RU57878U1 - SECTION RADIATOR FOR WATER HEATING SYSTEMS - Google Patents

Abstract

The utility model relates to the field of heating technology, in particular to heating radiators used for heating residential, public and industrial buildings and allows to increase the heat transfer surface and increase the heat transfer intensity while reducing the overall dimensions of the section, as well as simplify the design of the heat transfer surface and reduce manufacturing costs radiator. Sectional radiator 1 consists of at least two sections, each of which includes a collector 2 for the passage of the coolant through the section and collectors 3 for the passage of the coolant between the sections. Each section has a heat exchange element 4, including front and rear side panels 5 with symmetrical relative to the collectors 2 and 3, with ribs to increase the heat transfer area, connected to the collector 2 by the main ribs 6 located in a plane passing through its longitudinal axis perpendicular to the front and rear panels 5. The ribs to increase the heat transfer area are symmetrical with respect to the collectors 2 and 3 and form three vertical channels adjacent to the front and rear panels 5 and open the top and bottom sections. The extreme channels 7 have a rectangular cross section and are formed by the outer 12 and inner 13 side and rear 10 ribs. The middle channel 8 has a T-shaped cross section, its “vertical component” is formed by the inner 13 side ribs of the extreme channels 7, and the “horizontal component” is formed by the lateral ribs 9 perpendicular to the rear ribs 10, forming the extreme channels 7 and located along their middle and rear ribs 11, which are connected to the main ribs 6. Panels 5 symmetrically protrude beyond the side ribs 12, forming the extreme channels 7. 1 npf m.s., 1 s.p.f. pm, 2 Fig.

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 (application No. 2002114003, IPC F 24 H 3/00, publ. 30.05.2002) containing a pipe for a coolant with heat-dissipating (heat-exchange) elements mounted on it, made in the form of autonomous, finned heat pipes operating in a closed evaporative -condensation cycle, the bases of the heat pipes are located inside the pipe for the coolant, and the inner region of the pipe for the coolant in the place of fastening of the heat-dissipating elements has fins and structural elements to create a vortex flow carrier.

Known sectional radiator (patent RU No. 2127854, IPC F 24 H 3/06, publ. 03/20/1999), 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, heat dissipating (heat exchange ) an element made at the same time with the indicated channels of aluminum alloy by injection molding and equipped with means for increasing the heat transfer area in the form of ribs. The radiator has low mechanical strength due to the use of cast aluminum alloys, while hydraulic shocks associated with filling and draining the coolant in the heating system during commissioning, repair and seasonal maintenance work quickly disable individual radiator elements.

Known section of the radiator for water central heating systems (patent RU No. 2180423, IPC F 24 H 3/06, publ. 10.03.2002),

closest to the claimed utility model and adopted for the prototype, including a pipeline for the passage of the heat carrier through the radiator section, two pipelines for the passage of the heat medium between the radiator sections, a heat exchange element made of aluminum alloy with means for increasing the heat transfer area. The heat exchange element includes two main ribs located symmetrically relative to the pipeline for the passage of the coolant through the radiator section in a plane perpendicular to the plane of the piping for the passage of the coolant between the radiator sections, two side ribs of the same height located on one side relative to the plane of the main ribs at the edges of these ribs perpendicular to them, two central ribs of the same height, located on one side relative to the plane of the main ribs parallel to each other and symmetrically with respect to the longitudinal axis of the radiator section, while between the lateral and central ribs, symmetrically with respect to the longitudinal axis of the radiator section, there are three rows of studs, the height and diameter of the base of the studs forming a row closer to the longitudinal axis of the section greater than studs, forming a row located further from the longitudinal axis of the section, and between the mentioned Central ribs is the Central row of studs, and the height of all the studs and central ribs does not exceed the upper th edge of said side edges. The radiator does not provide a high heat transfer rate and has large dimensions and a complex structure.

The technical result, which the proposed utility model aims to achieve, is to increase the heat transfer surface due to the development of the profile structure of the heat exchange element, which leads to an increase in the heat flux from it and an increase in heat transfer intensity while reducing the overall dimensions of the section, as well as to simplify the design of the heat transfer surface and , hence,

simplifying the manufacturing technology of the radiator, which will lead to lower costs for its manufacture.

The technical result is achieved in that in a sectional radiator for water heating systems, consisting of at least two sections, each of which has a collector for the passage of the heat carrier through the section connected to the collectors for the passage of the heat carrier between the sections and a heat exchange element having a front and rear panels with ribs to increase the heat transfer area, located symmetrically relative to the collectors for the passage of coolant and connected to the collector for the passage of the coolant through the section with the ribs located in the plane passing through its longitudinal axis perpendicular to the front and rear panels, the new one is that the ribs to increase the heat transfer area are symmetrical with respect to the collectors for the coolant passage and form three vertical channels adjacent to the front and rear panels, open above and below the section, the extreme channels have a rectangular cross section and are formed by external and internal side and rear ribs, the middle channel has a T-shaped cross section , its “vertical component” is formed by the inner ribs of the extreme channels, and the “horizontal component” is formed by the lateral ribs and the rear edge, while its side ribs are perpendicular to the rear ribs forming the extreme channels and located in their middle, and the rear ribs are connected to the main ribs, forming the "horizontal component" of the T-shaped cross section of the middle channels, in addition, the longitudinal size of the front and rear panels is larger than the longitudinal size of the channels adjacent to them.

The longitudinal dimensions of the front and rear panels of the section are equal to each other and amount to 74 mm, and their thickness is 1.2 mm, the transverse size of the section is 69.20 mm, the thickness of the outer, inner and rear ribs,

forming the extreme channels and the thickness of the side ribs forming the "horizontal component" of the T-shaped cross section of the middle channel is 1.3 mm, and the thickness of its hind ribs is 1.5 mm, the longitudinal size of the extreme channels and the "vertical component" of the T-shaped transverse the cross section of the middle channel is 20 mm, and the transverse dimension of the outer channels and the transverse dimension of the "horizontal component" of the T-shaped cross section of the middle channel is 12 mm, while the longitudinal dimension of the "horizontal component" of the T-shaped erechnogo sectional secondary channel is 40 mm, the outer diameter of the collector for the passage of coolant through the section is 14 mm, 10 mm and an inner, moreover, the thickness of the main ribs is equal to 2 mm, their length is 3 mm.

The essence of the utility model is illustrated in figure 1 - figure 2, where:

Figure 1 is a General view of a sectional radiator.

Figure 2 - cross section of a heat exchange element (section aa)

Here: 1 - sectional radiator; 2 - collector for the passage of coolant through the radiator section; 3 - collectors for the passage of coolant between sections; 4 - heat exchange element; 5 - front and rear side panels; 6 - main ribs; 7 - extreme vertical channels; 8 - middle vertical channel; 9 - side ribs forming the "horizontal component" of the T-shaped cross section of the middle channel 8; 10 - the rear ribs of the extreme channels 7; 11 back ribs of the middle channels 8; 12 - outer side ribs forming the extreme channels 7; 13 - inner side ribs forming the extreme channels 7.

Sectional radiator 1 for water heating systems (Fig. 1), contains at least two sections, each of which has a vertical collector 2 for the passage of the coolant through the section of the radiator connected to horizontal collectors 3 for the passage of the coolant between the sections of the radiator (upper and lower ) Collectors 2 and 3 are interconnected to form a single channel for passage

coolant. Each section 1 has a heat exchange element 4 (figure 2), including front and rear side panels 5 with ribs symmetrically positioned relative to the collectors 2 and 3 to increase the heat transfer area, connected to the collector 2 by the main ribs 6 located in the plane passing through it the longitudinal axis is perpendicular to the front and rear panels 5. The ribs to increase the heat transfer area of the front and rear panels 5 are symmetrical with respect to the collectors 2 and 3 and form three vertices on each side of the collectors 2 and 3 channel adjacent to the front and rear panels 5 and open at the top and bottom of the section. The extreme channels 7 have a rectangular cross section and are formed by the outer 12 and inner 13 side and rear 10 ribs. The middle channel 8 has a T-shaped cross section, its “vertical component” is formed by the inner 13 side ribs of the extreme channels 7, and the “horizontal component” is formed by the lateral ribs 9 perpendicular to the rear ribs 10, forming the extreme channels 7 and located along their middle and rear edge 11, which is connected to the main ribs 6. The longitudinal size of the front and rear panels 5 is larger than the total longitudinal size of the channels 7 and 8 adjacent to them, while the front and rear panels 5 symmetrically protrude from the side ribs 12 forming the extreme channels 7.

The longitudinal dimensions of the front and rear panels 5 are equal to each other and are 74 mm, and their thickness is 1.2 mm, the transverse section size is 69.20 mm, the thickness of the ribs 10, 12, 13 forming the extreme channels 7 is 1.2 mm, the thickness of the ribs forming the side walls 9 of the "horizontal component" of the T-shaped cross section of the middle channel 8 is 1.3 mm, and the thickness of the ribs forming its rear walls 11 is 1.5 mm, the longitudinal size of the extreme channels 7 and the vertical component T -shaped cross section of the middle channel 8 is 20 mm, and across ny resolution extreme channel 7 and

the transverse dimension of the "horizontal component" of the T-shaped cross section of the middle channel 8 is 12 mm, while its longitudinal size is 40 mm, the outer diameter of the vertical manifold 2 is 14 mm, and the inner 10 mm, in addition, the thickness of the main ribs 6 is 2 mm, their length is 3 mm.

Hot coolant - water enters the vertical collector 2 from horizontal 3, heating the heat exchange element 4. Due to convection, the air coming from below into the vertical channels 7 and 8 of the heat exchange element 4 is heated and exits through their upper open sections.

Due to the implementation of the heat exchange element 4 in the form of a system of branched ribs of a certain configuration and size, the heat transfer surface increases, which leads to an increase in the heat flux from it and an increase in heat transfer intensity with a decrease in overall dimensions. In addition, a clear geometric configuration of the fins allows you to simplify the design of the heat exchange surface and, therefore, to simplify the manufacturing technology of the radiator, which will reduce the cost of manufacturing the radiator.

The configuration of the heat exchange element 4 and the dimensions of the ribs are determined by calculation and confirmed experimentally as a result of research work between Kazan State Technical University. A.N. Tupolev and LLC “Research and Production Firm“ Energy and Efficiency ”, Kazan, where production for the production of heating radiators for heating various enclosed spaces (residential buildings, offices, trade and exhibition areas, etc.) is prepared . This product is designed to work in water heating systems with a coolant temperature of up to + 105 ° C.

Claims (2)

1. Sectional radiator for water heating systems, consisting of at least two sections, each of which has a collector for passage of heat carrier through a section connected to collectors for passage of heat transfer fluid between sections and a heat exchange element having front and rear panels with fins for increase the heat transfer area, located symmetrically relative to the collectors for the passage of the coolant and connected to the collector for the passage of the coolant through the section of the main ribs located in the plane, wearing through its longitudinal axis perpendicular to the front and rear panels, characterized in that the ribs for increasing the heat transfer area are made symmetrical with respect to the collectors for the coolant passage and form three vertical channels adjacent to the front and rear panels, open at the top and bottom of the section, the extreme channels have rectangular cross-section and formed by external and internal side and rear ribs, the middle channel has a T-shaped cross section, its "vertical component" is formed inner ribs of the extreme channels, and the "horizontal component" is formed by the side ribs and the rear edge, while its side ribs are perpendicular to the rear ribs forming the extreme channels and located in their middle, and the main ribs are connected to the main ribs, forming the "horizontal component" T- figurative cross section of the middle channels, in addition, the longitudinal size of the front and rear panels is larger than the longitudinal size of the channels adjacent to them. 2. The 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 and are 74 mm, and their thickness is 1.2 mm, the transverse size of the section is 69.20 mm, the thickness of the external, internal and hind ribs forming the extreme channels and the thickness of the side ribs forming the "horizontal component" of the T-shaped cross section of the middle channel is 1.3 mm, and the thickness of its hind ribs is 1.5 mm, the longitudinal dimension of the extreme channels and the "vertical component" T-shaped cross section of the middle the channel is 20 mm, and the transverse dimension of the extreme channels and the transverse dimension of the "horizontal component" of the T-shaped cross section of the middle channel is 12 mm, while the longitudinal dimension of the "horizontal component" of the T-shaped cross section of the middle channel is 40 mm, the outer diameter of the collector for the coolant to pass through the section is 14 mm, and the inner 10 mm, in addition, the thickness of the main ribs is 2 mm, their length is 3 mm.