This application claims priority to and all the advantages of International Patent Application No. PCT/EP2009/001932, filed on Mar. 17, 2009, which claims priority to French Patent Application No. FR 08/01546, filed on Mar. 20, 2008.
This invention relates to a heat exchanger for an air conditioning system. It also relates to a use of said heat exchanger as an internal exchanger of an air conditioning system, an integrated assembly for an air conditioning system operating with a coolant, and an air conditioning system comprising such an integrated assembly.
The invention is has a particularly advantageous use in the field of air conditioning systems operating with a supercritical coolant, such as carbon dioxide (CO2).
Air conditioning systems of this type generally include a compressor, a gas cooler, an internal exchanger, an expansion chamber and an accumulator. The coolant brought to high-pressure by the compressor is sent to the gas cooler in order to be cooled. The high-pressure fluid from the cooler then circulates in a first branch of the internal exchanger, and then is expanded by the expansion chamber. The low-pressure fluid then passes through the evaporator, then the accumulator before circulating in a second branch of the internal exchanger. The coolant then turns to the compressor to undergo another cycle.
In the internal exchanger, the hot high-pressure fluid circulating in the first branch exchanges heat with the cold low-pressure fluid circulating in the second branch.
The accumulator arranged at the outlet of the evaporator is designed to store the excess liquid present in the cold low-pressure fluid leaving the evaporator. This accumulator is generally in the form of a tank suitable for separating the liquid portion of the coolant from the gaseous portion. The accumulator sends the gaseous portion of the low-temperature coolant to the compressor after having passed through the internal exchanger.
Among the numerous internal exchangers known are that which, associated with a horizontal accumulator, forms the integrated assembly described in the French patent application no. 2 752 921. In this integrated assembly, the internal exchanger has a general spiral shape. A separation is provided between the windings of the internal exchanger so as to enable the circulation of the cold fluid, while the hot fluid circulates inside the tube wound in a spiral in parallel channels arranged perpendicularly to the axis of the tube.
This solution however involves providing a space between each winding in order to create the channel for the low-pressure fluid. It consequently creates significant diametral bulk.
To overcome this disadvantage, a heat exchanger for an air conditioning system, including a tube defining a path for the circulation of a fluid, called high-pressure fluid, and a second fluid, called low-pressure fluid, in which the tube is wound around an axis so as to define successive windings, has been proposed.
Also, in this exchanger, the successive windings of the tube are closely fit together so as to define leak-proof channels, called secondary channels, for the circulation of the second fluid, in which these secondary channels are located between projecting areas of the tube. The tube also has channels, called main channels, arranged in the projecting areas, intended to be passed through by the first fluid.
This known heat exchanger comprises an internal core with a substantially cylindrical shape placed at the center of the tube and consisting of a plurality of nested elements that simultaneously ensure the winding of the tube, the discharge of the first fluid at the outlet of the main channels and the supply of a second fluid at the inlet of the secondary channels.
However, this solution requires the implementation of a relatively complex internal core.
Another objective of the invention is to propose a heat exchanger for an air conditioning system that would in particular enable the architecture of the aforementioned known exchanger to be simplified at the outlet for the first fluid and the inlet for the second fluid.
This objective is achieved, according to the invention, by a heat exchanger for an air conditioning system, including a first tube defining a path for the circulation of a first fluid, called a high-pressure fluid, in which said first tube is wound in a spiral about an axis, called the axis of the exchanger, notable in that said heat exchanger also includes at least one second tube defining a path for the circulation of a second fluid, called a low-pressure fluid, in which said second tube is fastened to a face of the first tube and wound in a spiral with said first tube about said axis.
Thus, as will be seen in detail below, because the first and second fluids circulate in separate tubes, it is possible to separate the outlet of the first tube and the inlet of the second tube and therefore to provide separate means for discharging the first fluid and for supplying the second fluid, instead of requiring a single complex part simultaneously performing these two functions.
The invention also relates to a use of the heat exchanger according to the invention as an internal exchanger of an air conditioning system, notable in that said first fluid is a high-pressure fluid and said second fluid is a low-pressure fluid. In particular, said first and second fluids are made up of the same coolant, in particular a supercritical fluid.
According to an embodiment of the invention, said first tube comprises a plurality of main parallel channels each defining a path for circulation of the first fluid in a spiral about the axis of the exchanger. Advantageously, said main channels have a substantially circular cross-section for better resistance to the pressure of the first tube in which the first high-pressure fluid circulates.
Similarly, according to the invention, said second tube comprises a plurality of secondary parallel channels each defining a path for circulation of the second fluid in a spiral about the axis of the exchanger. Advantageously, said secondary channels have a substantially rectangular cross-section for a better surface for heat exchange between the second low-pressure fluid circulating in the second tube and the first high-pressure fluid circulating in the first tube.
In a preferred embodiment of the invention, the heat exchanger includes two second tubes fastened respectively to a face of the first tube.
This embodiment indeed makes it possible to obtain, by increasing the passage sections provided for the second tube, a reduction in head losses in the second branch of the exchanger, where the second low-pressure fluid circulates.
Of course, the invention nevertheless remains open to any number of second tubes for circulation of the second low-pressure fluid.
The invention also relates to an integrated assembly for an air conditioning system operating with a coolant, notable in that said integrated assembly comprises a housing in which an internal exchanger according to the invention is housed, between a lid and a base, in which said base is equipped with an inlet allowing the second fluid into the windings formed by said first and second tubes, and in that said housing comprises a second outlet tubing for the second fluid, parallel to the axis of the exchanger and comprising an outlet opening.
According to a particular embodiment, the integrated assembly according to the invention comprises a secondary inlet tubing for said second fluid, parallel to the axis of the exchanger and of which one end communicates with said outlet through said base.
According to this particular embodiment of the invention, said integrated assembly comprises an accumulator connected to the base of said integrated assembly, into which said second inlet tubing leads so as to communicate with said outlet.
According to a first alternative, the main tubings and the secondary tubings are arranged for co-current circulation of the first fluid in the first tube with that of the second fluid in the second tube.
According to a second alternative, the main tubings and the secondary tubings are arranged for counter-current circulation of the first fluid in the first tube with that of the second fluid in the second tube.
The invention finally relates to an air conditioning system operating with a coolant, including a compressor, a gas cooler, an expansion chamber and an evaporator, notable in that said air conditioning system comprises an integrated element according to the invention, in which the main inlet tubing is connected to the gas cooler and the main outlet tubing is connected to the expansion chamber, while the secondary inlet tubing is connected to the evaporator and the secondary outlet tubing is connected to the compressor.
The following description relating to the appended drawings, provided as non-limiting examples, will facilitate understanding of the invention and how it can be produced.
The air conditioning system 10 can be installed in a motor vehicle in order to cool the air of the vehicle interior, as needed by the passengers.
Such an air conditioning system operating according to a supercritical coolant cycle essentially includes a compressor 14, a gas cooler 11 associated with a fan 16, an internal heat exchanger 9, an expansion chamber 12, an evaporator 13 and an accumulator 17.
The compressor 14 compresses the coolant to a discharge pressure, called high pressure. The fluid then passes through the gas cooler 11 where it is subjected to cooling in the gaseous phase under high-pressure. During this cooling, the fluid is not condensed, unlike the air conditioning systems that use fluorinated compounds such as coolant.
The fluid thus cooled by the gas cooler 11 then circulates in a first branch 90 of the internal heat exchanger 9, called the “hot” branch, so as to be cooled again. The fluid then goes into the expansion chamber 12, which reduces its pressure, bringing it at least partially into the liquid state.
The fluid passing through the evaporator 13 then changes into the gaseous state under constant pressure. The heat exchange in the evaporator 13 enables an air conditioned air flow to be produced, which is sent to the vehicle interior.
Generally, the coolant leaving the evaporator is not entirely vaporized. The accumulator 17 is provided at the outlet of the evaporator 13 in order to store the excess liquid still contained in the fluid. The classic accumulators are in the form of a tank suitable for separating the liquid portion of the coolant from the gaseous portion.
The accumulator 17 then sends the gaseous portion of the low-temperature coolant into a second branch 92 of the internal heat exchanger, called the “cold” branch, for a heat exchange with the high-temperature coolant circulating in the “hot” branch 90.
As shown in
The internal exchanger 9 of
In other words, the first high-pressure tube is sandwiched between the second low-pressure tubes 120a, 120b so as to promote an exchange between the high-pressure fluid and the low-pressure fluid.
The way in which the different tubes are arranged with respect to one another in the heat exchange device 140 is also shown in
The circulation of the high-pressure fluid in the first tube 110 is ensured by a plurality of main parallel channels each defining a path for circulation of the high-pressure fluid in a spiral about the axis A of the exchanger. These main channels are contained in successive planes perpendicular to axis A. Although they are not shown in the figures, the French patent no. 2 752 921 provides a description of such main channels.
Advantageously, said main channels have a substantially circular cross-section so as to provide better resistance to pressure.
This same structure of channels can also be implemented in each second tube 120a, 120b of the secondary channels each defining a path for circulation of the low-pressure fluid in a spiral about the axis A of the exchanger, in which these main channels are contained in successive planes perpendicular to axis A.
Advantageously, said secondary channels have a substantially rectangular cross-section so as to provide a larger surface for heat exchange with the first tube 110 and to reduce the head losses along the path followed by the low-pressure fluid while providing the maximum effective passage section for the fluid through the second tubes 120a, 120b.
As shown more specifically in
The main tubings 111, 112 are not in contact with the internal or external faces of the second tubes 120a, 120b.
In practice, the main tubings 111, 112 are brazed or bonded to the ends of the first tube 110. Similarly, it can be seen in
As can be seen in
More specifically, a secondary inlet tubing 121 for the low-pressure fluid is provided, parallel to axis A of the exchanger, intended to receive the low-pressure fluid coming from the evaporator 13 of the air conditioning system, and to send it into the accumulator 17, passing through the base 160 of the exchanger. The low-pressure fluid separated from its liquid phase leaves the accumulator 17 through an inlet 161a, 161b for the low-pressure fluid in the heat exchange device 140, inside the windings formed by the first tube 110 and the second tubes 120a, 120b.
After having circulated in the two second tubes 120a, 120b and having exchanged heat with the high-pressure fluid circulating in the first tube 110, the low-pressure fluid arrives at the secondary channels in the housing 130 where it is collected by a secondary outlet tubing 122 equipped with an opening 123. The low-pressure fluid is then sent through the secondary outlet tubing 122 outside the exchanger in the direction of the compressor 14 of the air conditioning system.
In the embodiment of
The plate 160a, called the upper base plate, comprises holes 163a, 164a on which the secondary outlet tubing 122 for the low-pressure fluid and the main inlet tubing 111 for the high-pressure fluid are respectively brazed. Another hole referenced 162a is formed in the upper base plate 160a through which the secondary inlet tubing 121 for the low-pressure fluid passes. At the level of this hole, two alternatives are possible: one in which the secondary tubing 121 is brazed on the plate 160a at the level of the hole, and another in which the secondary tubing 121 is not mechanically connected to the plate 160a. Another hole 161a located substantially at the center of the windings of the tubes is instrumental to the inlet 160 for the low-pressure fluid in the heat exchange device 140.
The plate 160b, called the lower base plate, comprises a hole 162b for the passage of the secondary inlet tubing 121 for the low-pressure fluid, a hole 164b for the housing of the cap 115 of the main inlet tubing 111 for the high-pressure fluid and a hole 161b forming, with the hole 161a of the upper base plate 160a, the opening 160 for the low-pressure fluid. The secondary outlet tubing 122 for the low-pressure fluid simply comes into contact with the lower base plate 160b.
Similarly, the lid 150 of the exchanger consists of two plates referenced 150a, 150b.
The plate 150a, called the lower lid plate, comprises four holes 151a, 152a, 153a, 154a on which the main outlet tubing 112 for the high-pressure fluid, the secondary inlet tubing 121 for the low-pressure fluid, the secondary outlet tubing 122 of the high-pressure fluid and the main inlet tubing 111 for the high-pressure fluid are brazed.
The plate 150b, called the upper lid plate, enables the inlets/outlets for the high- and low-pressure fluids of the internal exchanger 9 to be connected to the corresponding inlets/outlets on the user side, which are located on a cap 170 capable of being attached on pins 151b, 152b of the upper lid plate 150b by means of screws passing through holes 171, 172 of the cap 170. Alternatively, the connection between the cap 170 and the upper plate 150b is produced by brazing at the level of the pints 151b and 152b.
It can be seen in the embodiment of
The accumulator is a separate part mechanically connected to the base 160 of the integrated assembly.
Alternatively, it is the accumulator that defines the housing 130 of the integrated assembly, which housing has the shape of a vat in which the bottom portion defines a chamber for receiving the fluid subjected to low pressure, which bottom portion extends plumb over the internal exchanger so as to end with an area of overlap with the cap 170, in which the latter enters the accumulator. It is therefore understood that the integrated assembly according to the invention is arranged and connected above the accumulator or is completely integrated in the accumulator.
The above description identifies a first fluid and a second fluid, but it is clear that, in a preferred embodiment of the invention, this fluid is identical and circulates in a closed loop in what forms the air conditioning system according to the invention.
Number | Date | Country | Kind |
---|---|---|---|
08 01546 | Mar 2008 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2009/001932 | 3/17/2009 | WO | 00 | 12/20/2010 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2009/115284 | 9/24/2009 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2136086 | Rosenblad | Nov 1938 | A |
2136153 | Rosenblad | Nov 1938 | A |
4100762 | Davis | Jul 1978 | A |
4655174 | Fillios | Apr 1987 | A |
4785878 | Honkajarvi et al. | Nov 1988 | A |
5242015 | Saperstein | Sep 1993 | A |
6681597 | Yin | Jan 2004 | B1 |
6935414 | Kawakubo | Aug 2005 | B2 |
20020083733 | Zhang | Jul 2002 | A1 |
20020092646 | Kuhn | Jul 2002 | A1 |
20020148600 | Bosch | Oct 2002 | A1 |
20030056532 | Dickson | Mar 2003 | A1 |
20030121648 | Hong | Jul 2003 | A1 |
20060196223 | Dexter | Sep 2006 | A1 |
20070264538 | Schank | Nov 2007 | A1 |
20080041093 | Sung | Feb 2008 | A1 |
20090114380 | Grabon | May 2009 | A1 |
20100155012 | Lemee | Jun 2010 | A1 |
Number | Date | Country |
---|---|---|
3634871 | May 1987 | DE |
0061779 | Oct 1982 | EP |
0529819 | Mar 1993 | EP |
2752921 | Mar 1998 | FR |
2913764 | Sep 2008 | FR |
2316738 | Mar 1998 | GB |
09-113152 | May 1997 | JP |
2000346584 | Dec 2000 | JP |
2002107069 | Apr 2002 | JP |
2007-178115 | Jul 2007 | JP |
51-88866 | Apr 2013 | JP |
WO 01-57454 | Aug 2001 | WO |
WO 2007-136379 | Nov 2007 | WO |
Entry |
---|
English language abstract for DE 3634871 extracted from espacenet.com database, dated Nov. 2, 2010, 7 pages. |
English language abstract for EP 0061779 extracted from espacenet.com database, dated Nov. 2, 2010, 11 pages. |
English language abstract for FR 2752921 extracted from espacenet.com database, dated Nov. 5, 2010, 20 pages. |
English language abstract for FR2913764 extracted from espacenet.com database, dated Nov. 2, 2010, 38 pages. |
English language translation and abstract for JP 09-113152 extracted from PAJ database, dated Nov. 5, 2010, 25 pages. |
English language translation and abstract for JP 2007-178115 extracted from PAJ database, dated Nov. 5, 2010, 38 pages. |
PCT International Search Report for PCT/EP2009/001932, dated Aug. 4, 2009, 4 pages. |
Number | Date | Country | |
---|---|---|---|
20110083468 A1 | Apr 2011 | US |