a tube of a smaller diameter of heat-resistant flexible material with a length of not more than 3/4 of the length of the entire radiator. The flow of hot coolant is first directed through the specified tube to the distant sections of the radiator, which then fills the rest of the pipeline and is more evenly distributed over the vertical pipelines. This allows you to increase the heat transfer efficiency of the radiator.

The nipple can be attached to the ends of horizontal pipelines with glue or with threads.

The thread may be coated with a layer of anticorrosive sealant.

The inner surface of vertical and horizontal pipelines, as well as the inner and outer surface of the tube located in the coolant supply pipe, can be coated with a layer of anticorrosive zinc material with a thickness of at least 30 microns.

The possibility of implementing the claimed technical solution, characterized by the above set of features, as well as the possibility of realizing the purpose can be confirmed by a description of the possible design of the radiator, which is illustrated by graphic materials that depict the following.

Figure 1 - radiator assembly (General view).

Figure 2 - nipple with a bellows.

The radiator consists of sections 1, made by injection molding of aluminum alloy and assembled using nipples 2 in a single design to ensure tightness.

Each section 1 includes a vertical pipe 3 of rectangular cross-section for the passage of the coolant through the radiator section, two horizontal pipes 4 of circular cross-section for the passage of coolant between the sections of the radiator, which are welded to the ends of the specified vertical pipe to form a single element for the passage of coolant.

All pipelines are made of steel and can have an anti-corrosion zinc coating with a thickness of at least 30 microns made by thermal diffusion from the inside.

The radiator also contains a heat-dissipating element consisting of two main ribs 5 located symmetrically with respect to the vertical pipe 3 in a plane perpendicular to the plane of the piping 4. The heat-dissipating element also includes two side ribs 6 of the same height located on one side relative to the plane of the main ribs 5 at the edges these ribs and perpendicular to them, as well as the Central ribs 7 of the same height, located parallel to each other.

The heat-dissipating element is made of an aluminum alloy by injection molding with the formation of a bimetallic part during the casting process with the aforementioned single element for the passage of the coolant, which is used as an embedded part during the casting process.

The sections 1 are assembled by connecting the pipelines 4 by means of nipples 2. The connection can be threaded using an anti-corrosion sealing compound such as silicone, or it can be carried out using an anaerobic adhesive. This eliminates the contact of aluminum elements of the radiator section with the coolant after connecting the radiator sections to each other.

Each nipple contains in the central part a bellows 8, which can be made of stainless steel with corrosion resistance. The bellows is connected to the parts of the nipple, for example, by welding.

The possibility of bending the bellows allows you to give the entire radiator the desired shape corresponding to the walls of the room. Such radiators do not require prior knowledge of geometric dimensions and configuration.

installation locations. They are easy to use because they can be mounted immediately in place.

The number of sections is selected depending on customer requirements. The side ribs of the sections after assembling the radiator form the front panel of the radiator and the rear panel of the radiator.

The described example of the implementation of a sectional radiator for water central heating systems proves the possibility of realizing the purpose of the utility model and achieving the above technical result, but it does not exhaust all the possibilities of implementing the utility model, characterized by the combination of features given in the formula.

Claims (16)

1. A radiator for water central heating systems, consisting of sections, in which each section includes at least one vertical pipe for the heat carrier to pass through the radiator section, to which at least two horizontal pipelines for supply and output are connected heat carrier, respectively, ensuring its passage between the sections of the radiator, and a heat-dissipating element consisting of at least one rib to increase the heat transfer area, characterized in that the ends of the horizontal the pipelines of each section are interconnected by means of a nipple containing in the central part an element capable of bending. 2. The radiator according to claim 1, characterized in that the element capable of bending is a bellows. 3. The radiator according to claim 2, characterized in that the bellows is made of stainless steel. 4. The radiator according to claim 1, characterized in that the element capable of bending is made of heat-resistant polymer material. 5. The radiator according to claim 2, characterized in that the bellows is made of heat-resistant polymer material. 6. A radiator according to any one of claims 1 to 5, characterized in that the horizontal pipe for supplying a coolant comprises a tube of a smaller diameter made of heat-resistant flexible material with a length of not more than 3/4 of the length of the entire radiator. 7. A radiator according to any one of claims 1 to 5, characterized in that the nipple is attached to the ends of horizontal pipelines with glue. 8. The radiator according to claim 6, characterized in that the nipple is attached to the ends of horizontal pipelines with glue. 9. A radiator according to any one of claims 1 to 5, characterized in that the nipple is attached to the ends of horizontal pipelines with a thread. 10. The radiator according to claim 6, characterized in that the nipple is attached to the ends of horizontal pipelines using threads. 11. The radiator according to claim 9, characterized in that the thread is coated with a layer of anticorrosive sealant. 12. The radiator according to claim 10, characterized in that the thread is coated with a layer of anticorrosive sealant. 13. A radiator according to any one of claims 1 to 5, 8, 10, 11, 12, characterized in that the inner surface of the vertical and horizontal pipelines is coated with a layer of anticorrosive zinc material with a thickness of at least 30 microns. 14. The radiator according to claim 6, characterized in that the inner surface of the vertical and horizontal pipelines, as well as the inner and outer surface of the tube, are coated with a layer of anticorrosive zinc material with a thickness of at least 30 microns. 15. The radiator according to claim 7, characterized in that the inner surface of the vertical and horizontal pipelines is covered with a layer of anticorrosive zinc material with a thickness of at least 30 microns. 16. The radiator according to claim 9, characterized in that the inner surface of the vertical and horizontal pipelines is covered with a layer of anticorrosive zinc material with a thickness of at least 30 microns.