CN217383940U - Radiator with high thermal conductivity - Google Patents

Abstract

The utility model provides a radiator with high thermal conductivity. It has solved the relatively poor problem of current radiator heating effect. The utility model discloses in effectively increase heat radiating area through the first fin of fixed setting at the riser both ends respectively and second fin to further optimize heat dissipation channel through dislocation set's first fin and second fin, make the heat on part first fin and the second fin dispel the heat to the outside, and conflict each other, further increase the heat radiating area of stand through fixed setting respectively at the first fin of stand both sides, second fin and third fin, promote the heating effect.

Description

Radiator with high thermal conductivity

Technical Field

The utility model relates to a radiator technical field, in particular to radiator with high heat conductivity.

Background

With the development of society and the progress of science and technology, the income of people is increased year by year, the living standard and the housing condition are further improved, and the use of indoor heating radiators in winter is more and more common. The heating radiator used at present is formed by splicing and assembling a plurality of radiator units, each radiator unit mainly comprises an upper pipe head, a lower pipe head and a main vertical pipe for connecting the upper pipe head and the lower pipe head, in order to improve the radiating efficiency, a radiation positive fin and a radiation back fin are arranged on the main vertical pipe, and after the radiator is assembled, the upper pipe head and the lower pipe head are respectively butted to form an upper pipe and a lower pipe. Hot water flows in from the water inlet joint or is directly heated in the lower pipe, and flows out from the water outlet joint after heat exchange is realized or closed water circulation is completed in the radiator. But through hot water after upper tube, low tube and main part riser flow, the radiating effect is relatively poor, can't effectively heat indoor, and the heating effect is relatively poor, and prior art exists and can improve the part.

Disclosure of Invention

The utility model discloses equipment provides a radiator with high thermal conductivity to the relatively poor not enough of current radiator heating effect.

The invention aims to be realized by the following technical scheme: the radiator with high thermal conductivity is characterized by being formed by splicing a plurality of radiating units, each radiating unit comprises an upper pipe, a lower pipe and a vertical plate fixedly arranged between the upper pipe and the lower pipe, the upper pipe, the lower pipe and the vertical plate are hollow and mutually communicated, hot water can flow between the upper pipe, the lower pipe and the vertical plate, a first fin and a second fin are fixedly arranged on two end faces, far away from the upper pipe and the lower pipe, of the vertical plate respectively, the upper end of the first fin and the upper pipe are located on the same plane, the lower end of the first fin is located above the lower pipe, the lower end of the second fin and the lower pipe are located on the same plane, the upper end of the second fin is located below the upper pipe, the upper end face of the first fin is overlapped with the upper end face of the vertical plate, the lower end face of the second fin is overlapped with the lower end face of the vertical plate, and two sides of the vertical plate are sequentially and fixedly provided with a first radiating fin, a second radiating fin and a second radiating fin are arranged in the direction of the vertical plate, The first radiating fin, the second radiating fin and the third radiating fin extend towards the direction away from the vertical plate respectively, and the first radiating fin, the second radiating fin and the third radiating fin are positioned between the first fin and the second fin.

Preferably, two ends of the second heat sink are respectively fixedly provided with an upper plate and a lower plate which are attached to the peripheries of the upper tube and the lower tube and have a certain gap with the upper tube and the lower tube, the upper plate and the lower plate are respectively positioned on two sides of a plane where the second heat sink is positioned, the upper plate extends around the upper tube in the direction of the first heat sink, and the lower plate extends in the direction of the third heat sink.

Preferably, the upper end of the first heat sink is fixedly provided with a first arc-shaped plate which is attached to the periphery of the upper plate and has a certain gap with the upper plate, the first arc-shaped plate extends in the direction away from the first heat sink, the lower end of the first heat sink is fixedly provided with a second arc-shaped plate which is attached to the periphery of the lower pipe and has a certain gap with the lower pipe, and the second arc-shaped plate extends in the direction away from the lower plate.

Preferably, the upper end of the third heat sink is fixedly provided with a third arc-shaped plate which abuts against the periphery of the upper tube and has a gap with the upper tube, the third arc-shaped plate extends in the direction away from the upper plate, the lower end of the third heat sink is fixedly provided with a fourth arc-shaped plate which abuts against the periphery of the lower plate and has a gap with the lower plate, and the fourth arc-shaped plate extends in the direction away from the first heat sink around the lower tube.

Preferably, the angle formed by the upper plate and the lower plate surrounding the outer peripheries of the upper pipe and the lower pipe is 90 degrees.

Preferably, the angles of the first arc-shaped plate, the second arc-shaped plate, the third arc-shaped plate and the fourth arc-shaped plate are smaller than 90 degrees.

Compared with the prior art, the utility model discloses a fixed first fin and the second fin that sets up at the riser both ends respectively effectively increase heat radiating area to further optimize heat dissipation channel through dislocation set's first fin and second fin, make the heat outside heat dissipation on partial first fin and the second fin, and conflict each other, through the fixed heat radiating area who sets up at the first fin of stand both sides respectively, second fin and third fin further increase the stand, promote the heating effect.

Drawings

FIG. 1 is a view of the overall structure of the present invention;

fig. 2 is a front view of the present invention;

fig. 3 is an overall structural view of the heat dissipating unit;

FIG. 4 is an enlarged view at A in FIG. 3;

fig. 5 is an enlarged view at B in fig. 4.

The mark in the figure is: 1. a heat dissipation unit; 2. feeding a pipe; 3. a lower pipe; 4. a vertical plate; 5. a first fin; 6. a second fin; 7. a first heat sink; 8. a second heat sink; 9. a third heat sink; 10. an upper plate; 11. a lower plate; 12. a first arc-shaped plate; 13. a second arc-shaped plate; 14. a third arc-shaped plate; 15. a fourth arc-shaped plate.

Detailed Description

The invention will be further described with reference to the embodiments shown in the drawings to which: as shown in fig. 1-5, a heat sink with high thermal conductivity is formed by splicing a plurality of heat dissipating units 1, where each heat dissipating unit 1 includes an upper tube 2, a lower tube 3, and a vertical plate 4 fixedly disposed between the upper tube 2 and the lower tube 3, the upper tube 2, the lower tube 3, and the vertical plate 4 are hollow and are communicated with each other, hot water can flow between the upper tube 2, the lower tube 3, and the vertical plate 4, two end surfaces of the vertical plate 4 far away from the upper tube 2 and the lower tube 3 are respectively and fixedly provided with a first fin 5 and a second fin 6, an upper end of the first fin 5 is located on the same plane as the upper tube 2, a lower end of the first fin 5 is located above the lower tube 3, a lower end of the second fin 6 is located on the same plane as the lower tube 3, an upper end of the second fin 6 is located below the upper tube 2, and an upper end surface of the first fin 5 coincides with an upper end surface of the vertical plate 4, the lower end face of the second fin 6 coincides with the lower end face of the vertical plate 4, first radiating fins 7, second radiating fins 8 and third radiating fins 9 are fixedly arranged on the two sides of the vertical plate 4 from the second fin 6 to the first fin 5 in sequence, certain gaps are reserved among the first radiating fins 7, the second radiating fins 8 and the third radiating fins 9, the first radiating fins 7, the second radiating fins 8 and the third radiating fins 9 extend towards the direction far away from the vertical plate 4 respectively, and the first radiating fins 7, the second radiating fins 8 and the third radiating fins 9 are located between the first fin 5 and the second fin 6.

The heat dissipation area is effectively increased by respectively fixing the first fins 5 and the second fins 6 which are arranged at the two ends of the vertical plate 4, the heat dissipation channel is further optimized by the first fins 5 and the second fins 6 which are arranged in a staggered mode, heat on part of the first fins 5 and part of the heat on the second fins 6 are dissipated to the outside and are not in conflict with each other, the heat dissipation area of the vertical column is further increased by respectively fixing the first cooling fins 7, the second cooling fins 8 and the third cooling fins 9 which are arranged on the two sides of the vertical column, and the heating effect is improved.

The two ends of the second heat sink 8 are respectively fixedly provided with an upper plate 10 and a lower plate 11 which are attached to the peripheries of the upper tube 2 and the lower tube 3 and have a certain gap with the upper tube 2 and the lower tube 3, the upper plate 10 and the lower plate 11 are respectively positioned on two sides of the plane where the second heat sink 8 is positioned, the upper plate 10 extends around the upper tube 2 to the direction of the first heat sink 7, and the lower plate 11 extends to the direction of the third heat sink 9. The upper end of the first radiating fin 7 is fixedly provided with a first arc-shaped plate 12 which is attached to the periphery of the upper plate 10 and has a certain gap with the upper plate 10, the first arc-shaped plate 12 extends towards the direction far away from the first radiating fin 7, the lower end of the first radiating fin 7 is fixedly provided with a second arc-shaped plate 13 which is attached to the periphery of the lower pipe 3 and has a certain gap with the lower pipe 3, and the second arc-shaped plate 13 extends towards the direction far away from the lower plate 11. The upper end of the third heat sink 9 is fixedly provided with a third arc-shaped plate 14 which is attached to the periphery of the upper tube 2 and has a little gap with the upper tube 2, the third arc-shaped plate 14 extends in the direction away from the upper plate 10, the lower end of the third heat sink 9 is fixedly provided with a fourth arc-shaped plate 15 which is attached to the periphery of the lower plate 11 and has a certain gap with the lower plate 11, and the fourth arc-shaped plate 15 extends in the direction away from the first heat sink 7 around the lower tube 3. The upper plate 10 and the lower plate 11 which are respectively and fixedly arranged at two ends of the second radiating fin 8 are used, the first arc-shaped plate 12 and the second arc-shaped plate 13 which are respectively and fixedly arranged at two ends of the first radiating fin 7 are respectively used, the third arc-shaped plate 14 and the fourth arc-shaped plate 15 which are respectively and fixedly arranged at two ends of the third radiating fin 9 are used for further prolonging the lengths of the first radiating fin 7 and the second radiating fin 8 and the third radiating fin 9, the radiating range is effectively increased, and after the heat emitted by the upper pipe 2 and the lower pipe 3 is absorbed by the upper plate 10, the lower plate 11, the first arc-shaped plate 12, the second arc-shaped plate 13, the third arc-shaped plate 14 and the fourth arc-shaped plate 15, three persons are carried out through the first radiating fin 7 with a larger area, the third radiating fin 9 and the third radiating fin 9, the radiating efficiency is higher, and the better heating effect is achieved.

The angle of the upper plate 10 and the lower plate 11 enclosing the peripheries of the upper pipe 2 and the lower pipe 3 is 90 degrees. The angles of the first arc-shaped plate 12, the second arc-shaped plate 13, the third arc-shaped plate 14 and the fourth arc-shaped plate 15 are less than 90 degrees. Make the one end that upper tube 2 kept away from lower tube 3 and the one end that lower tube 3 kept away from upper tube 2 expose completely externally, the radiating effect is better.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (6)

1. The radiator with high thermal conductivity is characterized by being formed by splicing a plurality of radiating units (1), wherein each radiating unit (1) comprises an upper pipe (2), a lower pipe (3) and a vertical plate (4) fixedly arranged between the upper pipe (2) and the lower pipe (3), the upper pipe (2), the lower pipe (3) and the vertical plate (4) are hollow and are communicated with each other, hot water can flow among the upper pipe (2), the lower pipe (3) and the vertical plate (4), first fins (5) and second fins (6) are fixedly arranged on two end faces, far away from the upper pipe (2) and the lower pipe (3), of the vertical plate (4), the upper ends of the first fins (5) and the upper pipe (2) are positioned on the same plane, the lower ends of the first fins (5) are positioned above the lower pipe (3), the lower ends of the second fins (6) and the lower pipe (3) are positioned on the same plane, the upper end of the second fin (6) is positioned below the upper tube (2), the upper end surface of the first fin (5) is superposed with the upper end surface of the vertical plate (4), the lower end surface of the second fin (6) is superposed with the lower end surface of the vertical plate (4), a first radiating fin (7), a second radiating fin (8) and a third radiating fin (9) are sequentially and fixedly arranged on the two sides of the vertical plate (4) from the second fin (6) to the first fin (5), a certain gap is left among the first radiating fin (7), the second radiating fin (8) and the third radiating fin (9), the first radiating fin (7), the second radiating fin (8) and the third radiating fin (9) respectively extend towards the direction far away from the vertical plate (4), and the first radiating fin (7), the second radiating fin (8) and the third radiating fin (9) are positioned between the first fin (5) and the second fin (6).

2. The heat sink with high thermal conductivity as claimed in claim 1, wherein the second heat sink (8) has an upper plate (10) and a lower plate (11) fixed to both ends thereof and abutting against the outer periphery of the upper tube (2) and the lower tube (3) with a gap therebetween, the upper plate (10) and the lower plate (11) are respectively located on both sides of the plane where the second heat sink (8) is located, the upper plate (10) extends around the upper tube (2) in the direction of the first heat sink (7), and the lower plate (11) extends in the direction of the third heat sink (9).

3. A heat sink with high thermal conductivity according to claim 2, wherein the first heat sink (7) is fixedly provided at its upper end with a first arc-shaped plate (12) which abuts against the periphery of the upper plate (10) with a certain gap from the upper plate (10), the first arc-shaped plate (12) extends in a direction away from the first heat sink (7), the first heat sink (7) is fixedly provided at its lower end with a second arc-shaped plate (13) which abuts against the periphery of the lower tube (3) with a certain gap from the lower tube (3), and the second arc-shaped plate (13) extends in a direction away from the lower plate (11).

4. A heat sink with high thermal conductivity according to claim 3, wherein the third heat sink (9) is fixedly provided at its upper end with a third arc-shaped plate (14) abutting against the periphery of the upper tube (2) with a slight gap from the upper tube (2), the third arc-shaped plate (14) extending away from the upper plate (10), and the third heat sink (9) is fixedly provided at its lower end with a fourth arc-shaped plate (15) abutting against the periphery of the lower plate (11) with a gap from the lower plate (11), the fourth arc-shaped plate (15) extending around the lower tube (3) away from the first heat sink (7).

5. A heat sink with high thermal conductivity according to claim 4, wherein the angle of the upper plate (10) and the lower plate (11) around the periphery of the upper tube (2) and the lower tube (3) is 90 degrees.

6. A heat sink with high thermal conductivity according to claim 4, characterized in that the angle of the first (12), second (13), third (14) and fourth (15) arc is less than 90 degrees.

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