RU145712U1 - SECTION RADIATOR - Google Patents

Abstract

1. Sectional radiator comprising upper and lower manifolds, vertical tubular sections connected to them, each of which is a channel for the passage of the coolant through the radiator section with a system of heat-removing fins and contains front and rear panels, characterized in that the width of the section is equal to its depth or they differ from each other by no more than 10%, and the coolant channel has a central location relative to the center of the cross section of the section. 2. The sectional radiator according to claim 1, characterized in that each section contains one pair of symmetrical fins located in a plane passing through the longitudinal axis of the coolant channel, one pair of symmetrical fins located at an angle to the transverse axis of the coolant channel and forming a closed air duct with the front panel cavity, one pair of symmetrical curved ribs having a part inclined relative to the longitudinal axis of the channel and a part parallel to the rear panel. 3. Sectional radiator according to claim 1, characterized in that each section additionally contains three fins, forming with the rear panel two closed air cavities. The sectional radiator according to claim 3, characterized in that one of the ribs forming closed air cavities with the rear panel, is located in a plane passing through the transverse axis of the coolant channel, starts on the coolant channel and is made before connecting to the rear panel, and two other ribs begin on curved ribs at the place of smooth mating of their inclined and parallel parts of the rear panel and are also made before connecting to the rear panel. 5. Sectional radiator according to claim 1, characterized in that the fins

Description

The utility model relates to the field of heating technology, in particular to sectional aluminum radiators used for space heating, and to tubular elements (sections) of such radiators.

Sectional radiators are the most common heating devices used in heating systems of residential, public and industrial buildings. Sectional aluminum radiators are characterized by high heat transfer, relatively low weight and cost. The heat transfer of a sectional radiator is affected by such parameters as the number of sections, section configuration (profile), its dimensions, method of manufacturing the constituent elements, alloy composition and other parameters. Thus, improving the profile of the sections is one of the directions in the development of this technical field.

Known heat transfer profile (certificate of utility model RU 36725, IPC F28F 1/10, publ. March 20, 2004), containing a pipe for the passage of the coolant and heat dissipating element made in the form of two longitudinal walls located on opposite sides of the pipe parallel to each other, and longitudinal plates radially spaced between the walls. At least two radial profile plates form a closed air channel with each longitudinal wall along the entire length of the wall. Air channels, longitudinal walls and radial plates are located relative to the axis of the pipe according to the principle of symmetry.

Known heat transfer profile (patent for utility model RU 42642, IPC F28F 1/10, publ. 10.12.2004) containing a pipe for the passage of the coolant and heat-dissipating element made in the form of two longitudinal walls located on opposite sides of the pipe parallel to each other friend, and longitudinal heat sink plates located between the walls radially relative to the pipe. The external and internal radial profile plates form two closed air channels with each longitudinal wall.

Known sectional radiator of a household heating system made of extruded aluminum profiles (RF patent for invention RU 2254521, IPC F24H 3/00, publ. 06/20/2005), containing inlet and outlet collectors, vertical tubular axisymmetric sections connected to them with axial radial ribs, rear and front exterior panels. The tubular channel of the section is a pipe with vertical heat-releasing ribs made of radial axial, and intermediate symmetrically curved ribs.

Known sectional radiator of a household heating system made of extruded aluminum profiles (RF patent for the invention RU 2391609, IPC F24H 3/00, publ. 10.06.2010), containing inlet and outlet collectors, and connected to them axisymmetrically arranged tubular sections in the form of a pipe with vertical heat sink fins made of radial axial, with intermediate symmetrically curved ribs. The sectional tubular channel in section is a pipe with one pair of radial ribs placed horizontally, one pair of ribs, bent parallel to the outer panel mainly on one quarter of the length of the ribs and offset 45 ° relative to the axis of the section channel, with one pair of symmetrical ribs located relative to each other at an angle of predominantly 90 °, making up an isosceles triangle (closed cavity) in cross section, on the sides of which, at least half their length, is a pair of horizontal ntal ribs. The outer and rear panels of the section have technological bulges at the edges with an inner and outer ledge.

This technical solution is the closest to the claimed solution and therefore selected by the applicant as a prototype.

The disadvantages of the above designs, including and prototype, is the low value of the reduced heat flux from one section of the radiator - not more than 140 ... 170 W / section.

In the prototype, the width of the section exceeds the depth of the section. The calculations made by the applicant made it possible to form the dependences of the overall dimensions and thermal characteristics of the radiator on various geometric parameters. So, the most effective measure to increase heat transfer is to increase the depth of the profile, since the mass growth rate in this case is significantly less than the increase in thermal power compared to the option of increasing the width while maintaining the minimum depth. In addition, the coolant channel in the prototype is shifted to the rear panel of the section, which reduces the efficiency of heating the air in the front of the section. Therefore, the prototype does not provide a sufficiently high intensity of heat transfer.

The utility model is based on the task of creating a new sectional radiator having optimal dimensions and cross-section from the point of view of the optimal ratio of the weight and size and thermal characteristics of the section and the radiator as a whole.

The technical result is an increase in heat transfer from one section of the radiator while reducing the metal content of the profile used, as well as improving the manufacturability.

To achieve this goal, in a sectional radiator containing upper and lower collectors, vertical tubular sections connected to them, each of which is a channel for the heat carrier to pass through the radiator section with a system of heat-removing fins and contains front and rear panels, according to a utility model, the width of the section equal to its depth or they differ from each other by no more than 10%, the coolant channel has a central or close to central location relative to the center of the cross section with ktsii.

Each section contains one pair of symmetrical ribs located in a plane passing through the longitudinal axis of the coolant channel, one pair of symmetrical ribs located at an angle to the transverse axis of the coolant channel and forming a closed air cavity with the front panel, one pair of symmetric curved ribs having an inclined relative to the longitudinal axis of the channel part and part parallel to the rear panel.

Each section additionally contains three ribs forming two closed air cavities with the rear panel.

The ribs located in the plane passing through the longitudinal axis of the coolant channel are made short with a length of not more than 30% of the section width.

The width of the section must correspond to its depth, or be different from it, but not more than 10%, these are the parameters of the section that provide close to the maximum value the area of the side surface of the section. This leads to a maximum or close to maximum value of the heat given to the air at a constant value of the cross-sectional area of the section.

The advantages of a central or near central location of the coolant channel are the uniform heating of the front and rear panels of the section, which provide most of the heat transfer to the air, as well as the convenience of assembly and installation of the section and collectors.

The claimed configuration of the section provides a high value of the average reduced coefficient of heat transfer to air of at least 194 W / section, as well as the uniformity of heating of the front and rear panels of the section.

The presence of closed air cavities formed by ribs with a rear panel additionally contributes to the intensive transfer of heat to the rear wall of the section.

The implementation of the ribs located in the plane passing through the longitudinal axis of the coolant channel, short, not more than 30% of the width of the section, reduces the hydraulic resistance when air flows inside the cross section of the section, but at the same time gives additional heat transfer to the air.

Patent studies did not reveal technical solutions characterized by the claimed combination of features, therefore, we can assume that the specified technical solution corresponds to the concept of "novelty."

In addition, the proposed technical solution can be manufactured on an industrial scale and will find application in sectional radiators used for space heating, which meets the criterion of "industrial applicability".

The essence of the proposed technical solution is illustrated by drawings:

in FIG. 1 shows a general view of a sectional radiator assembly;

in FIG. 2 is a side view of a radiator;

in FIG. 3 is a cross-sectional view of a radiator section.

Below is one example of the implementation of this utility model. This example is provided primarily for illustrative purposes and should not be construed as limiting the scope of claims.

The sectional radiator comprises upper and lower collectors 1 and vertical tubular sections 2 connected to them (Fig. 1, 2). The upper and lower collectors 1 are made in the form of a profile pipe with a channel for the passage of coolant between the sections of the radiator, a hollow visor located on the front side and the supporting part.

Each vertical tubular section 2 of the radiator represents a channel 3 for passage of the heat carrier through the section of the radiator with a system of heat-removing fins to increase the area of heat transfer (Fig. 3). The coolant channel 3 has a central or close to central location relative to the center of the cross section of the section profile (deviation from the center of not more than 5%).

Each vertical tubular section 2 contains:

- front 4 and rear 5 panels,

- one pair of symmetrical short ribs 6 (the length of the ribs is not more than 30% of the width of the section) located in a plane passing through the longitudinal axis a of the coolant channel 3, which is parallel to the front panel 4, and symmetrical about the transverse axis b of the coolant channel 3,

- one pair of symmetrical ribs 7, connecting the coolant channel 3 with the front panel 4, located at an angle of 30 ... 60 ° to the transverse axis b of the coolant channel 3, forming a closed air cavity with the front panel 4 and making up an equilateral or close to equilateral triangle in the cross section , on the sides of which, about half their length is a pair of symmetrical ribs 8 parallel to the front panel 4,

- one short rib 9 located between the ribs 7 in the plane passing through the transverse axis 6 of the coolant channel 3,

- one pair of symmetrical curved ribs 10 located between the short ribs 6 and the rear panel 5, which start on the coolant channel 3, have an inclined part located at an angle of 30 ... 50 ° to the longitudinal axis a of the coolant channel 3, and smoothly mate to parallel to the rear panel 5 parts 11,

- three ribs parallel to the transverse axis b of the coolant channel 3 and forming two closed air cavities with the back panel 5, one of these ribs 12 is located in a plane passing through the transverse axis b of the coolant channel 3, starts on the coolant channel 3 and is made before connecting to the back panel 5, and the other two 13 begin at the ribs 10 in the place of smooth pairing of their inclined and parallel to the rear panel 5 of the parts 11 and are also made before connecting to the rear panel 5.

The ends of the ribs 8 and parallel to the rear panel 5 of the parts 11 of the ribs 10 are in the same plane and do not go beyond the front 4 and rear 5 panels. At the ends of the parts 11 of the ribs 10 and the rear panel 5, technological thickenings are made to increase the strength and stability during broaching. The same thickening is performed on the rib 12.

The longitudinal dimensions of the front 4 and rear 5 panels are equal. The number of sections in the radiator can vary from 3 to 16.

The width A of the section (longitudinal dimension) corresponds to the depth of the B section (transverse dimension) or differs from it by no more than 10%. As shown by the calculations and tests made by the applicant, the radiator shows the best characteristics with a section size of 90 × 90 mm. Such a design is the preferred embodiment of the claimed utility model, however, section sizes may be different.

The configuration of the section, its dimensions and thermal parameters were determined by calculation by the applicant together with the South Ural State University, Chelyabinsk and experimentally confirmed by the Scientific and Technical Firm LLC Vitaterm, Moscow.

Due to the implementation of the radiator section in the form of a system of branched ribs of the claimed configuration and size, the heat transfer surface increases, which leads to an increase in the heat flux from one section and the radiator as a whole and an increase in the heat transfer intensity while reducing the overall dimensions of the radiator.

Claims (10)

1. Sectional radiator comprising upper and lower manifolds, vertical tubular sections connected to them, each of which is a channel for the passage of the coolant through the radiator section with a system of heat-removing fins and contains front and rear panels, characterized in that the width of the section is equal to its depth or they differ from each other by no more than 10%, and the coolant channel has a central location relative to the center of the cross section of the section. 2. Sectional radiator according to claim 1, characterized in that each section contains one pair of symmetrical fins located in a plane passing through the longitudinal axis of the coolant channel, one pair of symmetrical fins located at an angle to the transverse axis of the coolant channel and forming with the front panel a closed air cavity, one pair of symmetrical curved ribs having a part inclined relative to the longitudinal axis of the channel and a part parallel to the rear panel. 3. The sectional radiator according to claim 1, characterized in that each section further comprises three fins, forming two closed air cavities with the rear panel. 4. The sectional radiator according to claim 3, characterized in that one of the ribs, forming closed air cavities with the rear panel, is located in a plane passing through the transverse axis of the coolant channel, starts on the coolant channel and is made before connecting to the rear panel, and two other ribs begin on curved ribs in the place of smooth mating of their inclined and parallel parts of the rear panel and are also made before connecting to the rear panel. 5. Sectional radiator according to claim 1, characterized in that the ribs located in a plane passing through the longitudinal axis of the coolant channel are made short, with a length of not more than 30% of the width of the section. 6. Sectional radiator according to claim 1, characterized in that each vertical tubular section further comprises one short rib located between the ribs forming a closed air cavity with the front panel in a plane passing through the transverse axis of the coolant channel. 7. Sectional radiator according to claim 1, characterized in that the longitudinal dimensions of the front and rear panels of the section are equal to each other. 8. The sectional radiator according to claim 1, characterized in that the width and depth of each section are 90 mm. 9. Sectional radiator according to claim 1, characterized in that at the ends of the curved ribs and the rear panel technological thickenings are made to increase strength and stability during broaching. 10. Sectional radiator according to claim 1, characterized in that it contains from 3 to 16 sections.