DE102007021605A1 - Component assembly for a refrigeration cycle and cooling circuit equipped therewith - Google Patents

Abstract

At least two components for a refrigeration cycle are integrated into a component assembly prior to attachment to an article. For example, a decompression device (300) and a gas-liquid separator (500) are integrated into a component assembly (A1), and then the component assembly (A1) is attached to an object. Alternatively, the decompression device (300) and an internal heat exchanger (200) are integrated into a component assembly (A2) and then the component assembly is attached or fixed to an article. As another example, the decompression device (300), the gas-liquid separator (500), the internal heat exchanger (200) are integrated into a component assembly (A3) and then attached to an article.

Description

The The present invention relates to an assembly of components for a Cooling circuit and is aimed at a cooling circuit equipped with the arrangement.

A refrigeration cycle for a vehicle air conditioning system generally includes a compressor 10 , a radiator (eg condenser, gas cooler) 100 , a decompression device 300 , an evaporator 400 , a gas-liquid separator 500 and an internal heat exchanger 200 , as in 8th shown. The aforementioned components are, for example, via cooling pipes P1 to P6 and cooling hoses H1, H2, as in 9 shown connected.

The compressor 10 is arranged to receive a driving force from a vehicle engine. The radiator 100 is in front of a radiator 600 arranged, which is mounted on the front part of an engine compartment EC of the vehicle and receives air while the vehicle is driving. The evaporator 400 is disposed in an air conditioning unit (not shown) mounted in a passenger compartment PC of the vehicle. Also the decompression device 300 , the gas-liquid separator 500 and the inner heat exchanger 200 are arranged at predetermined locations in the engine compartment EC.

The inner heat exchanger 200 has a channel or passage for a high pressure coolant and a passage or passage for a low pressure coolant for effecting heat exchange between a high pressure coolant and a low pressure coolant flowing therethrough. The plurality of coolant tubes are connected to the inner heat exchanger 200 coupled to make the connection with the high pressure passage and the low pressure passage. Also has the decompression device 300 two coolant passages herein to control the pressure of the high pressure coolant based on the temperature of the coolant behind the radiator. This is the multiple coolant tube or the plurality of coolant tubes with the decompression device 300 coupled to make the connection with the two coolant channels. Thus, the arrangement of the coolant tubes is complicated, the coupling work of the coolant tubes increases.

in the In view of the above, the invention was made, and it is an object of the present invention to provide a component assembly for one Cooling circuit to disposal to be able to make the connection or the connection to simplify pipes. Another object of the present invention exists in a cooling circuit with the component arrangement.

According to one Aspect of the present invention has a component arrangement for a cooling circuit a decompression device for decompressing a high-pressure coolant and a gas-liquid separator for separating a low pressure refrigerant, which has been compressed by the decompression device, namely in a coolant gaseous Phase and a coolant liquid Phase. The decompression device and the gas-liquid separator are integrated.

At the Gas-liquid separator it is a relatively large component of the components for the Cooling circuit. The decompression device and the gas-liquid separator are in an arrangement integrated before it on an object, for example a vehicle body or an air conditioning chassis attached become. Thus, the decompression device on an object by attaching the gas-liquid separator attached to the object. Furthermore, the decompression device and the gas-liquid separator compactly constructed. About that addition, since the decompression device with the gas-liquid separator integrated before it was attached to the object, easy to Fasten. Furthermore, the decompression device and the gas-liquid separator are integrated into a single unit, they can be transported during transport easy handling and assembly.

Farther become the decompression device and the gas-liquid separator integrated into the arrangement in various ways. For example become the decompression device and the gas-liquid separator integrated by using common housing. As another example let the decompression device and the gas-liquid separator with each other, for example by welding or using Attach fastening or fixing means such as clamps and screws.

According to one Second aspect of the present invention has a component assembly for one Cooling circuit a decompression device for decompressing a high-pressure coolant and an internal heat exchanger to carry out the heat exchange between the high pressure coolant and a low pressure refrigerant, the was compressed by the decompression device. The decompression device and the inner heat exchanger are integrated.

In components of the refrigeration cycle, the decompression device and the internal heat exchanger have a relatively large number of coupling parts. The decompressor and the internal heat exchanger are integrated into one unit, and then one of the (decompression) decom Pressing device and inner heat exchanger attached to one object, so that the other (from the group) decompression device and inner heat exchanger is attached or fixed.

In In this case, since the pipes for connection of the decompression device and the internal heat exchanger are reduced or reduced, the structure of the cooling circuit simplified. Farther the components of the cooling circuit can be easily connected. Also, the decompression device and the internal heat exchanger becomes compact constructed. As the decompressor and the internal heat exchanger are integrated into a single unit, they can be transported during transport easy handling and assembly.

Farther are the decompression device and the internal heat exchanger integrated into the arrangement in various ways. For example are the decompression device and the internal heat exchanger provided integrally by a part, such as a housing, in common to have. As another example, the decompression device and the inner heat exchanger with each other, for example by welding or by using Fixing means such as clamps and screws, fixed or fixed.

At the Cooling circuit With the above arrangement, the assembly work is improved.

Other Objects, features and advantages of the present invention will become clearer from the following detailed description with reference to the attached Drawings in which similar Parts by similar Reference numerals are designated and in which:

1 a schematic representation of a refrigeration cycle for a vehicle with an arrangement of components according to a first embodiment of the invention;

2 shows a perspective view of the arrangement of components according to the first embodiment;

3 Fig. 12 is a partial perspective view of a heat exchanging part of an internal heat exchanger of the refrigerating cycle, which partially comprises a cross sectional view according to the first embodiment;

4 FIG. 12 is a schematic diagram of a refrigeration cycle for a vehicle having an arrangement of components according to the second embodiment of the present invention; FIG.

5 is a perspective view of the arrangement of components according to the second embodiment;

6 is a schematic representation of a refrigeration cycle for a vehicle with an assembly of components according to a third embodiment of the present invention;

7 is a perspective view of the assembly of components according to the third embodiment;

8th is a schematic representation of a refrigeration cycle, installed on a vehicle as related art or other design; and

9 is a schematic representation of the in 8th shown cooling circuit.

First Embodiment

A first embodiment will now be described with reference to FIGS 1 to 3 to be discribed. To 1 For example, a refrigeration cycle is used as a supercritical vapor compression refrigeration cycle for a vehicle air conditioner. As a coolant, for example, carbon dioxide is used. Alternatively, ethylene, ethane, nitrogen oxide or the like may be used as the refrigerant. In this embodiment, refrigerant discharged from a compressor has a pressure equal to or greater than a critical pressure to thereby provide a specified refrigerating capacity.

The refrigeration cycle generally includes a compressor 10 , a gas cooler 100 as a high-pressure side heat exchanger, an expansion valve 300 as a decompression device, an internal heat exchanger 200 , an evaporator 400 as a low-pressure side heat exchanger and a collector 500 as a gas-liquid separator 500 , In the cooling circuit in particular, the expansion valve 300 and the collector 500 integrated into the component assembly A1. Hereafter the above components 10 . 100 . 200 . 300 . 400 . 500 described in accordance with a flow of the coolant.

The compressor 10 is powered by the engine of a vehicle. The compressor 10 Absorbs and compresses coolant. Here is a general compressor as a compressor 10 used, the construction of the compressor 10 is not limited to a particular type. Thus, the structure of the compressor 10 not described in detail. Also, the compressor can 10 to be an electric compressor.

The compressor 10 is with the gas cooler 100 connected by a first cooling hose H1 of a flexibility such that in the compressor 10 compressed high-pressure coolant into the gas cooler 100 is introduced. The gas cooler 100 is arranged so that air through the gas cooler 100 goes while the vehicle is running or by a cooling fan (not shown) generated air passes through the gas cooler 100 , The gas cooler 100 takes the heat exchange between the from the compressor 10 discharged high pressure coolant and the air, whereby the high pressure coolant is cooled. Here is the structure of the gas cooler 100 not limited to a particular type, and the gas cooler 100 is designed as a general gas cooler. Thus, the structure of the gas cooler 100 not described in detail.

The gas cooler 100 is with a first Einlasssteilöffnung 301 of the expansion valve 300 connected by a first coolant tube P1. This is how the gas cooler is made 100 discharged coolant in the first inlet opening 301 of the expansion valve 300 introduced. The first coolant pipe P1 is made of metal. Here is the expansion valve 300 as a part of the assembly A1. At the expansion valve 300 it is an expansion valve of well-known box type and has a first coolant channel or passage and a second coolant channel or passageway therein. Also has the expansion valve 300 a temperature sensing part (not shown) in the first coolant passage.

In the expansion valve 300 The high-pressure coolant flows out of the first inlet opening through the first coolant channel, which is in communication with the temperature sensing part 301 to a first discharge opening 302 , The first outlet opening 302 is with a high pressure coolant inlet 202 of the internal heat exchanger 200 connected by a metallic second coolant pipe P2.

The inner heat exchanger 200 takes a heat exchange between that from the gas cooler 100 discharged high pressure refrigerant and a low-pressure refrigerant, which has a pressure lower than the pressure of the high-pressure refrigerant and in the compressor 10 to be sucked. The inner heat exchanger 200 has, as in 3 shown over a heat exchanging part 201 , The heat exchanging part 201 has a high pressure coolant passage 200a and low pressure coolant passages 200b ,

For example, the high-pressure coolant passage extends 200a along an axis of the heat exchanging part 201 and the low pressure coolant passages or channels 200b are arranged so that they are on a radially outer side of the high pressure coolant passage or passage 200a extend. In other words, the high pressure coolant passage 200a and the low pressure coolant passages 200b are arranged coaxially and thus has the heat exchanging part 201 essentially a double passage construction (double tube construction).

The inner heat exchanger 200 has an inlet 202 for high pressure coolant and an outlet 203 for high pressure coolant at the ends of the heat exchanging part 201 , The heat exchanging part 201 is bent into a U-shape. This is the high pressure coolant inlet 202 and the high pressure coolant outlet 203 adjacent each other on one end of the first heat exchanger 200 arranged. In this embodiment, the internal heat exchanger 200 provided as a single component and fixed at a suitable location in the engine compartment EC with a fastening or fixing element, for example a clamp and a (not shown) console. The construction of the internal heat exchanger 200 is not limited to the type discussed and illustrated above. The inner heat exchanger 200 can have a different shape and construction.

The outlet 203 for the high-pressure coolant of the internal heat exchanger 200 is with a second inlet opening 303 of the expansion valve 300 connected by a metallic third coolant pipe P3. In the expansion valve 300 is the second inlet opening 303 in connection with the second coolant channel, in which a (not shown) valve member is provided. Thus, the high-pressure coolant, which is the high-pressure coolant channel 200a of the internal heat exchanger 200 has penetrated into the second coolant channel of the expansion valve 300 from the second inlet opening 303 introduced.

The expansion valve 300 is configured to enthalpically decompress and expand the high pressure refrigerant. Also regulates the expansion valve 300 the pressure of the high pressure coolant based on the temperature of the gas cooler 100 discharged coolant.

The expansion valve 300 has a second outlet opening 304 at an outflow end of the second coolant channel. The second outlet opening 304 is with the evaporator 400 connected via a fourth metallic cooling pipe P4. Thus, the refrigerant, which has been decompressed by the valve member in the second coolant channel, from the second outlet opening 304 discharged and into the evaporator 400 introduced through the fourth coolant pipe P4.

The evaporator 400 takes the heat exchange between the low - pressure coolant, the expansion valve 300 decompressed and air to be introduced into the passenger compartment PC of the vehicle. The evaporator 400 Namely cools the air by evaporation of the low pressure coolant. The evaporator 400 is housed in an air conditioning unit mounted in the vehicle compartment PC. Here is the evaporator 400 a heat exchanger of known type, but its construction is not limited to a particular type. Thus, the structure of the evaporator 400 not described in detail.

Furthermore, an outlet opening of the evaporator 400 with a coolant inlet 501 of the collector 500 connected by a metallic fifth coolant pipe P5. Thus, low-pressure coolant, which is in the evaporator 400 was vaporized in the coolant inlet 501 of the collector 500 introduced. The collector 500 herein separates the low pressure refrigerant into a gaseous phase refrigerant and a liquid phase refrigerant therein and collects the excess of refrigerant therein as the liquid phase refrigerant. Also supplies the collector 500 the gaseous refrigerant and the cooling oil that has been separated and extracted are discharged to a suction side of the compressor 10 ,

Here is the collector 500 one of a known type and can have any structure. Thus, the construction of the collector 500 not described in detail. The collector 500 has a coolant outlet 502 that with a low pressure coolant inlet 204 of the internal heat exchanger 200 is connected by a sixth metallic coolant pipe P6. Thus, the gaseous refrigerant and the cooling oil in the low-pressure coolant channels 200b of the internal heat exchanger 200 introduced through the sixth coolant pipe P6.

The collector 500 is with respect to the expansion valve 300 for example, integrated into the assembly A1 prior to installation on the vehicle. For example, the collector 500 and the expansion valve 300 using fasteners, such as screws and the like, such as 2 recognize, integrated.

In this embodiment, the collector has 500 a stiff block on its upper part. This rigid block is formed with the coolant inlet 501 and the coolant outlet 502 to which the sixth coolant pipe P6 and the fifth coolant pipe P5 are respectively coupled. For example, the coolant inlet 501 and the coolant outlet 502 open in a direction substantially perpendicular to a longitudinal direction of the collector 500 , The expansion valve 300 is attached to the stiff block. Thus, the coolant inlet 501 , the coolant outlet 502 , the pipe coupling parts for the coolant pipes P5, P6 and the expansion valve 300 on or adjacent to the top of the collector 500 arranged in a concentrated manner.

Furthermore, the expansion valve 300 arranged such that the first and second coolant channels are provided adjacent to each other in a horizontal direction. The arrangement helps to reduce the height of the assembly A1.

The inlet and outlet openings 301 . 302 . 303 . 304 of the expansion valve 300 are formed so that the ends of the coolant tubes P1, P2, P3, P4 are coupled in the same manner as the coupling direction of the ends of the coolant tubes P5, P6. For example, the coupling parts of the first inlet opening 301 and the second outlet opening 304 on a first side of the expansion valve 300 trained and open in the same direction. Also, the first inlet opening 301 and the second outlet opening 304 open in the same direction as the coolant inlet 501 on the stiff block of the collector 500 is trained.

Likewise, the coupling parts are the first outlet opening 302 and the second inlet opening 303 on a second side of the expansion valve 300 are formed and are open in the same direction, the second side of the first side opposite. Also, the first outlet opening 302 and the second inlet opening 303 in the same direction as the coolant outlet 502 open, on the stiff block of the collector 500 is trained. Namely, the coupling parts for the pipes P1, P2, P3, P4 are separated on the first and second sides of the expansion valve 300 shaped.

Next is the first side of the expansion valve 300 with bolt holes 301 . 304a for receiving bolts for fixing the tubes P1, P4 formed. The bolt holes 301 . 304a are open in the same direction as a bolt hole 501 formed on the rigid block for receiving a bolt for fixing the pipe P5. Thus, the coolant tubes P1, P4, P5 are coupled in the same direction.

Similarly, the second side of the expansion valve 300 formed with bolt holes for receiving bolts for fixing the tubes P2, P3. The bolt holes of the second side may be open in the same direction as a bolt hole formed on the rigid block for receiving a bolt for fixing the hole P6. Thus, the coolant holes P2, P3, P6 are coupled in the same direction.

Also, the bolt holes 301 . 304a on an upper part of the expansion valve 300 educated. In other words, the bolt holes 301 . 304a are on the opposite side of the bolt hole 501 of the rigid block, based on the first inlet opening 301 and the second outlet opening 304 , educated. Thus, the coolant tubes P1, P4 are effectively coupled without disturbing the collector 500 would be eligible. Similarly, the bolt holes for fixing the coolant pipes P2, P3 are on the upper part of the second side of the expansion valve 300 realized. Thus, the coolant tubes P2, P3 are effectively coupled, without any disturbance to the collector 500 would be eligible.

Thus, the coupling parts of the tubes P1, P2, P3, P4, P5, P6 are associated with the assembly A1 and at or adjacent to the upper part of the collector 500 arranged in a concentrated manner. Thus, the tubes P1, P2, P3, P4, P5, P6 are simply coupled and fixed.

The associated components are integrated with the collector 500 in the assembly A1, before they are mounted on the vehicle. The assembly A1 is integrally mounted on and fixed to a vehicle body via a bracket or a bracket BKT as a support member. In the in 2 As shown, the console BKT has a support member for holding the assembly A1. The carrier part contacts the collector 500 and only keeps the collector 500 , Namely, the support part has a support wall which is an outer surface of a columnar body (tank body) of the collector 500 surrounds and contacts attachment walls at the ends of the support wall to be fastened by fixing parts such as screws. Thus, the arrangement A1 is detachably held by the support part of the console BKT.

The BKT bracket holds the assembly A1 in a location slightly higher than, for example, a center portion of the collector 500 lies in the vertical direction. The console BKT has a mounting wall for attachment to a vehicle body. The fixing wall extends generally along an axis of the columnar body of the collector 500 and bolt holes are formed on the fixing wall at separate locations. Thus, the console BKT is fixed or fixed to the vehicle body by fastening bolts in the bolt holes.

That from the collector 500 discharged low pressure coolant enters the low pressure coolant inlet 204 of the internal heat exchanger 200 introduced through the sixth coolant pipe P6. In the inner heat exchanger 200 the low pressure coolant flows through the low pressure coolant channels 200b against the low pressure coolant outlet 205 while cooling the high pressure coolant passing through the high pressure coolant channels 200a flows. Then, the low pressure refrigerant becomes the low pressure refrigerant outlet 205 discharged and into the compressor 100 sucked in by a second coolant hose H2 of flexibility. In 1 denotes the double-dashed line 600 a radiator. The gas cooler 100 is in front of the radiator 600 arranged in the engine compartment EC.

When next Let the effects be described in this embodiment.

The collector 500 is a relatively large component of the components of the refrigeration cycle. The associated components and parts such as the expansion valve 300 are with the collector 500 integrated, and then becomes the collector 500 attached to the vehicle body. Thus, the associated components on the vehicle become together with the collector 500 mounted by the collector 500 is attached to the vehicle body.

In the above discussion are the collector 500 and the expansion valve 300 for example, integrated using the rigid block, screws and the like. Furthermore, the collector 500 and the expansion valve 300 be integrated by different types or means. For example, the collector 500 and the expansion valve 300 be provided integrally by a common part of a housing of the collector 500 with a housing of the expansion valve 300 is used. Alternatively, collectors 500 and expansion valve 300 be connected, for example by welding or by using fixatives such as brackets and screws.

Thus, the collector 500 and the expansion valve 300 compactly constructed. Also, the expansion valve 300 simply assembled. In addition, the collector 500 and the expansion valve 300 handled as a single unit and thus easily transported and handled during assembly. The expansion valve 300 is a box type expansion valve having the temperature sensing part in the cooling passage. This will be the expansion valve 300 easily integrated in the arrangement A1.

The expansion valve 300 and the collector 500 are attached to the vehicle body through the same console BKT. Therefore, the number of fixing elements such as bracket, bracket and screws is reduced and thus reduces the amount of fixing work for fixing the fasteners. As a result, this lowers the costs. Also, the spaces for the fixing elements and the work spaces for fixing the fixing elements are reduced. In addition, the weight of the cooling circuit is reduced.

In the cooling circuit with the component assembly A1, the assembly work is improved. At the In this embodiment, the cooling circuit has the inner heat exchanger 200 , The cooling circuit can also without internal heat exchanger 200 get along.

Second Embodiment

A second embodiment will now be described with reference to FIGS 4 and 5 described. Here, similar parts are denoted by like reference numerals, and a feature of this embodiment, which is different from the first embodiment, will now be mainly described. As in 4 to recognize, are the inner heat exchanger 200 and the expansion valve integrated, for example, in a component assembly A2 in the cooling circuit.

As in 5 to see is the expansion valve 300 integrated with the inner heat exchanger 200 , such that the first outlet opening 302 directly with the inlet 202 for the high pressure coolant, and the second inlet port 303 directly to the outlet 203 is connected for the high-pressure refrigerant, without the need for the second and third tubes P2, P3. The expansion valve 300 and the inner heat exchanger 200 are previously integrated into the assembly A2 and then the assembly A2 is mounted on and fixed to the vehicle body using the console BKT. In this embodiment, the collector 500 provided as a single component and mounted on a predetermined part in the engine compartment.

As in 4 This will be seen from the gas cooler 100 discharged high pressure coolant into the first inlet opening 301 of the expansion valve 300 introduced through the first cooling tube P1. Then, the high pressure refrigerant flows to the first outlet port 302 through the first coolant channel of the expansion valve 300 , Furthermore, the high-pressure coolant flows into the inlet 202 for the high-pressure coolant of the internal heat exchanger 200 directly from the first outlet opening 302 ,

In the inner heat exchanger 200 The high pressure coolant exchanges heat with the low pressure coolant passing through the channels 200b for the low pressure coolant while passing through the high pressure coolant channel 200a flows. Then, the high pressure refrigerant becomes the second inlet port 303 directly from the outlet 203 for the high-pressure coolant of the internal heat exchanger 200 introduced.

In the expansion valve 300 the high pressure coolant is decompressed by the valve member (not shown) in the second coolant channel. Then the low pressure coolant enters the evaporator 400 from the second outlet opening 304 introduced through the fourth coolant pipe P4.

Afterwards, the low-pressure coolant flows through the evaporator 400 and then flows into the collector 500 through the fifth coolant pipe P5 in a similar manner to the first embodiment. Then that's the collector 500 discharged low pressure coolant the low pressure coolant inlet 204 of the internal heat exchanger 200 supplied through the sixth coolant pipe P6. In the flow through the low-pressure channels 200b of the heat exchanging part 201 The low pressure coolant exchanges heat with the high pressure coolant. Then, the low pressure refrigerant becomes the low pressure refrigerant outlet 205 discharged and into the compressor 10 sucked through the second coolant hose H2.

When next should the effects of the second embodiment described in more detail become.

The inner heat exchanger 200 as well as the expansion valve 300 have a relatively large number of coupling parts. The inner heat exchanger 200 and the expansion valve 300 are integrated into the assembly or unit A2 before being attached to the vehicle body. The integrated internal heat exchanger 200 as well as the expansion valve 300 are mounted together on the vehicle body by one (out of the group) internal heat exchanger 200 and expansion valve 300 be attached to the vehicle body.

Here are the inner heat exchanger 200 as well as the expansion valve 300 integrated by various means or means. For example, the internal heat exchanger 200 as well as the expansion valve 300 be provided integrally by using a common housing. Alternatively, the internal heat exchanger 200 as well as the expansion valve 300 connected, for example by welding or by the use of fastening or fixing elements such as clamps, brackets and screws.

This will be pipes for connection of expansion valve 300 and inner heat exchanger 200 eliminated. The coupling construction between the expansion valve 300 and the internal heat exchanger 200 is so simplified. Also, since the number of tubes in the refrigeration cycle is reduced, the refrigeration cycle can be easily assembled within the engine compartment.

Because the inner heat exchanger 200 and the expansion valve 300 integrated and compact, the components of the refrigeration cycle are mounted in a smaller space. Furthermore, can be internal heat exchanger 200 and expansion valve 300 easy to assemble. In addition, the inner heat exchanger 200 as well as the expansion valve 300 handled as a single unit and thus easy to transport and assemble.

In the cooling circuit is the inner heat exchanger 200 in the flow direction behind the gas cooler 100 arranged, the expansion valve 300 is downstream of the inner heat exchanger 200 arranged relative to the flow of the high-pressure coolant. To the pressure of the high-pressure coolant in the expansion valve 300 To control the temperature of the high pressure refrigerant at a location behind the gas cooler 100 He feels. Since the inner heat exchanger 200 configured so that the inlet 202 for the high pressure coolant and the outlet 203 are arranged adjacent to each other for the high pressure coolant, the pressure control can be in the expansion valve 300 easy to do.

As an expansion valve 300 box type is used, the first outlet opening 302 and the second inlet opening 303 of the expansion valve 300 directly with an inlet 202 for the high pressure coolant and the outlet 203 for the high-pressure coolant of the internal heat exchanger 200 each connected. Here is the construction of the internal heat exchanger 200 not limited to the U-shape as long as the high pressure coolant inlet 202 and the high pressure coolant outlet 203 are arranged adjacent to each other.

Alternatively, if the inlet 202 for the high pressure coolant and the outlet 203 for the high pressure refrigerant at separate locations, a pipe is connected to one (from the group) inlet 202 for the high pressure coolant and outlet for the high pressure coolant 203 coupled, and one end of the tube is close to the other from high pressure coolant inlet 202 and high pressure coolant outlet 203 arranged.

The heat exchanging part 201 of the internal heat exchanger 200 has a construction of double sewer pipe by the high pressure coolant duct 200a and the low pressure coolant channels 200b are aligned coaxially. The heat exchanging part 201 is formed by bending. Therefore, the inlet can be 202 for the high pressure coolant and the outlet 203 for the high pressure refrigerant slightly adjacent each other by bending the heat exchanging part 201 arrange in U-shape. Alternatively, the shape of the internal heat exchanger 200 according to the space available in the engine compartment. Thus, the arrangement A2 can be provided compact.

Third Embodiment

A third embodiment will now be described with reference to FIGS 6 and 7 to be discribed. As in 6 shown are the inner heat exchanger 200 , the expansion valve 300 and the collector 500 integrated, for example, in a component assembly A3 in the cooling circuit. Next, as in 7 shown is the expansion valve 300 arranged so that the first outlet opening 302 directly with the inlet 202 for the high-pressure coolant of the internal heat exchanger 200 is connected, and the second inlet opening 303 is directly with the outlet 203 for the high-pressure coolant of the internal heat exchanger 200 connected.

Also, the coolant outlet 502 of the collector 500 directly with the low pressure coolant inlet 204 of the internal heat exchanger 200 connected. The inner heat exchanger 200 , the expansion valve 300 and the collector 500 are integrated into the assembly A3 before being attached to the vehicle body. The assembly A3 is attached to and fixed to a predetermined position in the engine room with the console BKT.

That from the gas cooler 100 discharged high-pressure coolant is in the first inlet opening 301 of the expansion valve 300 introduced via the first cooling tube P1. In the expansion valve 300 the high-pressure coolant flows through the first coolant channel and reaches the first outlet opening 302 , Then the high pressure coolant flows directly into the inlet 202 for the high-pressure coolant of the internal heat exchanger 200 from the first outlet opening 302 of the expansion valve 300 ,

In the inner heat exchanger 200 The high pressure coolant exchanges heat with the low pressure coolant passing through the low pressure coolant channels 200b flows while passing through the high pressure coolant channel 200a goes. Then, the high pressure refrigerant flows directly into the second inlet port 303 of the expansion valve 300 from the high pressure coolant outlet 203 of the internal heat exchanger 200 ,

In the expansion valve 300 For example, the refrigerant is decompressed by the valve member (not shown) as it flows through the second coolant channel. The decompressed refrigerant is added to the evaporator 400 from the second outlet opening 304 introduced through the fourth coolant pipe P4.

After passing through the evaporator 400 The low-pressure coolant flows through the fifth coolant pipe P5 and enters the coolant inlet 501 of the collector 500 introduced. Then the refrigerant is in the gas phase and the cooling oil is in the collector 500 were separated into the inlet 204 For the low pressure coolant of the internal heat exchanger 200 directly from the coolant outlet 502 of the collector 500 introduced.

In the inner heat exchanger 200 The low pressure coolant exchanges heat with the high pressure coolant passing through the high pressure coolant channel 200a flows while the flow through the low-pressure coolant channels 200b takes place. Afterwards, the low-pressure coolant from the outlet 205 for the low pressure coolant of the internal heat exchanger 200 discharged and into the compressor 10 sucked through the second coolant hose H2.

The heat exchanging part 201 of the internal heat exchanger 200 for example, is of double-tube channel structure, wherein an inner tube, the high-pressure coolant channel 200a forms, and an outer tube surrounds the inner tube like a housing and the low-pressure coolant channels 200b between the outer tube and the inner tube manufactures. The inner heat exchanger 200 has coupling parts at its ends as the high pressure refrigerant inlet and outlet 202 . 203 , and the coupling parts are arranged at specific locations around the first outlet opening 302 and the second inlet opening 303 of the expansion valve 300 correspond to. The coupling parts between the expansion valve 300 and the internal heat exchanger 200 are similar to those at the second in 5 configured embodiment configured.

The heat exchanging part 201 of the internal heat exchanger 200 is of substantially U-shaped shape. The heat exchanging part 201 extends along the side wall and the bottom wall of the columnar body of the collector 500 against a radially opposite side. Also lies the heat exchanging part 201 at a distance from the outer surfaces of the tubular body of the collector 500 ,

Such as in 7 shown includes the heat exchanging part 201 straight parts that extend along the side wall of the columnar body of the collector 500 extend on one side, as well as parts which extend along the bottom wall of the columnar body against the other side of the columnar body, parts which extend along the side wall of the columnar body on the opposite side, and a deflecting member which deflects along the Side wall of the columnar body on the opposite side forms.

The console BKT holds the columnar body of the collector 500 in a way similar to the first in 2 shown embodiment. The inner heat exchanger 200 is from the collector 500 through the expansion valve 300 and the coupling parts between the inner heat exchanger 200 , the expansion valve 300 and the collector 500 carried.

Alternatively, the heat exchanging part 201 the inner heat exchanger directly through the console BKT be attached. As another example, the internal heat exchanger 200 at the collector 500 or any other object mounted or attached using an auxiliary console. In this embodiment, the coupling parts associated with the assembly A3 are at the upper part of the collector 500 arranged in a concentrated manner.

When next the effects of the third embodiment will be described.

The collector 500 is a relatively large component of the components of the refrigeration cycle. The expansion valve 300 and the inner heat exchanger 200 are with the collector 500 integrated into the unit A3, before the attachment to the vehicle body, then the collector 500 attached to the vehicle body. Thus, the associated components are mounted and fastened to the vehicle body by the collector 500 is attached to the vehicle body.

Here are the inner heat exchanger 200 , the expansion valve 300 and the collector 500 integrated in variable ways or by variable means. For example, the internal heat exchanger 200 and the expansion valve 300 with the collector 500 Thus, to a part summarized or integrated that parts, such as housing of the internal heat exchanger 200 and the expansion valve 300 , through parts of the housing of the collector 500 be formed. That is, the internal heat exchanger 200 , the expansion valve 300 and the collector 500 may be designed to form a housing therefrom. Alternatively, the internal heat exchanger 200 , the expansion valve 300 and the collector 500 be connected, for example by welding or by using brackets or screws.

This will make the pipes connect between the inner heat exchanger 200 , the expansion valve 300 and the collector 500 reduced and thus simplifies their designs. As a result, the refrigeration cycle is easily mounted in the engine compartment.

Furthermore, the inner heat exchanger 200 , the expansion valve 300 and the collector 500 in the arrangement A3, that is, integrated into a single unit. Therefore, the inner heat exchanger 200 , the expansion valve 300 and the collector 500 compactly constructed and housed in a reduced space. In addition, the inner heat exchanger 200 and the expansion valve 300 Can be easily assembled, the inner heat exchanger can continue 200 , the expansion valve 300 and the collector 500 handled as the single unit and thus easier to transport and handle during assembly.

at the above embodiments will the cooling circuit as supercritical Used cooling circuit, at the carbon dioxide as a coolant Use finds. However, the present invention is directed to the not discussed above, embodiments discussed above and illustrated let yourself rather, even in a subcritical vapor compression refrigeration cycle insert, in which the pressure of discharged from the compressor refrigerant less than the critical pressure and chlorofluorocarbon as the coolant Use finds. Also can one or several of the cooling tubes P1 to P6 and the coolant hose H2 be further integrally provided.

at the above embodiments will the console BKT, for example, on the vehicle body, for example as a frame, attached. The console BKT can also be on another Object, for example, attached to a chassis of an air conditioner become.

The for example embodiments of the present invention have been described. The present invention but is not limited to the example embodiment, can be rather in other ways, without the scope and meaning to deviate from the invention implement.

Claims (15)

Component arrangement for a refrigeration cycle, comprising: a decompression device ( 300 ) for decompressing a high pressure refrigerant flowing through the refrigeration cycle into a low pressure refrigerant; and a gas-liquid separator ( 500 for separating the low pressure refrigerant into liquid phase refrigerant and gaseous phase refrigerant and collecting an excess refrigerant therein, the decompression device (10) 300 ) and the gas-liquid separator ( 500 ) are integrated. Component arrangement for a refrigeration cycle, comprising: a decompression device ( 300 ) for decompressing a high pressure refrigerant flowing through the refrigeration cycle into a low pressure refrigerant; and an internal heat exchanger ( 200 ) for carrying out the heat exchange between the high-pressure coolant and the low-pressure coolant, wherein the decompression device ( 300 ) and the internal heat exchanger ( 200 ) are integrated. A component assembly according to claim 2, further comprising: a gas-liquid separator ( 500 for separating the low pressure refrigerant into liquid phase refrigerant and gaseous phase refrigerant and collecting an excess refrigerant therein, wherein the gas-liquid separator ( 500 ) with the decompression device ( 300 ) and the inner heat exchanger ( 200 ) is integrated. Component assembly according to claim 3, wherein the gas-liquid separator ( 500 ) a coolant outlet ( 502 ) for the discharge of refrigerant in gaseous phase, the internal heat exchanger ( 200 ) an inlet ( 204 ) for a low-pressure coolant and a low-pressure coolant channel ( 200b ) associated with the inlet ( 204 ) for the low pressure refrigerant to allow flow of the low pressure refrigerant, and the coolant outlet ( 502 ) of the gas-liquid separator ( 500 ) and the inlet ( 204 ) of the low-pressure coolant of the internal heat exchanger ( 200 ) are directly connected. Component arrangement according to one of claims 2 to 4, wherein the internal heat exchanger ( 200 ) a high pressure coolant channel ( 200a ) to allow the high pressure refrigerant to flow, and a high pressure coolant inlet ( 202 ) and a high pressure coolant outlet ( 203 ), which in conjunction with the high-pressure coolant channel ( 200a ), and the high pressure coolant inlet ( 202 ) and the high-pressure coolant outlet ( 203 ) of the internal heat exchanger ( 200 ) are arranged adjacent to each other. Component assembly according to claim 5, wherein the decompression device ( 300 ) has a first coolant channel, a temperature sensing channel arranged in communication with the first coolant channel for detecting a temperature of the high pressure coolant flowing through the first coolant channel, a second coolant channel, an expansion valve part disposed in communication with the second coolant channel second refrigerant channel to decompress flowing high pressure coolant, the decompression device has a first outlet ( 302 ) at one end of the first coolant channel to discharge the high-pressure coolant, and a second inlet ( 303 ) defi ned at one end of the second coolant channel to introduce the high pressure coolant into the second coolant channel, and the first outlet ( 302 ) of the decompression device ( 300 ) directly to the inlet ( 202 ) for the high-pressure coolant of the internal heat exchanger ( 200 ), and the second inlet ( 303 ) of the decompression device ( 300 ) directly to the outlet ( 203 ) for the high-pressure coolant of the first heat exchanger ( 200 ) connected is. Component assembly according to one of claims 2 to 6, wherein the inner heat exchanger ( 200 ) a heat exchanging part ( 201 ) for carrying out the heat exchange, and the heat exchanging part ( 201 ) of a double-pipe channel design in which a high-pressure coolant channel ( 200a ), which allows a flow of the high-pressure coolant, and a low-pressure coolant channel ( 200b ), which allows the flow of the low pressure refrigerant, are arranged coaxially. Component arrangement according to one of claims 1 to 7, wherein the decompression device ( 300 ) comprises a box-type expansion valve defining a first coolant channel therein and a temperature sensing portion disposed in communication with the first coolant channel for sensing a temperature of the high-pressure coolant flowing through the first coolant channel. Component assembly according to claim 8, wherein the gas-liquid separator ( 500 ) has a tank or collector body, and the decompression device ( 300 ) a coolant inlet ( 301 ) and a coolant outlet ( 302 ), which are in communication with the first coolant channel, and the decompression device ( 300 ) is arranged at one end of the tank body such that the coolant inlet ( 301 ) and the coolant outlet ( 302 ) are open in a direction substantially perpendicular to a longitudinal direction of the tank body. Component assembly according to one of claims 1 and 3 to 9, further comprising a carrier element (BKT), the at least one (from the group) decompression device ( 300 ) and gas-liquid separator ( 500 ) stores. Component assembly according to one of claims 3 to 9, further comprising a carrier element (BKT), the at least one (from the group) decompression device ( 300 ), inner heat exchanger ( 200 ) and gas-liquid separator ( 500 ) carries or stores. A component arrangement according to claim 10 or 11, wherein the support element (BKT) comprises a mounting wall which is to be fixed to an object, and a support wall which comprises at least one (from the group) decompression device (BKT). 300 ), inner heat exchanger ( 200 ) and gas-liquid separator ( 500 ) holds. Component arrangement according to one of claims 1 and 3 to 12, wherein the decompression device ( 300 ) and the gas-liquid separator ( 500 ) before they are attached to a part of a vehicle. Component arrangement according to one of claims 2 to 12, wherein the decompression device ( 300 ) and the internal heat exchanger ( 200 ) before being attached to a vehicle. Cooling circuit the component arrangement according to a the claims 1 to 14 inclusive.