FR2940420A1 - COMBINED DEVICE COMPRISING AN INTERNAL HEAT EXCHANGER AND AN ACCUMULATOR COMPRISING A CLIMATEING MOUTH - Google Patents

Abstract

The invention relates to a combined device (12) comprising an enclosure (17) housing at least one internal heat exchanger (5) and an accumulation zone (18). The accumulation zone (18) is delimited by at least one lower wall (42). The bottom wall (42) is above the internal heat exchanger (5).

Description

Combined device comprising an internal heat exchanger and a storage battery constituting an air conditioning loop.

Technical Field of the Invention

The present invention is in the field of air conditioning loops cooperating with a ventilation system, heating and / or air conditioning of a motor vehicle. It relates to a combined device comprising an internal heat exchanger and a participating accumulator of such a loop.

It also relates to an air conditioning loop comprising such a combined device.

State of the art

A motor vehicle is commonly equipped with a ventilation, heating and / or air conditioning system to regulate the aerothermal parameters of the air contained inside the passenger compartment of the vehicle. Such an installation cooperates with an air conditioning loop to cool a stream of air prior to the delivery of the latter inside the passenger compartment. Said loop comprises a plurality of elements inside which circulates successively a cooling fluid, such as a supercritical fluid, carbon dioxide known under the reference R744 in particular. These elements comprise at least one compressor, a gas cooler, an internal heat exchanger, an expansion member, an evaporator and an accumulator.

The refrigerant flows from the compressor to the gas cooler, then through a high pressure branch of the internal heat exchanger, then to the expansion member, then through the evaporator, and then to the accumulator, and finally through a low pressure branch of the internal heat exchanger, to return to the compressor.

The compressor is intended to receive the refrigerant fluid in the gaseous state and to compress it to carry it at high pressure. The gas cooler is adapted to cool the compressed refrigerant at a relatively constant pressure, giving up heat to its environment. The expansion member is able to lower the pressure of the refrigerant leaving the gas cooler by bringing it at least partly in the liquid state. The evaporator is itself capable of passing the coolant in the liquid state from the expansion element, at relatively constant pressure, to the gaseous state, by taking heat from said air flow which passes through the 'evaporator. The vaporized refrigerant is then sucked by the compressor. These arrangements are such that the coolant is at high pressure inside the high pressure branch of the internal heat exchanger while it is at low pressure inside the low pressure branch of the heat exchanger. internal heat.

The accumulator provides a separation function between a gaseous phase and a liquid phase of the refrigerant. For this purpose, the accumulator comprises a separation zone dedicated to this function. The accumulator also provides a storage function for a circulating coolant charge depending on the conditions of use of the air conditioning loop. For this, the accumulator comprises a refrigerant storage zone in the liquid state that said accumulator collects from the evaporator. In its generality, the accumulator consists of an enclosure housing the separation zone and the accumulation zone, the enclosure comprising a bottom wall which delimits the accumulation zone in the lower part of the enclosure. Thus, the refrigerant fluid in the liquid state from the evaporator separates in the gas phase and in the liquid phase, the latter coming to accumulate by gravity above the lower wall, within the zone d 'accumulation.

The internal heat exchanger is configured so that the refrigerant circulating inside the high pressure branch can give heat to the refrigerant circulating inside the low pressure branch.

JP 10019421 (NIPPON SOKEN, DENSO CORP) proposes associating the internal heat exchanger and the accumulator in a combined device. In its generality, the latter comprises said enclosure which is provided with an opening closed by a cover. The chamber houses the internal heat exchanger which overhangs the refrigerant storage zone in the liquid state, the heat exchanger being interposed between the separation zone and the accumulation zone, in the use position. of the combined device on the air conditioning loop.

The high pressure refrigerant fluid from the gas cooler enters the interior of the combi device through a high pressure inlet through the lid to circulate within the internal heat exchanger and finally be discharged out of the combined device via a high pressure outlet also formed through the lid.

The low pressure coolant from the evaporator enters the interior of the combi device through a low pressure inlet still formed through the lid. The refrigerant fluid at low pressure and in the liquid state tends to accumulate by gravity above the lower wall of the enclosure while the refrigerant fluid at low pressure and in the gaseous state tends to concentrate in a zone upper enclosure. The latter houses a bent duct arranged in a U, a first end of which is disposed in the upper part of the enclosure to admit the refrigerant fluid at low pressure and in the gaseous state into the duct, and convey it to a second end of the conduit in communication with the internal heat exchanger. Inside the latter, the high-pressure refrigerant yields heat to the refrigerant at low pressure. The refrigerant fluid at low pressure and in the gaseous state is discharged from the internal heat exchanger and out of the combined device through a low pressure outlet which is also formed through the cover.

Such a combined device has disadvantages in view of excessive structural complexity that deserves to be simplified.

More particularly, such a combined device consists of a large number of disparate parts which generates manufacturing costs that should be reduced.

Finally, the device as described in JP 10019421 does not take into account the integration of such a combined device in a motor compartment of a vehicle. It appears to be restrictive with regard to the arrangement of the air-conditioning loop that the high-pressure and low-pressure refrigerant inlet and outlet are all provided on the same side, that is to say through the cover of the enclosure.

Object of the invention

A first object of the present invention is to provide a combined device comprising a chamber housing an internal heat exchanger and a liquid-medium refrigerant storage zone circulating through the combined device, the structural arrangement of the parts making up said device being as simple as possible, the number of these parts being as small as possible.

A second object of the present invention is to provide an air conditioning loop comprising such a combined device, the arrangement of the latter facilitating its integration on the air conditioning loop in certain conformations of the latter. The present invention takes into account the coolant inlet or outlet disposed at each end of the combined device according to the invention. Indeed, the circuit taken by pipes carrying refrigerant in the engine compartment is dictated by the available space in the latter. The connection of two pipes by end of the combined device has a significant advantage compared to a combined device according to the prior art where the four pipes are collected at the same end.

The device of the present invention is a combined device comprising an enclosure housing at least one internal heat exchanger and an accumulation zone. Said accumulation zone is delimited by at least one lower wall. The bottom wall is above the internal heat exchanger.

Preferably, the enclosure comprises an upper partition and a lower partition opposite to one another, the upper partition being equipped with a low pressure inlet and a high pressure outlet while the lower partition is equipped with a high pressure inlet and a low pressure outlet. The low pressure inlet is connected to the low pressure outlet via a low pressure circulation path which passes through the combined device, the high pressure inlet being connected to the high pressure outlet via a path high pressure circulation which passes through the combined device.

The upper partition is preferably arranged in a top closure cover of an upper opening that comprises the enclosure, while the lower partition is arranged in a lower cover of a lower opening that also includes the enclosure.

The upper lid is advantageously equipped with said low pressure inlet and said high pressure outlet while the lower lid is equipped with said high pressure inlet and the low pressure outlet.

According to a first embodiment, the enclosure comprises a tube housing a partition wall of said accumulation zone and the internal heat exchanger, the partition wall constituting said bottom wall.

According to a second variant embodiment, the enclosure comprises an upper receptacle and a lower receptacle associated head-to-toe to each other via their respective bottoms which together constitute said bottom wall. Preferably, the enclosure also houses a separation zone which adjoins the upper lid.

The accumulation zone is preferably interposed between the separation zone and the bottom wall.

A plate is preferably interposed between the separation zone and the accumulation zone.

A space is advantageously provided between an edge of the plate and at least one side wall delimiting the accumulation zone.

The high-pressure inlet and the low-pressure outlet are preferably diametrically opposed to one another relative to a longitudinal axis of extension A of the combined device, this axis being the longitudinal axis of the enclosure.

Preferably, the high pressure inlet, the low pressure outlet, the low pressure inlet and the high pressure outlet are contained in the same general extension plane P of the combined device.

The internal heat exchanger preferably comprises at least one flat tube wound on itself.

An air conditioning loop of the present invention is mainly recognizable in that said loop comprises such a combined device. In the position of use of the combined device on the air conditioning loop, the accumulation zone is advantageously above the air conditioner. internal heat exchanger.

The bottom wall preferably constitutes a wall for receiving a refrigerant fluid in the liquid state from an evaporator included in said loop.

Preferably, said low pressure circulation path constitutes a low pressure line BP of the air conditioning loop while said high pressure circulation path constitutes a high pressure line HP of the air conditioning loop.

Description of the figures.

The present invention will be better understood and details will arise from reading the description which will be made of variants in connection with the figures of the attached plates, in which: Fig.1 is a schematic illustration of an air conditioning loop comprising a combined device according to the present invention. Figures 2 and 3 are diagrammatic illustrations in longitudinal section of respective embodiments of the combined device shown in the previous figure.

In FIG. 1, a ventilation, heating and / or air-conditioning system fitted to a motor vehicle cooperates with an air-conditioning loop 1 to cool a stream of air 2 before the latter is delivered inside the vehicle. cabin of the vehicle. The air conditioning loop 1 comprises a compressor 3, a gas cooler 4, an internal heat exchanger 5, an expansion device 6, an evaporator 7 and an accumulator 8 inside which a cooling fluid circulates, such as a supercritical fluid, carbon dioxide known under the reference R744 in particular. More particularly, the refrigerant circulates from the compressor 3 to the gas cooler 4, then through a high pressure branch 9 of the internal heat exchanger 5, then to the expansion member 6, then through the evaporator 7, then to the accumulator 8, and finally through a low pressure arm 10 of the internal heat exchanger 5, to return to the compressor 3. These provisions are intended to allow a heat exchange between the fluid circulating refrigerant at high pressure and at high temperature inside said high pressure branch 9 and the coolant circulating at low pressure and at low temperature inside said low pressure branch 10, which has the effect of improving a coefficient of performance COP of the air conditioning loop 1.

The air conditioning loop 1 comprises an HP high pressure line which starts at the outlet of the compressor 3 and ends at the inlet of the expansion member 6, in a direction of circulation 11 of the refrigerant inside the air conditioning loop 1 , the gas cooler 4 and the high pressure branch 9 of the internal heat exchanger 5 being interposed between these two points.

The air conditioning loop 1 also comprises a low pressure line BP which starts at the outlet of the expansion element 6 and ends at the inlet of the compressor 3, according to the flow direction 11 of the refrigerant inside the air conditioning loop. 1, the evaporator 7, the accumulator 8 and the low pressure branch 10 of the internal heat exchanger 5 being interposed between these two points.

The accumulator 8, located downstream of the evaporator 7 in the direction of circulation 11 of the refrigerant fluid inside the air conditioning loop 1, allows the recovery of any refrigerant residue in the outgoing liquid state. of the evaporator 7. The accumulator 8 also allows a separation of a gaseous phase and a liquid phase of the refrigerant leaving the evaporator 7.

The internal heat exchanger 5 and the accumulator 8 are associated in a combined device 12 forming a monobloc assembly jointly ensuring the functions of the internal heat exchanger 5 and the accumulator 8. The combined character of said device 12 allows the internal heat exchanger 5 and the accumulator 8 to be installed simultaneously on the air conditioning loop 1, the latter forming an integrated assembly. This also has the effect of dispensing with a pipe installed in the engine compartment between the outlet of the accumulator 8 and the inlet of the low pressure branch 10 of the internal heat exchanger 5.

The combined device 12 has a high pressure inlet 13 through which the refrigerant from the gas cooler 4 is admitted inside the combi device 12. The combi device 12 also has a high pressure outlet 14 through which the fluid high pressure refrigerant is discharged from the combined device 12 to the expansion member 6. The high pressure inlet 13 and the high pressure outlet 14 are connected to one another via the high pressure branch 9 .

The combined device 12 also comprises a low-pressure inlet 15 through which the refrigerant from the evaporator 7 is admitted inside the combined device 12. The combined device 12 finally has a low-pressure outlet 16 through which the low-pressure refrigerant is discharged from the combined device 12 to the compressor 3. The low-pressure inlet 15 and the low-pressure outlet 16 are connected to each other in particular via the low-pressure branch 10 and only by a separation zone 41 and an accumulation zone 18 that comprises the combined device 12.

In FIGS. 2 and 3, the combined device 12 comprises a sealed enclosure 17 which houses the internal heat exchanger 5, the separation zone 41 between the gas phase and the liquid phase of the refrigerant leaving the evaporator 7 as well as the accumulation zone 18 of the coolant in the liquid state coming from the evaporator 7, or more particularly from the separation zone 41.

Said separation zone 41 preferably has a cyclonic structure in the sense that the low pressure inlet 15 is offset relative to a longitudinal extension axis 0 of the combined device 12 to allow a tangential admission of the refrigerant fluid from the evaporator 7 within said separation zone 41. These provisions are intended to promote separation between the gas phase and the liquid phase.

The accumulation zone 18 is delimited by a lower wall 42 against which the coolant in the liquid state from the evaporator 7 accumulates by gravity. The low-pressure inlet 15 being, in the position of use of the combined device 12 on the air-conditioning loop 1 and / or in the operating position of the combined device 12 alone, placed above the lower wall 42, the cooling fluid to the liquid state naturally falls by gravity from the low pressure inlet 15 to the bottom wall 42 to finally rest against it.

The bottom wall 42 is preferably perpendicular to the axis of longitudinal extension A of the combined device 12. The bottom wall 42 is in contact with and is extended by at least one side wall 43 which extends parallel to the axis of longitudinal extension A of the combined device 12. The side wall 43 is for example formed into a cylinder whose axis of symmetry A 'coincides with the longitudinal extension axis A of the combined device 12. The side wall 43 defines an opening upper 26 which is closed by an upper cover 25. It follows that the bottom wall 42, the side wall 43 and the top cover 25 envelop the accumulation zone 18 and the separation zone 41. In other words, the zone of accumulation 18 and the separation zone 41 are jointly confined between the bottom wall 42, the side wall 43 and the top cover 25.

The separation zone 41 is contiguous to said upper lid 25, being positioned directly below the latter. Thus, the accumulation zone 18 is placed between the separation zone 41 and the bottom wall 42. A plate 44 is interposed between the separation zone 41 and the accumulation zone 18, a space 45 being formed between an edge 46. of the plate 44 and the lateral wall 43 laterally delimiting the accumulation zone 18.

According to the present invention, the bottom wall 42, which delimits in the lower part the accumulation zone 18, is disposed above the internal heat exchanger 5. Against the habits of the field, the designers of the present invention have made the choice to have the lower wall 42 of the accumulation zone 18, and therefore a fortiori the accumulation zone 18 itself, overhanging the internal heat exchanger 5, while in due to the fact that the coolant in the liquid state from the evaporator 7 concentrates by gravity inside the accumulation zone 18, a combined device according to the prior art has a built-up accumulation zone below the internal heat exchanger. The terms above, below, overhang, lower and upper are to be understood in the position of use of the combined device 12. This position of use can easily be appreciated from the installation of the combined device 12 according to the invention in the air conditioning loop 1 of the vehicle. This position of use can nevertheless just as easily be appreciated with the combined device 12 alone, that is to say independently of its installation in the air conditioning loop 1, as long as its operation appears realistic. In this case, and from the easy identification of the lower wall 42 of the accumulation zone 18, the present invention is characterized in that the internal heat exchanger 5 is disposed below said bottom wall 42, which is covered and bathed by the cooling fluid in the liquid state, in the use position and / or in the operating position of the combined device 12.

Those skilled in the art being able not only to identify the accumulation zone 18 of a combined device 12 but also to recognize the upper cover 25 which delimits the accumulation zone 18 and which is provided with the low pressure inlet 15 of refrigerant, the same skilled person easily discerns the bottom wall 42, which is opposite to the top cover 25, and finds that according to the present invention, the bottom wall 42 covers the internal heat exchanger with respect to a vertical axis g symbolizing the earth's gravity, this vertical axis g being substantially parallel to said longitudinal extension axis A and to said axis of symmetry A '.

The accumulation zone 18 overhanging or placed above the internal heat exchanger 5 is understood to be higher than the internal heat exchanger 5, along the vertical axis g corresponding to the gravity.

Advantageously, this arrangement of the accumulation zone 18 which is higher than the internal heat exchanger 5 is understood to be directly above the internal heat exchanger 5, that is to say contained in a volume defined by the side wall 43 of the combined device 12 according to the invention and above the latter.

These arrangements are such that internal components delimiting a low pressure circulation path 36 and a high pressure circulation path 35, in particular pipes capable of transporting the refrigerant fluid, are reduced to the maximum, to avoid overweight and excessive space. Such pipes are also straight, which reduces the pressure drops inside the combined device 12 according to the invention. More particularly, said paths 35,36 do not include any angled duct that is highly detrimental to a smooth and homogeneous flow of the refrigerant fluid. For example, a high pressure circulation path 35 passes through the combined device 12 parallel to the axis of longitudinal extension A of the latter from one end to the other (outside the high pressure branch 9 of the heat exchanger. internal heat 5). Finally, in the current case where the refrigerant fluid comprises oil to improve the durability of the compressor 3, the fact that the accumulation zone 18 overhangs the internal heat exchanger 5 facilitates the reintegration of oil by gravity to the compressor. inside the low pressure branch 10 of the internal heat exchanger 5.

The internal heat exchanger 5 consists for example of a flat tube wound on itself, preferably around the longitudinal extension axis A of the combined device 12, the flat tube housing microchannels for the passage of the refrigerant fluid at high pressure, an interstitial space being formed between turns of the flat tube wound to allow passage between these turns of the refrigerant fluid at low pressure.

The internal heat exchanger 5 is for example still composed of two flat tubes wound around the longitudinal extension axis A of the combined device 12 so that the respective turns formed by said tubes are interlocked with one another. 'other. In another variant, the internal heat exchanger 5 comprises three flat tubes wound spirally, the first tube placed between the two other tubes or sandwiched between these two tubes is the tube participating in the high pressure circuit while the other two tubes are traversed by the refrigerant fluid at low pressure.

The top cover 25 constitutes a preferred embodiment of an upper partition 19 of the enclosure 17. Similarly, a lower cover 27 constitutes a preferred embodiment of a lower partition 20 of the enclosure 17, said lower cover 27 equipping a lower opening 28 of the enclosure 17.

The upper partition 19 and the lower partition 20 are opposed to each other, that is to say disposed at two opposite ends of the enclosure 17, the latter preferably being cylindrical and elongated. The upper partition 19 is equipped with the low-pressure inlet 15 of the refrigerant inside the combined device 12 and the high-pressure outlet 14 of the refrigerant fluid from the combined device 12. The lower partition 20 is equipped with the inlet high pressure 13 of the refrigerant inside the combined device 12 and the low-pressure outlet 16 of the coolant out of the combined device 12.

According to the preferred embodiment described above, the top cover 25 is equipped with the low-pressure inlet 15 of the refrigerant inside the combined device 12 and the high-pressure outlet 14 of the refrigerant outside the combined device 12 while the lower cover 27 is equipped with the high-pressure inlet 13 of the refrigerant inside the combined device 12 and the low-pressure outlet 16 of the refrigerant outside the combined device 12.

These arrangements are such that the combined device 12 is capable of being fluidly connected to the air conditioning loop 1 via the upper and lower partitions 19, and according to the said preferred embodiment by means of the upper covers 25 and It follows that the connections between the combined device 12 and, on the one hand, the compressor 3 and, on the other hand, the gas cooler 4 are formed by means of conduits connected to the lower cover 27 while the connections between the combined device 12 and on the one hand the evaporator 7 and on the other hand the expansion member 6 are formed by means of conduits connected to the top cover 25. Such arrangements facilitate the integration of the combined device 12 on the air conditioning loop 1, and therefore its integration into the engine compartment of the motor vehicle.

The high-pressure inlet 13 and the low-pressure outlet 16 are arranged diametrically opposite each other with respect to the longitudinal extension axis 0 of the combined device 12. More particularly, the high-pressure inlet 13 , the low pressure output 16, the low pressure input 15 and the high pressure output 14 are contained in the same longitudinal extension plane P of the combined device 12, such as the plane of FIGS. 2 and 3. The diametrically opposite arrangement allows to free up maximum space to accommodate the connectors of the air conditioning loop lines.

According to a first variant embodiment illustrated in FIG. 2, the enclosure 17 takes the form of a cylindrical tube 29 and elongated along the axis of longitudinal extension, Ù, that is to say the length of which is more important than its diameter. The tube 29 houses a partition wall 30 of the accumulation zone 18 and the internal heat exchanger 5. In this case, the partition wall 30 constitutes the bottom wall 42, that is to say a bottom receiving the refrigerant fluid in the liquid state above which the latter accumulates. This partition wall 30 is sealed inside the tube 29 so as to prevent any flow of refrigerant from the accumulation zone 18 to the internal heat exchanger 5 under the effect of gravity.

According to a second variant embodiment illustrated in FIG. 3, the enclosure 17 comprises an upper receptacle 31 and a lower receptacle 32 which are associated head-to-toe to each other via their respective bottom 33, 34.

In this case, the bottom 33 of the upper receptacle 31 constitutes the lower wall 42 for receiving the coolant in the liquid state above which the latter accumulates. The bottom 33 of the upper receptacle 31 overhangs the internal heat exchanger 5. The advantage of such a solution lies in the ability to manufacture an upper receptacle 31 and a lower receptacle 32 identical so as to standardize the parts used in the device 12 according to the invention.

A device 37 for recovering an oil carried by the refrigerant equips the low pressure circulation path 36 to facilitate the reintegration of oil upstream of the low pressure branch 10 of the internal heat exchanger 5.

The accumulation zone 18 is further provided with a desiccant material 38 for drying the coolant at low pressure. The accumulation zone is for example still provided with an oil filter 40 to retain impurities carried by the latter.

Claims (1)

A combined device (12) comprising an enclosure (17) housing at least one internal heat exchanger (5) and an accumulation zone (18), said accumulation zone (18) being delimited by at least one wall lower part (42), characterized in that the bottom wall (42) is above the internal heat exchanger (5). 2. Combined device (12) according to the preceding claim, characterized in that the enclosure (17) comprises an upper partition (19) and a lower partition (20) opposite to one another, the upper partition ( 19) being equipped with a low pressure inlet (15) and a high pressure outlet (14) while the lower partition (20) is equipped with a high pressure inlet (13) and a low pressure outlet ( 16), the low pressure inlet (15) being connected to the low pressure outlet (16) via a low pressure circulation path (36) which passes through the combined device (12), the high pressure inlet (13) being connected to the high pressure outlet (14) via a high pressure circulation path (37) which passes through the combined device (12) 3. Combination device (12) according to any one of the preceding claims, characterized in that the upper partition (19) is arranged in an upper cover (25) for closing an upper opening (26) that comprises the enclosure (17), while the lower partition (20) is arranged in a lower cover (27) for closing a lower opening (28) which also comprises the enclosure (17). 4.- Combined device (12) according to claims 2 and 3, characterized in that the upper cover (25) is equipped with said low pressure inlet (15) and said high pressure outlet (14) while the lower cover ( 27) is provided with said high pressure inlet (13) and the low pressure outlet (16). 16 5. A combined device (12) according to any one of the preceding claims, characterized in that the enclosure (17) is a tube (29) housing a partition (30) of said accumulation zone (18) and the internal heat exchanger (5), the partition wall (30) constituting said bottom wall (42). 6. Combination device (12) according to any one of claims 1 to 4, characterized in that the enclosure (17) is an upper receptacle (31) and a lower receptacle (32) associated head to tail one to the other through their respective bottoms (33,34), a bottom (33) of the upper receptacle (31) constitutes said bottom wall (42). 7. A combined device (12) according to any one of claims 3 to 6, characterized in that the enclosure (17) also houses a separation zone (41) adjacent to the upper cover (25). 8.- Combination device (12) according to claim 7, characterized in that the accumulation zone (18) is interposed between the separation zone (41) and the bottom wall (42). 9. A combined device (12) according to any one of claims 2 to 6, characterized in that a plate (44) is interposed between the separation zone (41) and the accumulation zone (18). 25 10.- combined device (12) according to claim 7, characterized in that a space (45) is provided between an edge (46) of the plate (44) and at least one side wall (43) defining the zone d accumulation (18). 11. Combination device (12) according to any one of the preceding claims, characterized in that the internal heat exchanger (5) comprises at least one flat tube wound on itself. 12. Air conditioning loop (1) comprising a combined device (12) according to any one of the preceding claims. 13.- air conditioning loop (1) according to claim 12, characterized in that in the use position of the combined device (12) on the air conditioning loop (1), the accumulation zone (18) is above the internal heat exchanger (5). 14.- air conditioning loop (1) according to any one of claims 12 out 13, characterized in that the bottom wall (42) constitutes a wall for receiving a coolant in the liquid state from a evaporator (7) that comprises said loop (1). 15.- air conditioning loop (1) according to any one of claims 12 to 14 taken in combination with claim 2, characterized in that said low pressure circulation path (36) is constitutive of a low pressure line BP of the air-conditioning loop (1) while said high-pressure circulation path (37) constitutes an HP high-pressure line of the air-conditioning loop (1).