CN109114839A - air conditioning system - Google Patents

Abstract

The present invention relates to an air conditioning apparatus, and more particularly to an air conditioning system. The invention provides an air-conditioning system capable of utilizing an air-conditioning refrigerant to dissipate heat of a mainboard, aiming at the problem of low heat dissipation efficiency of the existing air-conditioning mainboard. The air conditioning system comprises a compressor, a first heat exchanger, a throttling assembly and a second heat exchanger which are sequentially connected to form a refrigerant circulating system, and further comprises a heat dissipation assembly, wherein the heat dissipation assembly is connected with the throttling assembly in series and used for dissipating heat of a main board of the air conditioning system. Because the active heat dissipation mode of heat absorption of the refrigerant is adopted, the heat dissipation efficiency of the mainboard is high, excessive electric control devices do not need to be added, and the cost is low.

Description

Air-conditioning system

Technical field

The present invention relates to a kind of conditioners, more particularly to a kind of air-conditioning system.

Background technique

A large amount of heat is issued during convertible frequency air-conditioner main board work, mainboard temperature is caused to rise, and when being more than setting value, is Mainboard is protected not to be burned, air-conditioning can reduce compressor operating frequency or directly shutdown.In order to solve heat dissipation problem, usually Using plate fin radiator, but the radiating efficiency of this passive radiating mode is lower, and heat dissipation effect is limited.

Summary of the invention

Based on this, it is necessary to for the lower problem of radiating efficiency present in current air-conditioning mainboard, provide a kind of energy The air-conditioning system enough to be radiated using air conditioner coolant to mainboard.

Above-mentioned purpose is achieved through the following technical solutions:

A kind of air-conditioning system, including compressor, First Heat Exchanger, orifice union and the second heat exchanger be in turn connected to form it is cold Matchmaker's circulatory system further includes radiating subassembly, and the radiating subassembly is connected with the orifice union, for the air-conditioning system Mainboard heat dissipation.

Refrigerant commutation group is provided between the First Heat Exchanger and second heat exchanger in one of the embodiments, Part, the radiating subassembly and the orifice union are connected to the First Heat Exchanger and described the by the refrigerant component that commutates Between two heat exchangers, the refrigerant commutation component is for making refrigerant followed by radiating subassembly and orifice union.

Refrigerant commutation component includes two-bit triplet reversal valve, the first check valve and the in one of the embodiments, Two check valves, the first working hole of the two-bit triplet reversal valve are connected with second heat exchanger, and the two-bit triplet changes Be connected to the second working hole of valve with the outlet of the orifice union, the First Heat Exchanger by first check valve with The import of the radiating subassembly is connected；The import phase of the third working hole of the two-bit triplet reversal valve and the radiating subassembly Connection, the outlet of the orifice union is connected by second one-way valve with the First Heat Exchanger；

The two-bit triplet reversal valve includes spool, and the spool has the first station and second station, when the spool When positioned at the first station, the first working hole of the two-bit triplet reversal valve is connected with the second working hole；When the spool position When second station, the first working hole of the two-bit triplet reversal valve is connected with third working hole.

The two-bit triplet reversal valve is pressure reversal valve, the pressure of the pressure reversal valve in one of the embodiments, Power control piper is connected with second heat exchanger.

The two-bit triplet reversal valve is solenoid directional control valve in one of the embodiments,.

The refrigerant commutation component includes four-way reversing valve in one of the embodiments, and the four of the four-way reversing valve A working hole is connected with the First Heat Exchanger, the second heat exchanger, the import of radiating subassembly and the outlet of orifice union respectively.

The radiating subassembly includes heat sink and refrigerant liquid pipe in one of the embodiments, the heat sink be used for The mainboard of the air-conditioning system is connected, and the outer tube wall of the refrigerant liquid pipe is connected with the heat sink.

The radiating subassembly further includes radiating module in one of the embodiments, and the radiating module is set to described Between heat sink and the mainboard of the air-conditioning system.

The refrigerant liquid pipe is set to inside the heat sink in one of the embodiments,.

The heat sink includes the upper and lower plate of opposite connection in one of the embodiments, and the upper and lower plate connects Offer tube seat on the face of touching respectively, the refrigerant liquid pipe setting in the tube seat.

The beneficial effects of the present invention are:

The heat dissipation being connected in series with throttling set is arranged in air-conditioning system of the present invention between First Heat Exchanger and the second heat exchanger Component, when refrigerant is in compressor compresses, after First Heat Exchanger or the second heat exchanger heat release, refrigerant is when flowing through radiating subassembly Can absorb heat to the mainboard of air conditioner, cool down to mainboard, avoid because mainboard temperature it is excessively high caused by compressor frequency reducing or Shutdown, it is higher to the radiating efficiency of mainboard due to the active heat removal mode using refrigerant heat absorption, and do not need to increase excessive electricity Device is controlled, cost is relatively low.

Detailed description of the invention

Fig. 1 is schematic diagram of the air-conditioning system of the first embodiment of the invention in refrigeration mode；

Fig. 2 is schematic diagram of the air-conditioning system of the first embodiment of the invention in heating mode；

Fig. 3 is the schematic diagram (the first station) of two-bit triplet reversal valve in the air-conditioning system of the first embodiment of the invention；

Fig. 4 is the schematic diagram (second station) of two-bit triplet reversal valve in the air-conditioning system of the first embodiment of the invention；

Fig. 5 is the schematic diagram of the air-conditioning system of second of embodiment of the invention；

Fig. 6 is the main view of radiating subassembly in air-conditioning system of the present invention；

Fig. 7 is the side view cutaway drawing of radiating subassembly in air-conditioning system of the present invention；

Fig. 8 is the overhead sectional view of radiating subassembly in air-conditioning system of the present invention.

Wherein:

100- compressor；

200- First Heat Exchanger；

300- orifice union；

The second heat exchanger of 400-；

500- radiating subassembly；

510- heat sink；The upper and lower plate of 511-；512- tube seat；

520- refrigerant liquid pipe；

530- radiating module；

600- two-bit triplet reversal valve；

610- spool；620- pressure control conduit；

The first working hole of A-；The second working hole of B-；C- third working hole；

The first check valve of 700-；

800- second one-way valve；

900- four-way reversing valve.

Specific embodiment

In order to make the objectives, technical solutions, and advantages of the present invention clearer, by the following examples, it and combines attached Figure, is further elaborated air-conditioning system of the invention.It should be appreciated that specific embodiment described herein only to It explains the present invention, is not intended to limit the present invention.

It is herein component institute serialization number itself, such as " first ", " second " etc., is only used for distinguishing described object, Without any sequence or art-recognized meanings.And " connection ", " connection " described in the application, unless otherwise instructed, include directly and It is indirectly connected with (connection).In the description of the present invention, it is to be understood that, term " on ", "lower", "front", "rear", " left side ", The orientation of the instructions such as " right side ", "vertical", "horizontal", "top", "bottom", "inner", "outside", " clockwise ", " counterclockwise " or position are closed System is merely for convenience of description of the present invention and simplification of the description to be based on the orientation or positional relationship shown in the drawings, rather than indicates Or imply that signified device or element must have a particular orientation, be constructed and operated in a specific orientation, therefore cannot understand For limitation of the present invention.

In the present invention unless specifically defined or limited otherwise, fisrt feature in the second feature " on " or " down " can be with It is that the first and second features directly contact or the first and second features pass through intermediary mediate contact.Moreover, fisrt feature exists Second feature " on ", " top " and " above " but fisrt feature be directly above or diagonally above the second feature, or be merely representative of First feature horizontal height is higher than second feature.Fisrt feature can be under the second feature " below ", " below " and " below " One feature is directly under or diagonally below the second feature, or is merely representative of first feature horizontal height less than second feature.

The present invention provides a kind of air-conditioning system, including compressor, First Heat Exchanger, orifice union and the second heat exchanger are successively Connection forms coolant circulating system, and the coolant circulating system is similar with existing air-conditioning system, and refrigerant is after compressor compresses High temperature and pressure refrigerant is formed, cryogenic high pressure refrigerant is formed after First Heat Exchanger (condenser) heat release, using orifice union Become gaseous low temperature refrigerant, is then returned in compressor after heat absorption in the second heat exchanger (evaporator).Due to refrigerant into Temperature is lower before and after entering orifice union, therefore can radiate by the refrigerant in this stage, in embodiments of the present invention It further include radiating subassembly, radiating subassembly is connected with orifice union, using the refrigerant before and after entrance orifice union to air-conditioning system Mainboard heat dissipation, avoid because mainboard temperature it is excessively high caused by compressor frequency reducing or shutdown, due to using refrigerant heat absorption active heat removal side Formula, it is higher to the radiating efficiency of mainboard, and do not need to increase excessive automatically controlled device, cost is relatively low.

In the refrigeration and heating operations of air-conditioning system, require to radiate to the mainboard of air-conditioning system, then in sky In the refrigeration and heating operations of adjusting system, the direction of refrigerant flow throttling device is opposite, that is to say, that if radiating subassembly Be mounted on one end of throttling set, when air-conditioning system is in refrigerating state, refrigerant in First Heat Exchanger (condenser) after heat release, It first passes through radiating subassembly and enters back into orifice union, carry out radiating and cooling using mainboard of the low temperature refrigerant to air-conditioning system；Work as air-conditioning When system is changed into heating state, refrigerant after heat release, is introduced into orifice union using scattered in the second heat exchanger (condenser) Hot component, at this point, temperature is too low to will lead to radiating subassembly pair since refrigerant is becoming gaseous state low temperature refrigerant after orifice union Condensation is generated on the mainboard answered, is easy to produce potential faults.Therefore, in order to avoid the potential faults, no matter needing to guarantee is making Under cold state or heating state, refrigerant will be introduced into radiating subassembly in heat exchanger after heat release, enter back into orifice union, be Realization above-mentioned purpose, embodiment of the present invention are provided between First Heat Exchanger and the second heat exchanger refrigerant commutation component, Radiating subassembly and orifice union are connected between First Heat Exchanger and the second heat exchanger by refrigerant commutation component, refrigerant commutation group Part is for making refrigerant followed by radiating subassembly and orifice union.

As depicted in figs. 1 and 2, in the first embodiment of the invention, refrigerant commutation component includes two-bit triplet commutation Valve 600, the first check valve 700 and second one-way valve 800, the first working hole A of two-bit triplet reversal valve 600 and the second heat exchanger 400 are connected, and the second working hole B of two-bit triplet reversal valve 600 is connected with the outlet of orifice union 300, First Heat Exchanger 200 are connected by the first check valve 700 with the import of radiating subassembly 500；The third working hole C of two-bit triplet reversal valve 600 It is connected with the import of radiating subassembly 500, the outlet of orifice union 300 passes through second one-way valve 800 and 200 phase of First Heat Exchanger Connection, First Heat Exchanger 200 and the second heat exchanger 400 are connected with compressor 100 respectively.

In conjunction with as shown in Figure 3 and Figure 4, two-bit triplet reversal valve 600 includes spool 610, spool 610 have the first station and Second station, when spool 610 is located at the first station, the first working hole A and the second working hole B of two-bit triplet reversal valve 600 It is connected；When spool 610 is located at second station, the first working hole A and the third working hole C phase of two-bit triplet reversal valve 600 Connection.

As shown in figures 1 and 3, when air-conditioning system is run in cooling mode, the spool of two-bit triplet reversal valve 600 610 are located at the first station, and refrigerant forms high-temperature high-pressure state after the compression of compressor 100, by 200 heat release of First Heat Exchanger Cryogenic high pressure refrigerant is formed afterwards, radiating subassembly 500 is entered by the first check valve 700, to air-conditioning system in radiating subassembly 500 Mainboard radiate, subsequently into gaseous state low temperature refrigerant is changed into orifice union 300, pass sequentially through two-bit triplet reversal valve 600 the second working hole B and the first working hole A flows into the second heat exchanger 400, and refrigeration is completed in heat absorption in the second heat exchanger 400 Compressor is returned after circulation.

As shown in Figure 2 and Figure 4, when air-conditioning system, which switches, to be run under heating mode, the spool of two-bit triplet reversal valve 600 Positioned at second station, refrigerant forms high-temperature high-pressure state after the compression of compressor 100, after 400 heat release of the second heat exchanger Cryogenic high pressure refrigerant is formed, the first working hole A and third working hole C for passing sequentially through two-bit triplet reversal valve 600 flow into heat dissipation Component 500 radiates to the mainboard of air-conditioning system in radiating subassembly 500, subsequently into being changed into gas in orifice union 300 State low temperature refrigerant, gaseous state low temperature refrigerant enters First Heat Exchanger 200 by second one-way valve 800, in 200 interior suction of First Heat Exchanger Heat returns to compressor after completing heating circulation.It can be seen that from the operational process of refrigerant under above refrigeration and heating mode cold Matchmaker is to first pass through radiating subassembly 500 to enter back into orifice union 300.

As a preferred embodiment, two-bit triplet reversal valve 600 is pressure commutation in conjunction with shown in Fig. 3 and Fig. 4 Valve, the pressure control conduit 620 of pressure reversal valve are connected with the second heat exchanger 400.When air-conditioning system is transported in a heating mode When row, the high pressure and high temperature refrigerant that compressor 100 is discharged is introduced into heat release in the second heat exchanger 400, is discharged from the second heat exchanger 400 Refrigerant remain as high pressure conditions, high pressure refrigerant is delivered to valve body by the pressure control conduit 620 of two-bit triplet reversal valve 600 Interior, high pressure refrigerant pushes spool 610 to be moved to second station, is connected to the first working hole A in valve body with third working hole C. When air-conditioning system is run in cooling mode, the high pressure and high temperature refrigerant that compressor 100 is discharged is introduced into First Heat Exchanger 200 Heat release, and the refrigerant of 400 side of the second heat exchanger is in low-pressure state, the reset spring in two-bit triplet reversal valve 600 pushes Spool 610 overcomes the refrigerant low pressure of 400 side of the second heat exchanger, and spool 610 is made to move to the first station, the first working hole A with Second working hole B is connected in valve body.The use that automatically controlled device can be reduced using pressure reversal valve, is commutated using two-bit triplet The control for spool 610 is realized in the refrigerant pressure variation of 600 two sides of valve.

In other embodiments, two-bit triplet reversal valve 600 can also use solenoid directional control valve, make when air-conditioning system switches When cold heating mode, control electric signal is issued to two-bit triplet reversal valve 600, converts station using electromagnetic drive spool 610.

As shown in figure 5, air-conditioning system of the present invention additionally provides second of embodiment, unlike one embodiment: Refrigerant commutation component includes four-way reversing valve 900, four working holes of four-way reversing valve 900 respectively with First Heat Exchanger 200, the The import of two heat exchangers 400, radiating subassembly 500 is connected with the outlet of orifice union 300.When air-conditioning system is in refrigeration mode When, four-way reversing valve 900 makes the inlet communication of First Heat Exchanger 200 Yu radiating subassembly, while make the outlet of orifice union 300 with The connection of second heat exchanger 400；When air-conditioning system is in heating mode, four-way reversing valve 900 makes the second heat exchanger 400 and heat dissipation The inlet communication of component, while be connected to the outlet of orifice union 300 with First Heat Exchanger 200, whether refrigeration mode or Heating mode, four-way reversing valve 900 are entering orifice union 300 after refrigerant being kept to first pass through radiating subassembly 500 always.

As shown in Figure 6 to 8, in the present embodiment, radiating subassembly 500 includes heat sink 510 and refrigerant liquid pipe 520, is dissipated For being connected with the mainboard of air-conditioning system, the outer tube wall of refrigerant liquid pipe 520 is connected hot plate 510 with heat sink 510.Refrigerant into Enter in radiating subassembly 500 and flowed along refrigerant liquid pipe 520, the heat of mainboard is by heat sink 510 by cold in refrigerant liquid pipe 520 Matchmaker absorbs, and realizes the heat spreading function to mainboard.

Further, radiating subassembly 500 further includes radiating module 530, and radiating module 530 is set to heat sink 510 and sky Between the mainboard of adjusting system, radiating module 530 can be such that mainboard comes into full contact with heat sink 510, and heat is enable uniformly to pass It is directed on heat sink 510, improves radiating subassembly 500 to the radiating efficiency of mainboard.

It further, can be by refrigerant liquid pipe 520 in order to enable refrigerant liquid pipe 520 to come into full contact with heat sink 510 It is set to inside heat sink 510.Specifically, heat sink 510 includes the upper and lower plate 511 of opposite connection, upper and lower plate 511 is connect Tube seat 512 is offered on the face of touching respectively, it will be in the setting of refrigerant liquid pipe 520 and tube seat 512.

The embodiments described above only express several embodiments of the present invention, and the description thereof is more specific and detailed, but simultaneously Limitations on the scope of the patent of the present invention therefore cannot be interpreted as.It should be pointed out that for those of ordinary skill in the art For, without departing from the inventive concept of the premise, various modifications and improvements can be made, these belong to guarantor of the invention Protect range.Therefore, the scope of protection of the patent of the invention shall be subject to the appended claims.

Claims (10)

1. a kind of air-conditioning system, including compressor (100), First Heat Exchanger (200), orifice union (300) and the second heat exchanger (400) it is in turn connected to form coolant circulating system, which is characterized in that further include radiating subassembly (500), the radiating subassembly (500) it connects with the orifice union (300), for the mainboard heat dissipation to the air-conditioning system.

2. air-conditioning system according to claim 1, which is characterized in that the First Heat Exchanger (200) is changed with described second Refrigerant commutation component is provided between hot device (400), the radiating subassembly (500) and the orifice union (300) pass through described Refrigerant commutation component is connected between the First Heat Exchanger (200) and second heat exchanger (400), the refrigerant commutation group Part is for making refrigerant followed by radiating subassembly (500) and orifice union (300).

3. air-conditioning system according to claim 2, which is characterized in that the refrigerant commutation component includes two-bit triplet commutation Valve (600), the first check valve (700) and second one-way valve (800), the first working hole of the two-bit triplet reversal valve (600) (A) it is connected with second heat exchanger (400), the second working hole (B) and the section of the two-bit triplet reversal valve (600) The outlet of stream component (300) is connected, and the First Heat Exchanger (200) passes through first check valve (700) and the heat dissipation The import of component (500) is connected；The third working hole (C) and the radiating subassembly of the two-bit triplet reversal valve (600) (500) import is connected, and the outlet of the orifice union (300) passes through second one-way valve (800) and the First Heat Exchanger (200) it is connected；

The two-bit triplet reversal valve (600) includes spool (610), and the spool (610) has the first station and second station, When the spool (610) is located at the first station, the first working hole (A) and the second work of the two-bit triplet reversal valve (600) Make mouth (B) to be connected；When the spool (610) is located at second station, the first work of the two-bit triplet reversal valve (600) Mouth (A) is connected with third working hole (C).

4. air-conditioning system according to claim 3, which is characterized in that the two-bit triplet reversal valve (600) is changed for pressure To valve, the pressure control conduit (620) of the pressure reversal valve is connected with second heat exchanger (400).

5. air-conditioning system according to claim 3, which is characterized in that the two-bit triplet reversal valve (600) is changed for electromagnetism To valve.

6. air-conditioning system according to claim 2, which is characterized in that the refrigerant commutation component includes four-way reversing valve (900), four working holes of the four-way reversing valve (900) respectively with the First Heat Exchanger (200), the second heat exchanger (400), the import of radiating subassembly (500) is connected with the outlet of orifice union (300).

7. air-conditioning system according to any one of claims 1 to 6, which is characterized in that the radiating subassembly (500) includes dissipating Hot plate (510) and refrigerant liquid pipe (520), the heat sink (510) are described cold for being connected with the mainboard of the air-conditioning system The outer tube wall of matchmaker's liquid pipe (520) is connected with the heat sink (510).

8. air-conditioning system according to claim 7, which is characterized in that the radiating subassembly (500) further includes radiating module (530), the radiating module (530) is set between the heat sink (510) and the mainboard of the air-conditioning system.

9. air-conditioning system according to claim 7, which is characterized in that the refrigerant liquid pipe (520) is set to the heat dissipation Plate (510) is internal.

10. air-conditioning system according to claim 9, which is characterized in that the heat sink (510) includes opposite connection Upper and lower plate (511) offers tube seat (512) on the face of upper and lower plate (511) contact, the refrigerant liquid pipe respectively (520) setting and the tube seat (512) are interior.