CN203797827U - Temperature control system - Google Patents

Abstract

The utility model provides a temperature control system which comprises a first heat exchanger (11), a second heat exchanger (12), an electronic element (13), a radiating device (20) and a refrigerant cooling device (30). The second heat exchanger (12) is communicated with the first heat exchanger (11); the radiating device (20) is arranged between the first heat exchanger (11) and the second heat exchanger (12), absorbs heat emitted by the electronic element (13) and is provided with refrigerant flow channels (21); the refrigerant cooling device (30) is arranged between the radiating device (20) and the second heat exchanger (12). The temperature control system has the advantage that a radiating effect can be improved for the electronic element.

Description

Temperature control system

Technical field

The utility model relates to temperature control technology field, in particular to a kind of temperature control system.

Background technology

The heat radiation of the power component in the electric-controlled parts of existing direct-current variable-frequency multi-connection off-premises station mainly adopts fan cooling, but radiating effect is bad, and especially the radiating effect under hot environment is poorer.

Utility model content

The utility model aims to provide a kind of better temperature control system of radiating effect that makes electronic component.

To achieve these goals, the utility model provides a kind of temperature control system, comprising: First Heat Exchanger; The second heat exchanger, is connected with First Heat Exchanger; Electronic component; Temperature control system also comprises: heat abstractor, and be arranged between First Heat Exchanger and the second heat exchanger and absorb the heat that electronic component distributes, heat abstractor has refrigerant channel; Refrigerant heat sink, is arranged between heat abstractor and the second heat exchanger.

Further, refrigerant heat sink is subcooler.

Further, subcooler has the first opening, the second opening, the 3rd opening and the 4th opening, the first opening is connected with the second opening, the 3rd opening is connected with the 4th opening, the first opening and the 3rd opening are all connected with heat abstractor, between the 3rd opening and heat abstractor, be provided with first throttle device, the second opening is connected with the second heat exchanger.

Further, between the first opening and the second opening, have refrigerant first-class to, between the 3rd opening and the 4th opening, have refrigerant second to, refrigerant first-class to refrigerant second to contrary.

Further, also comprise: gas-liquid separator, the 4th opening is connected with gas-liquid separator.

Further, also comprise: four-way change-over valve, the pipeline between air inlet and the four-way change-over valve of the 4th opening and gas-liquid separator is connected.

Further, also comprise: the second throttling arrangement, is arranged between First Heat Exchanger and heat abstractor; Check valve, in parallel with the second throttling arrangement and be arranged between First Heat Exchanger and heat abstractor, check valve only allows refrigerant to be flowed to the second heat exchanger by First Heat Exchanger.

Further, heat abstractor also comprises: heat sink, has refrigerant channel in heat sink.

Further, First Heat Exchanger is connected with refrigerant heat sink by refrigerant line, and refrigerant line embeds in refrigerant channel.

Further, heat abstractor also comprises: the first heat sink, is provided with first and holds groove on the first heat sink; The second heat sink, is fixed on the first heat sink, is provided with second and holds groove on the second heat sink, and first holds groove and second holds groove and match and form refrigerant channel.

Further, between refrigerant line and heat abstractor, be filled with heat conduction vibration damping thing.

Application the technical solution of the utility model, owing to being provided with heat abstractor between First Heat Exchanger and the second heat exchanger, and heat abstractor has refrigerant channel, can the flow through refrigerant channel of heat abstractor of refrigerant between First Heat Exchanger and the second heat exchanger, again because the refrigerant between First Heat Exchanger and the second heat exchanger is liquid refrigerants, liquid refrigerant temperature is lower, and therefore, low temperature liquid refrigerant is lowered the temperature to heat abstractor.Because heat abstractor absorbs the heat that electronic component distributes, therefore, by the heat abstractor after refrigerant cooling, electronic component is lowered the temperature, the temperature of electronic component is reduced, be equivalent to adopt refrigerant to lower the temperature to electronic component, due to the characteristic of refrigerant self, the cooling-down effect of refrigerant is more remarkable.As the above analysis, temperature control system of the present utility model has improved the radiating effect of electronic component.

Brief description of the drawings

The Figure of description that forms the application's a part is used to provide further understanding of the present utility model, and schematic description and description of the present utility model is used for explaining the utility model, does not form improper restriction of the present utility model.In the accompanying drawings:

Fig. 1 shows the pipeline schematic diagram according to the embodiment of temperature control system of the present utility model;

The temperature control system that Fig. 2 shows Fig. 1 is applied to the partial schematic sectional view on air-conditioner.

Wherein, the Reference numeral in above-mentioned figure is as follows:

11, First Heat Exchanger; 12, the second heat exchanger; 13, electronic component; 14, the second throttling arrangement; 15, check valve; 16, refrigerant line; 17, compressor; 18, separator; 19, four-way change-over valve; 20, heat abstractor; 21, refrigerant channel; 24, heat conduction vibration damping thing; 25, the first heat sink; 26, the second heat sink; 30, refrigerant heat sink; 31, the first opening; 32, the second opening; 33, the 3rd opening; 34, the 4th opening; 35, first throttle device; 40, gas-liquid separator.

Detailed description of the invention

It should be noted that, in the situation that not conflicting, the feature in embodiment and embodiment in the application can combine mutually.Describe below with reference to the accompanying drawings and in conjunction with the embodiments the utility model in detail.

As depicted in figs. 1 and 2, the temperature control system of the present embodiment comprises First Heat Exchanger 11, the second heat exchanger 12, electronic component 13, heat abstractor 20 and refrigerant heat sink 30.The second heat exchanger 12 is connected to realize flowing of refrigerant between with First Heat Exchanger 11.Heat abstractor 20 is arranged between First Heat Exchanger 11 and the second heat exchanger 12 and absorbs the heat that electronic component 13 distributes, and heat abstractor 20 has refrigerant channel 21, and preferably, heat abstractor 20 contacts with electronic component 13.Refrigerant heat sink 30 is arranged between heat abstractor 20 and the second heat exchanger 12.The temperature control system of the present embodiment also comprises compressor 17, separator 18 and four-way change-over valve 19, wherein, the mode of communicating of compressor 17, separator 18, four-way change-over valve 19, First Heat Exchanger 11 and the second heat exchanger 12 can adopt in existing air-conditioner the connected relation between corresponding component to realize process of refrigerastion.

The temperature control system of application the present embodiment, owing to being provided with heat abstractor 20 between First Heat Exchanger 11 and the second heat exchanger 12, and heat abstractor 20 has refrigerant channel 21, can the flow through refrigerant channel 21 of heat abstractor 20 of refrigerant between First Heat Exchanger 11 and the second heat exchanger 12, again because the refrigerant between First Heat Exchanger 11 and the second heat exchanger 12 is liquid refrigerants, liquid refrigerant temperature is lower, and therefore, low temperature liquid refrigerant is lowered the temperature to heat abstractor 20.Because heat abstractor 20 absorbs the heat that electronic component 13 distributes, therefore, by the heat abstractor 20 after refrigerant cooling, electronic component 13 is lowered the temperature, the temperature of electronic component 13 is reduced, be equivalent to adopt refrigerant to lower the temperature to electronic component 13, due to the characteristic of refrigerant self, the cooling-down effect of refrigerant is more remarkable.As the above analysis, the temperature control system of the present embodiment has improved the radiating effect of electronic component 13.

Because refrigerant and the electronic component 13 of the heat abstractor 20 of flowing through have carried out heat exchange, the temperature that flows out the refrigerant of heat abstractor 20 can increase, after the refrigerant that temperature increases to some extent flows into the second heat exchanger 12, the endothermic effect of the refrigerant in the second heat exchanger 12 reduces, can cause like this refrigeration to reduce, therefore, the temperature control system of the present embodiment also tool has the following advantages, because refrigerant heat sink 30 is arranged between heat abstractor 20 and the second heat exchanger 12, therefore, the refrigerant that flows to the second heat exchanger 12 by the heat abstractor 20 refrigerant heat sink 30 of can flowing through, because refrigerant heat sink 30 is lowered the temperature to its refrigerant of flowing through, the temperature that is refrigerant heat sink 30 refrigerant that flows to the second heat exchanger 12 reduces, improve the endothermic effect of the refrigerant in the second heat exchanger 12, and then raising refrigeration.

In the present embodiment, refrigerant heat sink 30 is subcooler.Subcooler stable performance, and convenient installation.

As shown in Figure 1, in the present embodiment, subcooler has the first opening 31, the second opening 32, the 3rd opening 33 and the 4th opening 34, the first opening 31 is connected with the second opening 32, the 3rd opening 33 is connected with the 4th opening 34, the first opening 31 and the 3rd opening 33 are all connected with heat abstractor 20, be provided with first throttle device 35, the second openings 32 and be connected with the second heat exchanger 12 between the 3rd opening 33 and heat abstractor 20.In the situation that first throttle device 35 is opened, the refrigerant flowing out through heat abstractor 20 is divided into two-way, one road flows into the first opening 31, and another road flows into the 3rd opening 33 after first throttle device 35, and the pressure of the refrigerant of process first throttle device 35 reduces and be accompanied by the reduction of temperature.Because the first opening 31 is connected with the second opening 32, the 3rd opening 33 is connected with the 4th opening 34, therefore, the refrigerant of flowing through between the refrigerant of flowing through between the first opening 31 and the second opening 32 and the 3rd opening 33 and the 4th opening 34 carries out heat exchange, from the second opening 32 flow out and flow into the second heat exchanger 12 refrigerant temperature reduce, through heat exchange and temperature raise refrigerant flow out from the 4th opening 34.In the situation that first throttle device 35 is closed, refrigerant can not flow into the 3rd opening 33, and subcooler is not worked, and that is to say, the subcooler with said structure also can allow refrigerant to pass through in idle situation.First throttle device 35 is preferably electromagnetic expanding valve.

In the present embodiment, between the first opening 31 and the second opening 32, have refrigerant first-class to, between the 3rd opening 33 and the 4th opening 34, have refrigerant second to, refrigerant first-class to refrigerant second to contrary.

As shown in Figure 1, the temperature control system of the present embodiment also comprises that gas-liquid separator 40, the four openings 34 are connected with gas-liquid separator 40.The refrigerant that temperature raises flows out and flows into gas-liquid separator 40 from the 4th opening 34, and gas-liquid separator 40 will stay liquid refrigerants to deposit therein, prevent that liquid refrigerants from entering in compressor 17, causes the damage of compressor 17.

The temperature control system of the present embodiment is preferably refrigeration system, the condenser that First Heat Exchanger 11 is refrigeration system, the evaporimeter that the second heat exchanger 12 is refrigeration system.Further, the temperature control system of the present embodiment can be also the temperature control system of air-conditioner, the outdoor unit heat exchanger that First Heat Exchanger 11 is air-conditioner, the indoor set heat exchanger that the second heat exchanger 12 is air-conditioner.As shown in Figure 1, in the present embodiment, the pipeline between air inlet and the four-way change-over valve 19 of the 4th opening 34 and gas-liquid separator 40 is connected.

As shown in Figure 1, the temperature control system of the present embodiment also comprises the second throttling arrangement 14 and check valve 15.The second throttling arrangement 14 is arranged between First Heat Exchanger 11 and heat abstractor 20; Check valve 15 is in parallel with the second throttling arrangement 14 and be arranged between First Heat Exchanger 11 and heat abstractor 20, and check valve 15 only allows refrigerant to be flowed to the second heat exchanger 12 by First Heat Exchanger 11.In the time that air-conditioner freezes, the second throttling arrangement 14 cuts out, and refrigerant flows to form circulation through check valve 15; In the time of air conditioner heat-production, the second throttling arrangement 14 is opened, and refrigerant flows to form circulation through the second throttling arrangement 14.The second throttling arrangement 14 plays the effect of step-down cooling equally.The second throttling arrangement 14 is preferably electromagnetic expanding valve.

As shown in Figure 1, in the present embodiment, First Heat Exchanger 11 is connected with refrigerant heat sink 30 by refrigerant line 16, and refrigerant line 16 embeds in refrigerant channel 21.Said structure can prevent that refrigerant from directly contacting with heat abstractor 20, but still interior mobile at refrigerant line 16, prevents the leakage of refrigerant, and has avoided the abutting joint of refrigerant line 16 with refrigerant channel 21, reduces installation cost, simplifies installation procedure.Certainly, refrigerant line 16 can not pass refrigerant channel 21, and refrigerant directly contacts with heat abstractor 20.

In the present embodiment, refrigerant channel 21 has multiple parallel-segment that are parallel to each other and extend, and between adjacent two parallel-segment, is connected with linkage section.The refrigerant channel 21 of said structure is equivalent to the bending of carrying out, like this, increase the contact area of refrigerant and heat abstractor 20, indirectly increased the contact area of refrigerant and electronic component 13 simultaneously, increase the cooling-down effect of refrigerant, and then improved the radiating effect of electronic component 13.In addition, refrigerant in the time that the refrigerant channel 21 of said structure flows every through linkage section will Speed Reduction some, like this, increased refrigerant and 13 times of contact of electronic component, when having improved the cooling-down effect of refrigerant, improved the utilization rate of refrigerant.

As shown in Figure 2, in the present embodiment, between refrigerant line 16 and heat abstractor 20, be filled with heat conduction vibration damping thing 24.Said structure makes refrigerant line 16 and heat abstractor 20 heat transfer effects better.When heat conduction vibration damping thing 24 is avoided temperature control system operation, the vibration of the refrigerant line 16 causing is delivered to electronic component 13, causes the damage of electronic component 13.

As shown in Figure 2, in the present embodiment, heat abstractor 20 also comprises heat sink, has refrigerant channel 21 in heat sink, and refrigerant channel 21 is positioned at plank frame, convenient manufacture.

As shown in Figure 2, in the present embodiment, heat abstractor 20 also comprises the first heat sink 25 and the second heat sink 26, also can say, heat sink comprises the first heat sink 25 and the second heat sink 26.On the first heat sink 25, be provided with first and hold groove.The second heat sink 26 is fixed on the first heat sink 25, is provided with second and holds groove on the second heat sink 26, and first holds groove and second holds groove and match and form refrigerant channel 21.Said structure has not only increased the contact area with electronic component 13, facilitates refrigerant line 16 is arranged in refrigerant channel 21 simultaneously.In addition, heat abstractor 20 can be also the pipeline of bending, or straight tube.Preferably, the first heat sink 25 contacts with electronic component 13.

In the present embodiment, electronic component 13 is the power component in control panel.

The foregoing is only preferred embodiment of the present utility model, be not limited to the utility model, for a person skilled in the art, the utility model can have various modifications and variations.All within spirit of the present utility model and principle, any amendment of doing, be equal to replacement, improvement etc., within all should being included in protection domain of the present utility model.

Claims (11)

1. a temperature control system, comprising:

First Heat Exchanger (11);

The second heat exchanger (12), is connected with described First Heat Exchanger (11);

Electronic component (13);

It is characterized in that, described temperature control system also comprises:

Heat abstractor (20), is arranged between described First Heat Exchanger (11) and described the second heat exchanger (12) and absorbs the heat that described electronic component (13) distributes, and described heat abstractor (20) has refrigerant channel (21);

Refrigerant heat sink (30), is arranged between described heat abstractor (20) and described the second heat exchanger (12).

2. temperature control system according to claim 1, is characterized in that, described refrigerant heat sink (30) is subcooler.

3. temperature control system according to claim 2, it is characterized in that, described subcooler has the first opening (31), the second opening (32), the 3rd opening (33) and the 4th opening (34), described the first opening (31) is connected with described the second opening (32), described the 3rd opening (33) is connected with described the 4th opening (34), described the first opening (31) and described the 3rd opening (33) are all connected with described heat abstractor (20), between described the 3rd opening (33) and described heat abstractor (20), be provided with first throttle device (35), described the second opening (32) is connected with described the second heat exchanger (12).

4. temperature control system according to claim 3, it is characterized in that, between described the first opening (31) and described the second opening (32), have refrigerant first-class to, between described the 3rd opening (33) and described the 4th opening (34), have refrigerant second to, described refrigerant first-class to described refrigerant second to contrary.

5. according to the temperature control system described in claim 3 or 4, it is characterized in that, also comprise:

Gas-liquid separator (40), described the 4th opening (34) is connected with described gas-liquid separator (40).

6. temperature control system according to claim 5, is characterized in that, also comprises:

Four-way change-over valve (19), the pipeline between air inlet and the described four-way change-over valve (19) of described the 4th opening (34) and described gas-liquid separator (40) is connected.

7. temperature control system according to claim 1, is characterized in that, also comprises:

The second throttling arrangement (14), is arranged between described First Heat Exchanger (11) and described heat abstractor (20);

Check valve (15), in parallel with described the second throttling arrangement (14) and be arranged between described First Heat Exchanger (11) and described heat abstractor (20), described check valve (15) only allows refrigerant to be flowed to the second heat exchanger (12) by described First Heat Exchanger (11).

8. temperature control system according to claim 1, is characterized in that, described heat abstractor (20) also comprises:

Heat sink, has described refrigerant channel (21) in described heat sink.

9. temperature control system according to claim 1, is characterized in that, described First Heat Exchanger (11) is connected with described refrigerant heat sink (30) by refrigerant line (16), and described refrigerant line (16) embeds in described refrigerant channel (21).

10. temperature control system according to claim 1, is characterized in that, described heat abstractor (20) also comprises:

The first heat sink (25), is provided with first on described the first heat sink (25) and holds groove;

The second heat sink (26), is fixed on described the first heat sink (25) upper, is provided with second and holds groove on described the second heat sink (26), and described first holds groove and described second holds groove and match and form described refrigerant channel (21).

11. temperature control systems according to claim 9, is characterized in that, between described refrigerant line (16) and described heat abstractor (20), are filled with heat conduction vibration damping thing (24).