CN204165434U - Heat pipe - Google Patents

Abstract

The utility model discloses a kind of heat pipe, it comprises: the housing of sealing; Be covered in the capillary structure of inner walls, in it, form the liquid refrigerant flow channel for liquid Working fluid flow; Be configured in one deck clad of capillary structure inwall interlude, its inner gaseous working medium flow channel formed for supplying gaseous state Working fluid flow; Wherein, gaseous working medium flow channel and liquid refrigerant flow channel interconnect; Wherein, one end of housing is for being placed in form evaporator section on thermal source, and the other end of housing is for being placed on low-temperature receiver to form condensation segment; Wherein, the gaseous working medium formed after evaporator section evaporation process flow to condensation segment along gaseous working medium flow channel and carries out condensation process, and the liquid refrigerant formed after condensation is back to evaporator section along liquid refrigerant flow channel.Heat pipe of the present utility model, structure is simple, and easy to use, perfect heat-dissipating, heat transfer efficiency is high, and the heat utilization efficiency of heat pipe is high.

Description

Heat pipe

Technical field

The utility model relates to technical field of heat dissipation, particularly relates to a kind of heat pipe for dispelling the heat to electronic product.

Background technology

Along with market is to the requirement of electronic product light and thin degree, heat conductor is also more lightening, and in prior art, the heat that thermal source produces discharged in time by usual employing heat pipe.

The heat pipe of prior art generally adopts and covers capillary structure, to form the structure of liquid refrigerant and gaseous state Working fluid flow passage in copper inner walls, but the heat pipe of this kind of structure is due to the restriction in internal heat space, when heat pipe works, the convective resistance of liquid refrigerant and gaseous working medium increases, make the backflow obstruction of liquid refrigerant, therefore heat from heat source can be caused constantly to be stacked in heat pipe, thus to cause heat transfer bad, make heat pipe cannot reach the object of quick heat radiating.

Summary of the invention

The purpose of this utility model is exactly to solve the problem, and provides a kind of heat pipe, and its structure is simple, easy to use, perfect heat-dissipating, and heat transfer efficiency is high, greatly improves the heat utilization efficiency of heat pipe.

For realizing above-mentioned purpose of the present utility model, a kind of heat pipe of the present utility model comprises: the housing of sealing; Be covered in the capillary structure of inner walls, in it, form the liquid refrigerant flow channel for liquid Working fluid flow; Be configured in one deck clad of capillary structure inwall interlude, its inner gaseous working medium flow channel formed for supplying gaseous state Working fluid flow; Wherein, described gaseous working medium flow channel and described liquid refrigerant flow channel interconnect; Wherein, one end of described housing is for being placed in form evaporator section on thermal source, and the other end of described housing is for being placed on low-temperature receiver to form condensation segment; Wherein, the gaseous working medium formed after described evaporator section evaporation process flow to described condensation segment along described gaseous working medium flow channel and carries out condensation process, and the liquid refrigerant formed after condensation is back to described evaporator section along described liquid refrigerant flow channel.

Wherein, described clad is made up of Heat Conduction Material.

Wherein, described clad is metal level.

Preferably, described clad is layers of copper or aluminium foil layer.

Or described clad is rubberised layer.

Wherein, the inwall being in the capillary structure of described heat pipe evaporator section do not have configuration packet coating.

Wherein, the inwall being in the capillary structure of described heat pipe condenser section do not have configuration packet coating.

Compared with prior art, heat pipe of the present utility model has following beneficial effect:

1) heat pipe of the present utility model is at capillary structure inner wall arrangement clad, and by clad by liquid refrigerant flow channel and gaseous state Working fluid flow passage isolated, thus make gaseous state, liquid refrigerant produce convection current, and then reduce the convective resistance of gas-liquid, improve radiating efficiency;

2) clad of the present utility model is made up of the material that heat conductivility is good, therefore good heat conductivity, thus improves heat transfer efficiency;

3) heat pipe structure of the present utility model is simple, and easy to use, heat pipe utilization rate is high, perfect heat-dissipating.

Below in conjunction with accompanying drawing, the utility model is described in detail.

Accompanying drawing explanation

Fig. 1 is the half sectional view of the utility model heat pipe;

Fig. 2 is the schematic diagram of the flow direction of the hot intraductal working medium of the utility model;

Fig. 3 is the A-A of heat pipe shown in Fig. 1 the first structural representation to sectional view;

Fig. 4 is the B-B of heat pipe shown in Fig. 1 the first structural representation to sectional view;

Fig. 5 is the second structural representation of the A-A of heat pipe shown in Fig. 1 to sectional view;

Fig. 6 is the second structural representation of the B-B of heat pipe shown in Fig. 1 to sectional view.

Description of reference numerals: 1-housing; 2-capillary structure; 3-clad; 4-evaporator section; 5-condensation segment.

Detailed description of the invention

As shown in Figure 1, be the structural representation of heat pipe of the present utility model, as seen from the figure, heat pipe comprises: the housing 1 of sealing; By the capillary structure 2 that housing 1 inwall covers completely, in it, form the liquid refrigerant flow channel be used for for liquid Working fluid flow; Be configured in one deck clad 3 (as shown in Fig. 3, Fig. 5) of capillary structure 2 inwall interlude, its inner gaseous working medium flow channel formed for supplying gaseous state Working fluid flow; Wherein, the two ends of gaseous working medium flow channel and liquid refrigerant flow channel interconnect.

Wherein, one end (i.e. one end of heat pipe) of housing 1 is for being placed in form evaporator section 4 on thermal source, and the other end (i.e. the other end of heat pipe) of housing 1 is for being placed on low-temperature receiver to form condensation segment 5.Preferably, the inwall being in the capillary structure at heat pipe evaporator section and condensation segment place all do not have configuration packet coating (as Fig. 4, shown in Fig. 6, wherein, Fig. 4, Fig. 6 only illustrates the structure of the heat pipe at condensation segment place, and the structure of the heat pipe of evaporating section and condensation segment place is identical, therefore omit accompanying drawing), so that gaseous working medium flow channel is connected with liquid refrigerant flow channel, thus when gaseous working medium is converted into liquid refrigerant at condensation segment, liquid refrigerant flow channel can be entered into from gaseous working medium flow channel, and liquid refrigerant is when evaporator section is converted into gaseous working medium, gaseous working medium flow channel can be entered into from liquid refrigerant flow channel.

Wherein, clad of the present invention can be made up of the material that heat conductivility is good, as being made up of metal material, preferably, and the layers of copper that clad 3 becomes for copper or the aluminium foil layer that aluminium is made; Or clad of the present invention also can adopt rubberised layer.

Wherein, when clad 3 of the present invention is made up of metal material, this clad can be configured in the inwall of capillary structure 2 by electric plating method, also can be configured in the inwall of capillary structure 2 by the method for coating, can also be configured in the inwall of capillary structure 2 by the method for sintering.And when clad of the present invention adopts rubberised layer, this clad is configured in the inwall of capillary structure by the mode of coating.

When configuration packet coating, the interior walls be smooth of clad should be made, to form the level and smooth gaseous working medium flow channel surrounded by clad inwall, and pass through clad, by liquid refrigerant flow channel and gaseous state Working fluid flow passage isolated, the gaseous state making to be isolated by clad, liquid refrigerant can not produce convection current, thus reduce the convective resistance of gas-liquid.

Wherein, housing 1 of the present utility model can adopt the material of prior art to make, and capillary structure 2 can adopt the structure of prior art.

Wherein, as shown in Figure 3, Figure 4, the shape of cross section of the utility model heat pipe can be rounded, or as shown in Figure 5, Figure 6, the shape of cross section of heat pipe also can be Long Circle, certainly, in concrete application process, the shape of cross section of heat pipe can also adopt other shape.

Wherein, thermal source of the present utility model is the source of heat release of electronic product, as operationally produced the components and parts such as CPU or GPU of amount of heat; And low-temperature receiver of the present utility model can for being welded on one or more radiators of heat pipe condenser section, also can for being arranged on the one or more fans near heat pipe condenser section, can also for be placed in the radiator of heat pipe condenser section and the combination of fan simultaneously, by arranging the method for low-temperature receiver at heat pipe condenser section, make heat pipe the heat at thermal source place can be delivered to low-temperature receiver fast, thus the heat that thermal source produces is distributed timely.

In use, according to the needs of actual conditions, the heat flux of heat pipe can be increased by increasing the methods such as the lateral dimension of heat pipe, thus heat pipe can be made to be distributed over by the heat of thermal source fast, and make heat pipe be applicable to the larger system of power consumption.

Wherein, adding man-hour, heat pipe of the present utility model should be made to become the closed conductor of negative pressure.In use, one end of heat pipe is placed on thermal source, becomes evaporator section with the heat making described one end of heat pipe absorb thermal source, and the other end of heat pipe is placed on low-temperature receiver, become condensation segment to make the other end distribute heat of heat pipe.When heat pipe absorbs the heat of thermal source, liquid refrigerant in evaporator section is heated and evaporates, under the impact of pressure reduction, the condensation segment that the gaseous working medium formed after evaporation flow to heat pipe along smooth gaseous working medium flow channel carries out condensation process, the liquid refrigerant changed into by gaseous working medium after condensation enters into liquid refrigerant flow channel, and be back to the evaporator section of heat pipe along liquid refrigerant flow channel, so that the evaporator section liquid towards working medium of heat pipe proceeds evaporation process.The repetitive operation of Infinite Cyclic like this, can go out the heat Quick diffusing of thermal source, reach the object of heat radiation.

Because heat pipe of the present utility model adopts clad to form gaseous working medium flow channel, adopts capillary structure to form liquid refrigerant flow channel, therefore by isolated for the flow channel of liquid refrigerant and gaseous working medium, when avoiding heat pipe of the prior art work, liquid state and gaseous working medium make heat be stacked in heat pipe because generation convective resistance, make heat pipe cannot the defect of quick heat radiating, thus make heat pipe for thermal conductivity performance of the present utility model good, the heat transfer efficiency of very big raising heat pipe and radiating efficiency, improve the utilization rate of heat pipe.

When adopting heat pipe of the present utility model to conduct heat, heat-transferring method comprises the steps:

Capillary structure 2 is covered completely on the inwall of heat pipe closure casing 1, to form liquid refrigerant flow channel in the capillary structure 2 of heat pipe;

One deck clad 3 is configured at the interlude of capillary structure 2 inwall, to form the gaseous working medium flow channel for making gaseous working medium flow to the other end from heat pipe one end in clad 3 inside of heat pipe, thus to form the heat pipe with liquid refrigerant flow channel and the gaseous state Working fluid flow passage interconnected;

One end of heat pipe is placed on thermal source, so that the heat that one end of heat pipe absorbs thermal source becomes evaporator section;

The other end of heat pipe is placed on low-temperature receiver, so that the other end distribute heat of heat pipe becomes condensation segment;

Wherein, when heat pipe absorbs the heat of thermal source, liquid refrigerant in evaporator section is heated and carries out evaporation formation gaseous working medium, under the impact of pressure reduction, the condensation segment that gaseous working medium flow to heat pipe along gaseous working medium flow channel carries out condensation process, the liquid refrigerant changed into after condensation enters into liquid refrigerant flow channel, and is back to the evaporator section of heat pipe along liquid refrigerant flow channel.The repetitive operation of Infinite Cyclic like this, make gas, liquid binary states working medium respectively along the flowing of the Infinite Cyclic in gaseous working medium flow channel and liquid refrigerant flow channel of the direction shown in arrow in Fig. 2, thus the heat Quick diffusing of thermal source can be gone out, reach the object of heat radiation.

Although be explained in detail the utility model above; but the utility model is not limited thereto; those skilled in the art can modify according to principle of the present utility model; therefore, all various amendments carried out according to principle of the present utility model all should be understood to fall into protection domain of the present utility model.

Claims (7)

1. a heat pipe, is characterized in that, comprising:

The housing of sealing;

Be covered in the capillary structure of inner walls, in it, form the liquid refrigerant flow channel for liquid Working fluid flow;

Be configured in one deck clad of capillary structure inwall interlude, its inner gaseous working medium flow channel formed for supplying gaseous state Working fluid flow;

Wherein, described gaseous working medium flow channel and described liquid refrigerant flow channel interconnect;

Wherein, one end of described housing is for being placed in form evaporator section on thermal source, and the other end of described housing is for being placed on low-temperature receiver to form condensation segment;

Wherein, the gaseous working medium formed after described evaporator section evaporation process flow to described condensation segment along described gaseous working medium flow channel and carries out condensation process, and the liquid refrigerant formed after condensation is back to described evaporator section along described liquid refrigerant flow channel.

2. heat pipe according to claim 1, is characterized in that, the inwall being in the capillary structure of described heat pipe evaporator section does not have configuration packet coating.

3. heat pipe according to claim 1, is characterized in that, the inwall being in the capillary structure of described heat pipe condenser section does not have configuration packet coating.

4. the heat pipe according to claim 1 or 2 or 3, it is characterized in that, described clad is made up of Heat Conduction Material.

5. heat pipe according to claim 4, is characterized in that, described clad is metal level.

6. heat pipe according to claim 5, is characterized in that, described clad is layers of copper or aluminium foil layer.

7. the heat pipe according to claim 1 or 2 or 3, is characterized in that, described clad is rubberised layer.