CN205245859U - Heat absorption heat abstractor - Google Patents

Abstract

The utility model provides a heat absorption heat abstractor, heat absorption heat abstractor includes: storage unit, heat absorption unit and heat dissipation unit, storage unit, heat absorption unit and heat dissipation unit connect in proper order in order, heat dissipation unit terminal with the storage unit connection. The utility model discloses can solve the heat dissipation problem of power plant's transformer in the poor area in water -deficient area or limit, can leave the temperature in the device that generates heat in addition in arid water -deficient's the local small plant that builds, the availability factor of the transformer of improvement has increased productivity ratio.

Description

A kind of heat radiator device

Technical field

The utility model relates to heat-exchanger rig field, is specifically related to a kind of heat radiator device.

Background technology

At present, due to global energy crisis and environmental problem, energy-saving and emission-reduction have become hotter topic. In production, often have mechanical part and produce a large amount of high temperature, cannot dissipation, cause organism fever, impact operation. Existing method is all to deal with problems by water-cooled, but waste water resource is more serious. In place or the area thoroughly, limit of lack of water, it is particularly important that water resource seems. Therefore cannot realize good effect. In the process of generating, there is the situation of a large amount of body heat radiations. Therefore in the poor place of water resource, electric power resource is also relatively deficient, has brought a lot of inconvenience to life. Therefore exigence is a kind of energy-conservation, can effectively absorb heat, dispel the heat, and adopts the device that recycles water.

Utility model content

The utility model object is to provide a kind of heat radiator device, and described heat radiator device can effectively promote heat transfer efficiency. Solve the problem of desert area, areas of serious, poor area, limit, border sentry Cali circulation water electricity generation.

For achieving the above object, the concrete technical scheme of the utility model is as follows:

A kind of heat radiator device, described heat radiator device comprises: memory cell, heat absorbing units and heat-sink unit, described memory cell, heat absorbing units and heat-sink unit are connected successively in turn, and described heat-sink unit end is connected with described memory cell.

Further, described memory cell comprises a heat exchanging fluid storage box, in described heat exchanging fluid storage box, be equipped with heat exchanging fluid, described heat exchanging fluid storage box has an outlet and an entrance, described heat absorbing units comprises multiple the first heat exchange box that connect successively, multiple described the first heat exchange box longitudinal arrangements, described heat-sink unit comprises multiple the second heat exchange box that connect successively, multiple described the second heat exchange box longitudinal arrangements.

Further, described heat exchanging fluid storage box outlet is connected with the first heat exchange box bottom of the described heat absorbing units bottom by pipeline, the first heat exchange box top of the described heat absorbing units the superiors is connected with the second heat exchange box of the described heat-sink unit bottom by pipeline, and the second heat exchange box of the top layer of described heat-sink unit is connected with described heat exchanging fluid storage box entrance by pipeline.

Further, between two adjacent the first heat exchange box, connect by the first short tube, two first short tubes that are connected with same the first heat exchange box are placed in respectively the first heat exchange box two opposite sides.

Further, between adjacent the second heat exchange box of described heat-sink unit two, connect by one second short tube, two second short tubes that are connected with same the second heat exchange box are placed in respectively the second heat exchange box two opposite sides.

Further, in the pipeline that the second heat exchange box of the top layer of described heat-sink unit is connected with described heat exchanging fluid storage box entrance, be provided with capillary structure.

Further, the second heat exchange box outer wall of described heat-sink unit is provided with multiple heat radiation conduits.

Further, described heat radiator device also comprises power unit, described power unit comprises a pump group and gas fan, described pump group one end is connected with described heat exchanging fluid storage box outlet, the described pump group other end is connected with the first heat exchange box bottom of the described heat absorbing units bottom by pipeline, described gas fan one end is connected with the first heat exchange box of the described heat absorbing units the superiors by pipeline, and described gas is fanned the other end and is connected with the second heat exchange box of the described heat-sink unit bottom by pipeline.

Further, described the first heat exchange box can change with the interface caliber size that described the first short tube is connected, the caliber size of described the first short tube also can change, described the second heat exchange box can change with the interface caliber size that described the second short tube is connected, and the caliber size of described the second short tube also can change.

Further, described heat absorbing units comprises: the first heat exchange box, the first short tube, casing, the first long tube, multiple described the first heat exchange box are arranged in the sidewall of described casing, between described the first heat exchange box, connect by described the first short tube, multiple described the first heat exchange box vertically connect successively, in sidewall of described casing, be symmetrically arranged with the first heat exchange box shown in two row, the edge of described the first long tube setting and described casing, both sides, corner the first heat exchange box bottom is all connected with described the first long tube, described the first heat exchange box is connected with described memory cell, four described the first long tubes that are positioned at corner are connected with described heat-sink unit.

The utility model can solve the problem that the poor area in water-deficient area or limit lacks electric power, can build small plant in the place of drought and water shortage, solve the cooling problem of transformer, frequency converter in world wide, separately the temperature in heater members can be left, improve the service efficiency of machine, increase productivity ratio, produced positive social benefit, increased objective economic benefit to manufacturing industry and unit.

Brief description of the drawings

Fig. 1 is the utility model embodiment mono-structural representation;

Fig. 2 is the utility model embodiment bis-structural representations;

Fig. 3 is the utility model embodiment tri-structural representations;

Fig. 4 is the utility model embodiment tetra-structural representations;

Fig. 5 is that the utility model embodiment tetra-heat absorbing units masters look sectional view;

Fig. 6 is that the utility model embodiment tetra-heat absorbing units are along Fig. 4 A-A sectional view;

Fig. 7 is that the utility model embodiment tetra-heat absorbing units are along Fig. 4 B-B sectional view;

Fig. 8 is the utility model embodiment five structural representations;

Fig. 9 is the utility model embodiment six structural representations;

Figure 10 is the utility model embodiment seven structural representations;

Figure 11 is the utility model embodiment seven heat absorbing units tank wall schematic cross-sections;

Figure 12 is that the utility model embodiment seven heat absorbing units are along top view.

Detailed description of the invention

In order to make the purpose of this utility model, technical scheme and advantage clearer, below in conjunction with drawings and Examples, the utility model is explained in further detail. Should be appreciated that specific embodiment described herein is only for explaining the utility model, and be not used in restriction the utility model.

On the contrary, the utility model contain any defined by claim in marrow of the present utility model and scope, make substitute, amendment, equivalent method and scheme. Further, for the public is had a better understanding to the utility model, in below details of the present utility model being described, detailed some specific detail sections of having described. Do not have for a person skilled in the art the description of these detail sections can understand the utility model completely yet. Below in conjunction with accompanying drawing and detailed description of the invention, the utility model is further illustrated.

[embodiment mono-]

As shown in Figure 1, a kind of heat radiator device, described heat radiator device comprises: memory cell 1, heat absorbing units 2 and heat-sink unit 3, described memory cell 1, heat absorbing units 2 and heat-sink unit 3 are connected successively in turn, described heat-sink unit 3 ends are connected with described memory cell 1, form a circulation, above-mentioned connection all connects by pipeline.

Described memory cell 1 comprises a heat exchanging fluid storage box 11, in described heat exchanging fluid storage box 11, be equipped with heat exchanging fluid, described heat exchanging fluid includes but not limited to as recirculated water, heat conduction wet goods has the fluid of conductive force, described heat exchanging fluid storage box 11 has an outlet and an entrance, described heat absorbing units 2 comprises multiple the first heat exchange box 21 that connect successively, in accompanying drawing, be three the first heat exchange box 21 but quantity is not restricted to three, multiple described the first heat exchange box 21 longitudinal arrangements, between two adjacent the first heat exchange box 21, connect by the first short tube 22, described the first heat exchange box 21 can change with the interface caliber size that described the first short tube 22 is connected, the caliber size of described the first short tube 22 also can change, two first short tubes 22 that are connected with same the first heat exchange box 21 are placed in respectively the first heat exchange box 21 two opposite sides, described heat-sink unit 3 comprises multiple the second heat exchange box 31 that connect successively, in accompanying drawing, be three the second heat exchange box 21 but quantity is not restricted to three, multiple described the second heat exchange box 31 longitudinal arrangements, between two adjacent the second heat exchange box 31, connect by one second short tube 32, described the second heat exchange box 31 can change with the interface caliber size that described the second short tube 32 is connected, the caliber size of described the second short tube 32 also can change, two second short tubes 32 that are connected with same the second heat exchange box 31 are placed in respectively the second heat exchange box 31 two opposite sides, described heat exchanging fluid storage box 11 exports by pipeline and is connected with the first heat exchange box 21 bottoms of described heat absorbing units 2 bottoms, the first heat exchange box 21 top pipelines of described heat absorbing units 2 the superiors are connected with the second heat exchange box 31 of described heat-sink unit 3 bottoms, the second heat exchange box 31 of described heat-sink unit 3 top layers is connected with described heat exchanging fluid storage box 11 entrances by pipeline, in the pipeline that the second heat exchange box 31 of described heat-sink unit 3 top layers is connected with described heat exchanging fluid storage box 11 entrances, be provided with capillary structure, the heat exchange box of described heat absorbing units and described heat-sink unit is snakelike setting, can increase the heat-exchange time of heat exchanging fluid in heat exchange box, fully transferring heat.

When use, described heat absorbing units 2 is arranged in heater element, for example, in power plant's transformer, heat exchanging fluid in described memory cell 1 is to heat absorbing units 2, and because heat absorbing units 2 is placed in hot environment, the first heat exchange box 21 of heat absorbing units 2 absorbs heat and passes to heat exchanging fluid, absorption of fluids heat is converted into diffusion of vapor to heat-sink unit 3, heat-sink unit 3 is dispelled the heat steam heat is distributed by air cooling, and steam coagulates once again for fluid flows back in memory cell 1, reusable edible.

[embodiment bis-]

As shown in Figure 2, the present embodiment and above-described embodiment one are basic identical, unique difference is, described heat radiator device also comprises power unit 4, can accelerate the efficiency of heat conversion, described power unit 4 comprises a pump group 41 and gas fan 42, described pump group 41 one end are connected with described heat exchanging fluid storage box 11 outlets, described pump group 41 other ends are connected with the first heat exchange box 21 bottoms of described heat absorbing units 2 bottoms by pipeline, described gas is fanned 42 one end and is connected with the first heat exchange box 31 of described heat absorbing units 3 the superiors by pipeline, described gas is fanned 42 other ends and is connected with the second heat exchange box 41 of described heat-sink unit 4 bottoms by pipeline.

[embodiment tri-]

As shown in Figure 3, the present embodiment and above-described embodiment one are basic identical, unique difference is, the second heat exchange box 31 outer walls of described heat-sink unit 3 are provided with multiple heat radiation conduits 5, described heat radiation conduit 5 two ends are communicated with described the second heat exchange box 31, increase the contact area of the second heat exchange box 31 with air, improved radiating efficiency.

[embodiment tetra-]

As shown in Fig. 4-7, the present embodiment and above-described embodiment one are basic identical, unique difference is, described heat absorbing units 2 comprises: the first heat exchange box 21, the first short tube 22, casing 23, the first long tube 24, multiple described the first heat exchange box 21 are arranged in the sidewall of described casing 23, between described the first heat exchange box 21, connect by described the first short tube, multiple described the first heat exchange box 21 vertically connect successively, in 23 1 sidewalls of described casing, be symmetrically arranged with the first heat exchange box 21 shown in two row, described the first long tube 24 arranges the edge with described casing 23, both sides, corner the first heat exchange box 21 bottom is all connected with described the first long tube 24, described the first heat exchange box 21 is connected with described memory cell 1, four described the first long tubes 24 that are positioned at corner are connected with described heat-sink unit 3, when use, cold fluid in memory cell 1 injects the interior heat absorption of the first heat exchange box 21, import to the interior heat radiation of heat-sink unit 3 by the first long tube 24 again, in this embodiment, the first heat exchange box 21 is arranged horizontally, also can be vertical layout, when the first heat exchange box 21 is vertically arranged, the snakelike connection successively that is arranged in parallel of multiple the first heat exchange box 21.

[embodiment five]

As shown in Figure 8, in the present embodiment, described heat radiator application of installation is on generating set, and described memory cell 1, pump group 41, generating set, heat-sink unit 3 connect in turn, and generating set, by the fluid heating in pipeline, is transported to heat-sink unit 3 and dispels the heat.

[embodiment six]

As shown in Figure 9, in the present embodiment, described memory cell 1, heat absorbing units 2, fin connect in turn, and described heat absorbing units 2 absorbs the heat that thermal source produces, and is delivered on external fin and dispels the heat.

[embodiment seven]

As shown in Figure 10-12, in the present embodiment, described heat absorbing units 2 is replaceable for having the casing of snakelike tubular cavity, in described casing wall, be equipped with snakelike tubular cavity, in the fluid of heat in tank wall is delivered to cavity, greatly increase the heat-exchange time of fluid, strengthened heat exchange efficiency.

The utility model can solve the problem that the poor area in water-deficient area or limit lacks electric power, can build small plant in the place of drought and water shortage, solve the cooling problem of transformer, frequency converter in world wide, separately the temperature in heater members can be left, improve the service efficiency of machine, increase productivity ratio, produced positive social benefit, increased objective economic benefit to manufacturing industry and unit.

Claims (10)

1. a heat radiator device, it is characterized in that, described heat radiator device comprises: memory cell (1), heat absorbing units (2) and heat-sink unit (3), described memory cell (1), heat absorbing units (2) and heat-sink unit (3) are connected successively in turn, and described heat-sink unit (3) end is connected with described memory cell (1).

2. heat radiator device according to claim 1, it is characterized in that, described memory cell (1) comprises a heat exchanging fluid storage box (11), in described heat exchanging fluid storage box (11), be equipped with heat exchanging fluid, described heat exchanging fluid storage box (11) has an outlet and an entrance, described heat absorbing units (2) comprises multiple the first heat exchange box (21) that connect successively, multiple described the first heat exchange box (21) longitudinal arrangement, described heat-sink unit (3) comprises multiple the second heat exchange box (31) that connect successively, multiple described the second heat exchange box (31) longitudinal arrangement.

3. heat radiator device according to claim 2, it is characterized in that, described heat exchanging fluid storage box (11) outlet is connected with the first heat exchange box (21) bottom of described heat absorbing units (2) bottom by pipeline, the first heat exchange box (21) top of described heat absorbing units (2) the superiors is connected with second heat exchange box (31) of described heat-sink unit (3) bottom by pipeline, and second heat exchange box (31) of the top layer of described heat-sink unit (3) is connected with described heat exchanging fluid storage box (11) entrance by pipeline.

4. heat radiator device according to claim 3, it is characterized in that, between two adjacent the first heat exchange box (21), connect by the first short tube (22), two first short tubes (22) that are connected with same the first heat exchange box (21) are placed in respectively the first heat exchange box (21) two opposite sides.

5. heat radiator device according to claim 4, it is characterized in that, between adjacent the second heat exchange box of described heat-sink unit two (31), connect by one second short tube (32), two second short tubes (32) that are connected with same the second heat exchange box (31) are placed in respectively the second heat exchange box (31) two opposite sides.

6. heat radiator device according to claim 3, it is characterized in that, in the pipeline that second heat exchange box (31) of the top layer of described heat-sink unit (3) is connected with described heat exchanging fluid storage box (11) entrance, be provided with capillary structure.

7. heat radiator device according to claim 2, is characterized in that, the second heat exchange box (31) outer wall of described heat-sink unit (3) is provided with multiple heat radiation conduits (5).

8. heat radiator device according to claim 2, it is characterized in that, described heat radiator device also comprises power unit (4), described power unit (4) comprises a pump group (41) and gas fan (42), described pump group (41) one end is connected with described heat exchanging fluid storage box (11) outlet, described pump group (41) other end is connected with the first heat exchange box (21) bottom of described heat absorbing units (2) bottom by pipeline, described gas fan (42) one end is connected with first heat exchange box (31) of described heat absorbing units (3) the superiors by pipeline, described gas fan (42) other end is connected with second heat exchange box (41) of described heat-sink unit (4) bottom by pipeline.

9. heat radiator device according to claim 5, it is characterized in that, described the first heat exchange box (21) can change with the interface caliber size that described the first short tube (22) is connected, the caliber size of described the first short tube (22) also can change, described the second heat exchange box (31) can change with the interface caliber size that described the second short tube (32) is connected, and the caliber size of described the second short tube (32) also can change.

10. heat radiator device according to claim 1, it is characterized in that, described heat absorbing units (2) comprising: the first heat exchange box (21), the first short tube (22), casing (23), the first long tube (24), multiple described the first heat exchange box (21) are arranged in the sidewall of described casing (23), between described the first heat exchange box (21), connect by described the first short tube (22), multiple described the first heat exchange box (21) vertically connect successively, in (23) sidewalls of described casing, be symmetrically arranged with the first heat exchange box shown in two row (21), described the first long tube (24) arranges the edge with described casing (23), both sides, corner the first heat exchange box (21) bottom is all connected with described the first long tube (24), described the first heat exchange box (21) is connected with described memory cell (1), four described the first long tubes (24) that are positioned at corner are connected with described heat-sink unit (3).