DE112018000460T5 - ACCUMULATOR WITH INTERNAL HEAT EXCHANGER AND ACCORDING REFRIGERANT CIRCUIT - Google Patents

Abstract

[Problem] An accumulator having an indoor heat exchanger that makes it easy to find a high-pressure refrigerant outlet with a simple configuration, and a refrigerant circuit equipped with the accumulator [Solution] An accumulator having an indoor heat exchanger on one On the upstream side of a compressor disposed in a circulation passage for circulating a refrigerant in a refrigerant circuit for gas-liquid separation of a gas-liquid two-phase refrigerant, the accumulator comprises: a gas-liquid separation unit 21 connected thereto is formed to have a double-line structure into which the gas-liquid two-phase refrigerant is introduced; and a flat tube 31 adapted to be wound around an outer circumference of the gas-liquid separation unit and through which a high-pressure refrigerant passes, the accumulator having the indoor heat exchanger undergoing an internal heat exchange between the gas-liquid separation unit 21 and the flat tube 31 performs.

Description

Technical area

The present invention relates to an accumulator having an indoor heat exchanger having a heat exchange function and a refrigerant circuit equipped therewith.

State of the art

As an accumulator having an indoor heat exchanger of this type, for example, an accumulator having an indoor heat exchanger for an air conditioning system described in Patent Literature 1 has been proposed. The accumulator described in Patent Literature 1 includes a cylindrical casing and an indoor heat exchanger housed inside the casing. The inner heat exchanger comprises a cylindrical structure having a smaller diameter than the inner diameter of the housing, on the outside of which a high-pressure line is formed and on the inside of which a low-pressure line is formed, and on which, on the inside of the cylindrical structure, a liquid container with another smaller diameter is arranged.

A gas-liquid two-phase refrigerant is supplied to the liquid container via a cylindrical member and separated into a gas-phase refrigerant and a liquid-phase refrigerant, and a separated gas-phase refrigerant flows down through the low-pressure line formed on the cylindrical structure and is discharged. By high-pressure refrigerant flowing through the high-pressure passage of the cylindrical structure from the lower-end side to the upper-end side, the high-pressure refrigerant and the low-pressure refrigerant perform internal heat exchange through the cylindrical structure.

CITATION

patent literature

Patent Literature 1: JP 5350578 B

Summary of the invention

Technical problem

The accumulator described in Patent Literature 1 is designed so that, by arranging the liquid container and the indoor heat exchanger inside the case, a low-pressure refrigerant internally exchanges heat with a high-pressure refrigerant. For this reason, there is a problem that the internal structure of the housing becomes complex and, in connection with this, since the high-pressure pipe is disposed inside the housing, it is difficult to find occurrence of internal leakage of the high-pressure refrigerant and a defect internal leakage at the time of generation can not be found either.
Accordingly, the present invention has been made in view of the problem in the conventional example described in Patent Literature 1 as described above, and an object of the present invention is to provide an accumulator having an indoor heat exchanger that allows leakage of high pressure refrigerant with one Easy to find easy configuration, and to provide an equipped with the accumulator refrigerant circuit.

the solution of the problem

In order to achieve the above object, according to one aspect of the present invention, there is provided an accumulator having an indoor heat exchanger disposed on an upstream side of a compressor provided in a circulation passage for circulating a refrigerant in a refrigerant gas-liquid separation gas-liquid separation circuit 2-phase refrigerant is arranged, the accumulator comprises: a gas-liquid separation unit configured to have a double-line structure into which the gas-liquid two-phase refrigerant is introduced; and a flat tube configured to be wound around an outer circumference of the gas-liquid separation unit and through which a high pressure refrigerant passes, the inner heat exchanger having an internal heat exchange between the gas-liquid separation unit and the flat tube performs.

According to another aspect of the present invention, there is provided a refrigerant cycle comprising: a compressor configured to suck in a refrigerant and to compress; a radiator configured to cool the refrigerant compressed by the compressor; a decompressor configured to decompress the refrigerant cooled by the radiator; an evaporator configured to evaporate the refrigerant decompressed by the decompressor; and the above-described accumulator having the indoor heat exchanger configured to separate a gas-liquid two-phase refrigerant discharged from the evaporator into a gas-phase refrigerant and a liquid-phase refrigerant and supply a separated gas-phase refrigerant to the compressor, the refrigerant circuit This leads to the gas-liquid separation unit of the accumulator with the inner heat exchanger by supplying the gas-liquid two-phase refrigerant Separate gas-phase refrigerant to the compressor, the high-pressure refrigerant flowing from the radiator leads to the flat tube and supplies the high-pressure refrigerant derived from the flat tube to the decompressor.

Advantageous Effects of the Invention

According to the one aspect of the present invention, it is possible to provide an accumulator having an indoor heat exchanger that allows an outlet of a high-pressure refrigerant having a simple configuration to be easily found, and a refrigerant circuit equipped with the accumulator, since a flat tube connected thereto is configured to flow a high-pressure refrigerant, is arranged on the outside of a gas-liquid separation unit.

list of figures

• 1 FIG. 10 is an overall configuration diagram illustrating one embodiment of a refrigerant cycle according to the present invention; FIG.
• 2 Fig. 15 is a perspective view illustrating a first embodiment of a secondary battery with an internal heat exchanger according to the present invention;
• 3 Fig. 10 is a plan view of the accumulator having the indoor heat exchanger according to the present invention;
• 4 is a cross-sectional view along the line IV - IV of the 3 ;
• 5 Fig. 10 is a front view of the accumulator having the indoor heat exchanger according to the present invention;
• 6 is a cross-sectional view along the line VI - VI of the 5 ;
• 7 is a perspective view illustrating a double line;
• 8th is a plan view of the double line;
• 9 Fig. 15 is a perspective view illustrating a second embodiment of the accumulator having the indoor heat exchanger according to the present invention;
• 10 is a plan view of the second embodiment;
• 11 is a cross-sectional view along the line XI - XI of the 10 ;
• 12 is a cross-sectional view along the line XII - XII of the 10 ;
• 13 is a front view of the second embodiment; and
• 14 is a cross-sectional view along the line XIV - XIV of the 13 ,

Description of the embodiments

Next, an embodiment of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar reference numerals will be assigned to the same or similar parts. It should be noted, however, that the drawings are schematic, with a relationship between thickness and planar dimensions, thickness ratios between respective layers and the like being different from the actual ones. Therefore, specific thicknesses and dimensions should be determined in consideration of the following description. It should also be noted that the drawings contain sections with different proportions and proportions to each other.

The following embodiment shows apparatus and methods for exemplifying the technical idea of the present invention, and the technical idea of the present invention does not limit the materials, shapes, structures, arrangements and the like of the components to those described below. The technical idea of the present invention can be subjected to a variety of changes within the technical scope given by the claims described in the claims.

First Embodiment

First, a refrigeration cycle representing one aspect of the present invention will be described with reference to FIG 1 described.
The refrigerant cycle according to the present invention constitutes, for example, an air conditioner of a vehicle as in FIG 1 illustrated. A refrigerant circuit 1 circulates a CO ₂ refrigerant (hereinafter simply referred to as refrigerant), which is a natural refrigerant, and thereby performs an air conditioning of the vehicle interior. The refrigerant circuit 1 is about an area of an engine room 3 who has a motor 2 includes, up to a vehicle interior 4 arranged.

In particular, the refrigerant circuit comprises 1 one by the engine 2 driven compressor 11 , a radiator 12 , an accumulator 13 with an indoor heat exchanger, an expansion valve 14 and an evaporator 15 ,
The compressor 11 is a device for aspirating and compressing a gas phase Refrigerant and thus increasing the temperature and increasing the pressure and can be selected from compressors such as a reciprocating compressor, a rotary compressor and a scroll compressor. That from the compressor 11 compressed refrigerant passes through the refrigerant line RP1 and becomes the radiator 12 fed.

The radiator 12 that cools through the compressor 11 compressed refrigerant by means of heat exchange with the outside air. That through the radiator 12 cooled high pressure refrigerant becomes a flat tube 31 which will be described later in the accumulator 13 is included with the indoor heat exchanger, via the refrigerant line RP2 fed. The accumulator 13 high-pressure refrigerant discharged with the indoor heat exchanger is passed through the expansion valve 14 that in the refrigerant line RP3 is arranged and serves as a decompressor, decompresses and is the evaporator 15 supplied as a low-pressure refrigerant.

The evaporator 15 Cools air in the vehicle interior by heat exchange of the through the expansion valve 14 decompressed refrigerant with the air in the vehicle interior. A from the evaporator 15 flowing gas-liquid two-phase refrigerant is the accumulator 13 with the indoor heat exchanger via the coolant line RP4 and separated into a liquid-phase refrigerant and a gas-phase refrigerant, and the gas-phase refrigerant becomes the compressor 11 over the coolant line FP5 fed.
The accumulator 13 with the indoor heat exchanger sees an internal heat exchange of the gas-phase refrigerant, which was generated by the gas-liquid separation and has a low temperature and a low pressure, with that of the radiator 12 supplied high-pressure refrigerant and then leads the gas-phase refrigerant to the compressor 11 to.

A specific configuration of the accumulator 13 with the indoor heat exchanger includes a gas-liquid separation unit 21 and the flat tube 31 that is, around an outer periphery of the gas-liquid separation unit 21 wrapped, the indoor heat exchanger forms, as in the 2 . 3 and 4 illustrated.
As in 4 illustrated comprises the gas-liquid separation unit 21 a double line 22 whose two ends are opened, and which, for example, a cylindrical shape, one at an upper end portion of the double line 22 attached first lid 23 and a second lid attached to a lower end portion of the double lead 24 having.

As in the 4 . 6 . 7 and 8th shown, is the double line 22 formed, for example, by an extruded article formed by extruding a metallic material having a high thermal conductivity, such as aluminum and an aluminum alloy, and comprising an outer cylinder 2 a with a thick thickness and an inner cylinder 22b with a smaller diameter than that of the outer cylinder 22a and a thin thickness.
As in 4 Illustrated are the upper ends of the outer cylinder 22a and the inner cylinder 22b flush with each other and the lower end of the inner cylinder 22b is designed longer than that of the outer cylinder 22a , so that the inner cylinder 22b further down than the inner cylinder 22a , As in the 4 . 7 and 8th shown are the outer cylinder 22a and the inner cylinder 22b through partitions 22c which are formed at a predetermined distance in a circumferential direction and extend in the axial direction, connected to each other. Spaces, each from the inner peripheral surface of the outer cylinder 22a , the outer peripheral surface of the inner cylinder 22b and two adjacent partitions 22c are enclosed to gas-phase refrigerant channels 22d configured to be passed through a gas-phase refrigerant. Therefore, a plurality (for example 18 ) Gas-phase refrigerant channels 22d in the circumferential direction between the outer cylinder 22a and the inner cylinder 22b educated.

To the upper end of the inner cylinder 22b are connecting grooves 22e formed, which are adapted to the inner surface of the inner cylinder 22b with the respective gas phase refrigerant channels 22d connect to.
The first lid 23 is for example made of the same metallic material as the double line 22 formed and includes, as in the 2 to 4 illustrates a round plate section 23a Designed to be the top of the double line 22 to close, and an annular flange portion 23b that's about it is formed, from the outer peripheral surface of the round plate portion 23a extend down and onto the outer peripheral surface of the outer cylinder 22a the double line 22 to fit. An inflow line 23c that is designed to be one of the evaporator 15 supplied gas-liquid two-phase refrigerant in the interior of the inner cylinder 22b the double line 22 to flow is in a penetrating manner at a central portion of the round plate portion 23a educated.

The second lid 24 is for example made of the same metallic material as the double line 22 formed and includes, as in the 2 and 4 shown a round plate section 24a , which is adapted to the lower end of the inner cylinder 22b the double line 22 to close, and an annular flange portion 24b which is adapted to project from the outer peripheral surface of the round plate portion 24a to extend upward and on the outer peripheral surface of the outer cylinder 22a the double line 22 to fit.
The second lid 24 forms through the round plate section 24a , which is the lower end of the inner cylinder 22b the double line 22 closes, a liquid storage section 26 which is adapted to a separate liquid-phase refrigerant and lubricating oil on the side of the lower end of the inner cylinder 26b store and forms with the outer peripheral surface of the inner cylinder 22b , the round plate section 24a and the flange portion 24b a gas-phase refrigerant storage portion 24c which is adapted to one of the gas-phase refrigerant channels 22d temporarily store flowing gas-phase refrigerant.

In the round plate section 24a and between the outer peripheral surface of the inner cylinder 22b the double line 22 and the flange portion 24b is a drain line in a pervasive way 24d adapted to be temporarily in the gas-phase refrigerant storage portion 24c stored gas phase refrigerant the compressor 11 to be fed. In the above configuration, the protruding height of the drain pipe becomes 24d to the gas phase refrigerant storage section 24c set so that the opening area of the drain line 24d to the gas phase refrigerant storage section 24c opens at a position having a height which is approximately half the height of the gas-phase refrigerant storage portion 24c is.

At a position on the opposite side to the side of the drain pipe 24d on the lower end surface of the inner cylinder 22b the double line 22 is an oil return groove 27 formed to be formed in the liquid storage portion 26 stored oil to the adjacent gas-phase refrigerant storage portion 24c due.
The double line 22 , the first lid 23 and the second lid 24 can be connected by welding or soldering while the first lid 23 and the second lid 24 on the double line 22 put on or by screwing in the first lid 23 and the second lid 24 formed female threaded portions with respective at both ends of the outer cylinder 22a formed externally threaded portions are connected.

As in the 2-6 shown, the flat tube 31 so to the double line 22 wrapped that it is part of the outer peripheral surface of the double line 22 that from the first lid 23 and the second lid 24 is exposed, covers. The flat tube 31 will, like the double line 22 is formed by an extruded article formed by extruding a metallic material having a high thermal conductivity such as aluminum and an aluminum alloy. In addition, inside the flat tube 31 , as in 4 illustrates a plurality of high-pressure refrigerant channels 31a configured to pass a high-pressure refrigerant at a predetermined interval in the axial direction of the double pipe 22 educated. Further, the inner peripheral length of the flat tube becomes 31 set shorter than the outer peripheral length of the outer cylinder 22a , and both circumferential end portions of the flat tube 31 are like in the 2 and 3 shown with a first connection line 32 and a second connection line 33 along the axial direction on the outer peripheral surface of the outer cylinder 22a are arranged, connected.

The first connection line 32 will, as in 6 shown formed by a cylindrical body whose two upper and lower ends are closed, and on the side of the lower end thereof as shown in FIG 5 illustrates is an inlet opening 32a formed to allow a high pressure refrigerant to flow in, and on the left side surface thereof, as in FIG 6 Seen, is a connection opening 32b into which one end of the flat ear 31 is fitted, formed, which extends in the axial direction. In the connection opening 32b the first connection line 32 becomes one end of the flat tube 31 fitted and connected, and the interior of the first connection line 32 and the respective high-pressure refrigerant channels 31a of the flat tube 31 become connected with each other.

The second connection line 33 will, as in 6 represented by a cylindrical body whose two upper and lower ends are closed, as in the first connection line 32 , formed, and at the upper end of it, as in 5 Illustrated is a drain opening 33a formed to discharge a high-pressure refrigerant, and on the right side surface thereof, as in 6 Seen, is a connection opening 33b into the other end of the flat tube 31 is fitted, formed, which extends in the axial direction. In the connection opening 33b the second connection line 33 becomes the other end of the flat tube 31 fitted and connected, and the interior of the second connection line 33 and the respective high-pressure refrigerant channels 31a of the flat tube 31 become connected with each other.

The inflow opening 32a the first connection line 32 of the accumulator 13 with the indoor heat exchanger is connected to the refrigerant line RP2 connected, and the drain opening 33a the second connection line 33 it will be with the expansion valve 14 via the refrigerant line RP3 connected. Furthermore, the inflow line 23c of the first lid 23 of the accumulator 13 with the indoor heat exchanger with a refrigerant outlet of the evaporator 15 via the refrigerant line RP4 connected, and the drain line 24d the second lid 24 this is done with the compressor 11 via the refrigerant line FP5 connected.

Next, the operation of the first embodiment described above will be described
in the refrigerant circuit 1 is a gas-phase refrigerant through the compressor 11 Compresses and becomes the radiator 12 supplied as a high-pressure refrigerant. The high pressure refrigerant is made by heat exchange with the outside air through the radiator 12 cooled. In the cooling step, the temperature of the high pressure refrigerant is substantially isobaric.
The cooled high pressure refrigerant becomes the inflow port 32a the first connection line 32 the accumulator 13 supplied with the indoor heat exchanger, and is in the first connection line 32 to the respective high-pressure refrigerant channels 31a of the flat tube 31 distributed and flows into this, and that of the other end side of the high-pressure refrigerant channels 31a discharged high-pressure refrigerant is in the second connecting line 33 brought together and the expansion valve 14 from the drainage hole 33a fed.

That through the expansion valve 14 the compressed and expanded refrigerant is the evaporator 15 fed, heat exchanged with the air in the passenger compartment and the supply line 23c of the first lid 23 the accumulator 13 supplied with the indoor heat exchanger as a gas-liquid two-phase refrigerant.
In the accumulator 13 with the indoor heat exchanger that is from the inflow line 23c of the first lid 23 infused gas-liquid two-phase refrigerant into the inner cylinder 22b the double line 22 flows in and becomes gas-liquid separated, and oil having the largest specific gravity becomes in the bottom layer within the liquid storage portion 26 located on the lower end side of the inner cylinder 22b is formed, stored, and a separate liquid-phase refrigerant having a lower specific gravity than the oil is stored on the oil.

A separated gas-phase refrigerant moves to the side of the second lid 24 Side through at the top of the inner cylinder 22b trained connecting grooves 22e and continue through between the outer cylinder 22a and the inner cylinder 22b formed gas phase refrigerant channels 22d , Because the flat tube 31 around the outside of the gas phase refrigerant channels 22d is wound and a high-pressure refrigerant with a high temperature from the radiator 12 through the high-pressure refrigerant channels 31a in the flat tube 31 the high-pressure refrigerant having a high temperature and the low-pressure gas-phase refrigerant having a low temperature are internally heat-exchanged with each other. For this reason, the high-pressure refrigerant is cooled at a high temperature, and the low-temperature gas-phase refrigerant is heated to raise the temperature. The gas-phase refrigerant whose temperature has been raised by the internal heat exchange that maintains a gas-phase state returns from the gas-phase refrigerant storage section 24c the second lid 24c through the drainage line 24d to the compressor 11 back.

The in the liquid storage section 26 of the accumulator 13 Oil stored with the indoor heat exchanger is replaced by that at the bottom of the inner cylinder 22b formed oil return groove 27c in the gas-phase refrigerant storage section 24c returned and, if the upper surface of the oil is the upper surface of the drain pipe 24d has exceeded, along with the gas-phase refrigerant to the compressor 11 recycled.
Since the inner heat exchanger according to the first embodiment described above with the flat tube 31 is configured as described above, through which a high-pressure refrigerant is flowed, which is around the outer peripheral side of the gas-liquid separation unit 21 that the accumulator 13 is formed with the indoor heat exchanger, is wound to ensure a sufficient liquid storage capacity, it is only necessary the outer shape of the double pipe 22 containing the gas-liquid separation unit 21 forms, and thereby enlarge the inner diameter of the outer cylinder 22a and the inner cylinder 22b to enlarge.

Because the flat tube 31 through which a high-pressure refrigerant is flowed to the outer peripheral surface of the gas-liquid separation unit 21 is wound when the high-pressure refrigerant from the flat tube 31 leak, the leakage can also be easily detected by means of a CO ₂ sensor. Further, if it is not possible to use a CO ₂ sensor, it is possible to submerge the accumulator 13 With the indoor heat exchanger in a liquid and visual confirmation of the existence of bubbles to easily find the outlet of the high-pressure refrigerant. It is also possible to discharge a high pressure refrigerant at the time of the production end of an accumulator 13 with the indoor heat exchanger in a similar manner.

In the first embodiment described above, it is possible to use the gas-liquid separation unit 21 of the accumulator 13 with the Indoor heat exchanger with a simple configuration, in which only the double line 22 and the first lid 23 and the second lid 24 that close each of both ends of the double line, are arranged to design, and thereby the gas-liquid separation unit 21 be easily configured with a small number of components. Because the double line 22 By an extruded article formed by extruding a metallic material having a high heat conductivity, it is possible to form the double line 22 easy to make.

Because the opening position of the drain pipe 24d that in the second lid 24 is formed to a higher position than the bottom surface of the gas-phase refrigerant storage portion 24c is set, it is further possible, when a liquid-phase refrigerant to the gas-phase refrigerant storage section 24c through the oil return groove 27 at the bottom of the inner cylinder 22b is formed, exit, the leaked liquid-phase refrigerant to store until the liquid-phase refrigerant, the opening position of the drain line 24d achieved, and thereby possible to prevent the liquid-phase refrigerant from the drain line 24d to the compressor 11 is derived.

Because the flat tube 31 on its inside a plurality of high-pressure refrigerant channels 31a , which are formed with a spacing therebetween in the axial direction, comprises, a high-pressure refrigerant from the first connection line 32 to the respective high-pressure refrigerant channels 31a distributes and supplies and high-pressure refrigerant into the respective high-pressure refrigerant channels 31a with the second connection line 33 It is possible to uniformly flow a high-pressure refrigerant, thereby efficiently performing an internal heat exchange. Although in the above-described first embodiment, a case has been described in which the flat tube 31 is formed into a wide shape, which has an exposed portion of the double tube 22 covered, the present invention is not limited to the case, and it can be configured so that the flat tube 31 is divided into a plurality of flat tubes in the axial direction and the respective split flat tubes in parallel with the first connecting line 32 and the second connection line 33 are connected.

Next, a second embodiment of the present invention will be described with reference to FIGS 9 to 14 described.
In the second embodiment, a plurality of rows of flat tubes are wound around the outer periphery of a double line, and the flow direction of a high-pressure refrigerant is set to alternately change in the opposite direction for each row of the flat tube.
That is, in the second embodiment, an accumulator 13 with an inner heat exchanger having a plurality of, for example, four rows of flat tubes 41A . 41B . 41C and 41D configured with a predetermined intermediate in the axial direction of a double line 22 arranged distance around the outer peripheral surface of the double line 22 coming from a first lid 23 and a second lid 24 is free, wound, as in the 9 and 13 shown.
Inside the flat tubes 41A to 41D as in the 11 and 12 Illustrated are groups of high pressure refrigerant channels 41a to 41d each comprising a plurality of, for example, seven high pressure refrigerant passages, each parallel to each other in the width direction, which is the axial direction of the double passage 22 is, trained.

the one ends and the other ends of the respective flat tubes 41A to 41D are with a first connection line 42 or a second connection line 43 connected.
As in 11 shown, becomes the first connection line 42 from a cylindrical body, whose both ends are closed, formed and in the interior thereof are a partition plate 44a and a partition plate 44b arranged at a position that is the midpoint between the flat tubes 41A and 41B corresponds or a position to the center between the flat tubes 41C and 41D corresponds, and thereby become three connection spaces 45a . 45b and 45c educated. On the side of the lower end of the connection room 45a is an inflow opening 46a for a high-pressure refrigerant having a high temperature and formed on the side of the upper end of the connection space 45c a drain opening 46b designed for a high-pressure refrigerant.

As in 12 illustrates, the second connection line 43 like the first connection line 42 , formed of a cylindrical body whose both ends are closed, and in the interior thereof is a partition plate 44c at a position corresponding to the midpoint between the flat tubes 41B and 41C arranged and thereby become two connection spaces 47a and 47b educated.

Because of this, a high pressure refrigerant is used at a high temperature by a radiator 12 the inflow opening 46a is supplied evenly to the respective high-pressure refrigerant channels 41a of the flat tube 41A in the connection room 45a the first connection line 42 distributed and flows within the respective high-pressure refrigerant channels 41a to the connection room 47a of the second connection line 43 , as in 13 represented by solid arrows.

The high-pressure refrigerant, which is the respective high-pressure refrigerant channels 41a of the flat tube 41A has passed through, connects to the lower side of the connection space 47a the second connection line 43 , is applied evenly to the respective high-pressure refrigerant channels 41b of the flat tube 41B from the upper side of the connection room 47a distributed, flows within the respective high-pressure refrigerant channels 41a in the opposite direction to the direction in the flat tube 41A , as in 13 represented by solid arrows, and continues in the direction of the connection space 45b the first connection line 42 ,

The high-pressure refrigerant, which is the respective high-pressure refrigerant channels 41b of the flat tube 41B has passed through, connects to the lower side of the connection space 45b the first connection line 42 , is applied evenly to the respective high-pressure refrigerant channels 41c of the flat tube 41C from the upper side of the connection room 45b distributed, flows through the respective high-pressure refrigerant channels 41a in the opposite direction to the direction in the flat tube 41B , as in 13 represented by solid arrows, and continues in the direction of the connection space 47b the second connection line 43 ,

The high pressure refrigerant passing through the respective high pressure refrigerant channels 31c of the flat tube 31C passed, connects to the bottom of the connection space 47b the second connection line 43 , is applied evenly to the respective high-pressure refrigerant channels 41d of the flat tube 31D from the upper side of the connection room 47b distributed, flows through the respective high-pressure refrigerant channels 41d in the opposite direction to the direction in the flat tube 41C , as in 13 represented by solid arrows, and continues in the direction of the connection space 45c the first connection line 32 ,
The high pressure refrigerant passing through the high pressure refrigerant channels 41a of the flat tube 41D was conducted, connects in the connection room 45c the first connection line 42 one and is from drain opening 46b on the upper side to an expansion valve 14 directed.

The other components have a configuration similar to the configuration in the first embodiment, and the components corresponding to those in the first embodiment are assigned the same characters as those in the first embodiment, and detailed descriptions thereof are omitted.
Next, the operation of the second embodiment described above will be described.

As a gas-liquid separation unit 21 has a similar configuration as in the first embodiment described above, one from an inflow line 23c of the first lid 23 low-pressure gas-liquid two-phase refrigerant flowed into an inner cylinder 22b the double line 22 are introduced, and due to a specific weight difference are in a liquid storage section 26 an oil layer and a liquid-phase refrigerant layer are formed in a lower layer and an upper layer, respectively. A separated gas-phase refrigerant flows through gas-phase refrigerant channels 22d between an outer cylinder 22a and the inner cylinder 22b down and is from a drain pipe 24d the second lid 24 to a compressor 11 derived. Oil in the oil layer, in the lower layer in the liquid storage section 26 is stored, via an oil return groove 27 connected to the gas phase refrigerant and to the compressor 11 recycled.

Thereby, the low-pressure gas-phase refrigerant having a low temperature passing through the gas-phase refrigerant passages 22d between the outer cylinder 22a and the inner cylinder 22b flows down, internally with a high-pressure refrigerant at a high temperature, passing through the flat tubes 41A to 41D flows around the outer circumference of the double pipe 22 are wound, heat exchanged and thereby its temperature is increased.
In the flat tubes 41A to 41D a high-pressure refrigerant flows into the high-pressure refrigerant channels 41a of the flat tube 41A in the lower row of the inlet opening 46a the first connection line 32 has flowed to the second connection line 43 , And the high-pressure refrigerant connects on the opposite side through the connection space 47a the second connection line 43 , is then applied evenly to the high-pressure refrigerant channels 41b of the flat tube 41B distributed and flows in the opposite direction to the flow direction in the flat tube 41A ,

Subsequently, the high pressure refrigerant sequentially flows through the communication space 45b the first connection line 42 , the high-pressure refrigerant channels 41c of the flat tube 41C , the connection room 47b the second connection line 43 and the high pressure channels 41d of the flat tube 41D and reaches the connection room 45c the first connection line 42 and is from the drainage hole 46b of the connection room 45c to the expansion valve 14 derived. As described above, there according to the second embodiment, the second embodiment with respect to the gas-liquid separation unit 21 Having a similar configuration to the first embodiment described above, it is possible to have similar ones to achieve functional effects as in the first embodiment.

In terms of internal heat exchange function is due to the majority of flat tubes 41A to 41D , the first connection line 42 and the second connection line 43 formed a continuous high-pressure refrigerant passage through which a high-pressure refrigerant from the flat tube 41A in the lower row to the flat tube 41D in the upper row flows. The use of the circumferential direction length of the respective flat tubes 41A to 41D therefore allows the overall length of the high-pressure refrigerant flow path to be much longer than in the first embodiment, and thus it is possible to perform efficient internal heat exchange.

That of the flat tube 41A reached in the lower row high-pressure refrigerant, achieved in repeating the distribution and connection in the first connecting line 42 and the second connection line 43 , the flat tube 41D in the upper row. For this reason, temperature unevenness of a high-pressure refrigerant can be suppressed, and it becomes possible to perform a uniform heat exchange that makes it possible to perform a more efficient internal heat exchange. Furthermore, a high pressure refrigerant increased by the plurality of high pressure refrigerant passages 41a to 41d in the flat tubes 41A to 41D flows, the flow rate, thereby promoting the stirring of the high-pressure refrigerant in the first connection line 42 and the second connection line 43 ,

As a continuous high-pressure refrigerant passage only by parallel enveloping the plurality of flat tubes 41A to 41D and individually connecting both end portions thereof to the first connection line 42 and the second connection line 43 can be formed, is also the application of an elaborate processing of the flat tubes 41A to 41D not necessary and in conjunction with this can the flat tubes 41A to 41D , the first connection line 42 and the second connection line 43 simply on the outer peripheral surface of the gas-liquid separation unit 21 be used.

In addition, the high-pressure refrigerant sequentially flows from the lower side to the upper side on the outside of the gas-liquid separation unit 21 through the flat tubes 41A to 41D and on the other hand, this flows through the gas-liquid separation unit 21 separate gas phase refrigerant from the upper end of the inner cylinder 22b through the connecting grooves 22e down and on through the between the outer cylinder 22a and the inner cylinder 22b formed gas phase refrigerant channels 22d to the side of the second lid 24 , For this reason, the gas-phase refrigerant and the high-pressure refrigerant become countercurrents, thereby enabling the heat exchange efficiency to be further improved.

Although in the above-described second embodiment, a case has been described in which the inflow port 46a at the first connection line 42 is formed, the present invention is not limited to the case, and the first connection line 42 and the second connection line 43 can be exchanged laterally with each other.
Although in the second embodiment described above, a case has been described in which four flat tubes 41A to 41D can be used, the present invention is not limited to the case, and two or three or, further, five or more flat tubes may be formed to be wrapped. In this case, if an odd number of flat tubes are arranged, the first connecting line 42 and the second connection line 43 can be made in a common component and the manufacturing costs thereof compared to a case where the first connection line 42 and the second connection line 43 be prepared separately, be reduced
since it is only necessary, the inflow opening 46a (or the drain hole 46b) at the first connection line 42 and the drainage hole 46b (or the inlet opening 46a) on the second connection line 43 to form and the separating plates in the first connecting line 42 and in the second connection line 43 to arrange at positions inversely to each other.

Furthermore, it is also possible, the first connection line 42 and the second connection line 43 by separating a cylindrical body in the axial direction instead of a configuration of the first connection line 42 and the second connection line 43 to form as a separate body. In this case, the first connection line 42 and the second connection line 43 can be made of one component, and it is thereby possible to reduce the number of components and thereby lower the production cost.
Although in the above-described second embodiment, a case has been described in which the connection spaces in the first connection line 42 and in the second connection line 43 through the separator plates 44a to 44c Moreover, the present invention is not limited to the case, and the first connection line 42 can by connecting three cylindrical bodies with the connecting spaces 45a to 45c be configured and the second connection line 43 can by connecting two cylindrical bodies with the connecting rooms 47a and 47b be configured.

Although in the above-described first and second embodiments, a case has been described in which by closing the bottom surface of the inner cylinder 22b of the double pipe 22b with the second lid 24 the liquid storage section 26 is formed, the present invention is not limited to the case, and the bottom surface of the inner cylinder 22b can be closed by a bottom plate, the one from the second lid 24 is different element. In this case, it is not necessary to use the inner cylinder 22b further than the outer cylinder 22a to protrude, and the bottom surface of the inner cylinder 22b Can be configured to fit with the bottom surface of the outer cylinder 22a is flush.

Although in the above-described first and second embodiments, a case has been described in which a plurality of gas-phase refrigerant passages between the outer cylinder 22a and the inner cylinder 22b In addition, the number of the gas-phase refrigerant channels may be set to any number that is 1 or more. Although in this case on the partitions 22c can be waived, it is necessary to have one or more partitions 22c to form the double line 22 to produce as an extruded object. Furthermore, the outer cylinder 22a and the inner cylinder 22b manufactured as a separate body and connected by a connecting means, such as welding and soldering, to the double lead 22 to build.

Although in the above-described first and second embodiments, a case has been described in which the accumulator 13 is independently configured with the indoor heat exchanger, the present invention is not limited to the case, and the accumulator 13 with the indoor heat exchanger can also be integral with each of the compressor 11 , the radiator 12 and the evaporator 15 be configured. The key thing is that a gas phase medium from the accumulator 13 with the indoor heat exchanger, a gas phase medium suction section of the compressor 11 can be supplied.
Although in the first and second embodiments described above, the refrigerant cycle 1 As applied to an air conditioner for a vehicle, the present invention is not limited to the case, and the present invention can be applied to a refrigeration cycle used for a showcase, a vending machine, and the like.

LIST OF REFERENCE NUMBERS

11

compressor

12

radiator

13

Accumulator with an indoor heat exchanger

14

expansion valve

15

Evaporator

21

Gas-liquid separation unit

22

double line

22a

outer cylinder

22b

inner cylinder

22c

partition wall

22d

Gas-phase refrigerant passage

22e

communicating

23

first lid

23c

inflow line

24

second lid

24c

Gas phase refrigerant storage section

24d

drain line

26

Liquid storage portion

27

Ölrücklaufnut

31

flat tube

31a

High-pressure refrigerant passage

32

first connection line

32a

inflow

33

second connection line

33a

drain opening

41A to 41D

flat tube

41a to 41d

High-pressure refrigerant passage

42

first connection line

43

second connection line

44a to 44c

separating plate

45a to 45c

communication space

46a

inflow

46b

drain opening

47a, 47b

communication space

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 5350578 B [0004]

Claims (7)

An accumulator having an indoor heat exchanger disposed on an upstream side of a compressor disposed in a circulation passage for circulating a refrigerant in a refrigerant circuit for gas-liquid separation of a gas-liquid two-phase refrigerant, the accumulator comprises: a gas-liquid separation unit configured to have a double-piping structure into which the gas-liquid two-phase refrigerant is introduced; and a flat tube adapted to be wound around an outer circumference of the gas-liquid separation unit and through which a high pressure refrigerant passes, wherein the accumulator with the indoor heat exchanger performs an internal heat exchange between the gas-liquid separation unit and the flat tube. The accumulator with the indoor heat exchanger after Claim 1 wherein the gas-liquid separation unit is a double pipe comprising an inner cylinder adapted for gas-liquid separation of the gas-liquid two-phase refrigerant and an outer cylinder capable of forming a gas-phase refrigerant passage which separates it into a gas phase -Coolant allows to pass, comprises a first lid, which is attached to one end of the double line and adapted to direct a gas-liquid two-phase refrigerant in the inner cylinder, and a second lid, which on the other side of the A double line is provided and adapted to discharge the gas-phase refrigerant in the gas-phase refrigerant passage to the outside, and in the double line, a plurality of gas-phase refrigerant passages through a plurality of partition walls spaced at a distance in a circumferential direction between the outer cylinder and the inner cylinder are formed, are formed and connecting openings, the ausgebil to det are to connect an inner surface of the inner cylinder with the gas-phase refrigerant channels are formed between the inner cylinder and the first lid. The accumulator with the indoor heat exchanger after Claim 2 wherein the flat tube opens to both ends in a winding direction, a plurality of high pressure refrigerant passages are formed in parallel at a distance in an axial direction of the double line within the flat tube, a first connection line formed to communicate with the plurality of High pressure refrigerant passage, and thereby to form a high-pressure refrigerant flow path is connected to one end in the winding direction of the flat tube and a second connecting line, which is adapted to be in communication with the plurality of high-pressure refrigerant channels, and thereby a high pressure Refrigerant flow path is connected to the other end in the winding direction of the flat tube. The accumulator with the indoor heat exchanger after Claim 3 wherein a plurality of flat tubes each being a flat tube wound around the double line in a plurality of rows and the plurality of flat tubes constitute a continuous refrigerant passage in which the high pressure refrigerant alternately changes the flow direction in an opposite direction for each Row via the first connecting line and the second connecting line flows. The accumulator with the indoor heat exchanger after Claim 3 or 4 wherein the first connection line and the second connection line are connected such that the refrigerant supplied from the side of the second lid is discharged from the side of the first lid via the flat tube. The accumulator with the indoor heat exchanger after one of Claims 2 to 5 wherein the first lid includes an inflow pipe configured to feed a low-pressure refrigerant into the inner cylinder of the double pipe, and the second lid includes a drain pipe configured to trap the gas-phase refrigerant passing through the double-pipe gas-phase refrigerant passage dissipate to the outside. A refrigerant cycle comprising: a compressor configured to suck and compress a refrigerant; a radiator configured to cool the refrigerant compressed by the compressor; a decompressor configured to decompress the refrigerant cooled by the radiator; an evaporator configured to evaporate the refrigerant decompressed by the decompressor; and the accumulator with the indoor heat exchanger according to one of Claims 1 to 6 that is configured to separate a gas-liquid two-phase refrigerant discharged from the evaporator into a gas-phase refrigerant and a liquid-phase refrigerant and supply a separated gas-phase refrigerant to the compressor, the refrigerant circuit performs by supplying the gas-liquid Two-phase refrigerant to the gas-liquid separation unit of the accumulator with the indoor heat exchanger separate gas-phase refrigerant to the compressor, this leads from the Radiator flowing high pressure refrigerant to the flat tube and leads the derived from the flat tube high-pressure refrigerant to the decompressor.

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