The present invention relates to the field of heat exchangers, especially adapted to equip an air conditioning circuit of motor vehicle or to cool down any component of a vehicle.
Heat exchangers which equip air conditioning circuit of motor vehicle are organized to allow neighboring circulation into two spaces separated of two different fluids, in such a way to realize a heat exchange between the fluids without mixing them. A kind of heat exchanger used in the motor field is the plate-type heat exchanger, such heat exchanger being made by a pile of plates brazed between them and organized to define spaces where the fluids circulate.
Inside heat exchangers and thermodynamic circuits which are linked to these heat exchangers, fluids circulate with variable pressure, often high, about twenty bars. These high pressures, and their variation, apply important efforts on the heat exchanger components and on the thermodynamic circuit components, and especially the admission and evacuation fluid pipes. In addition to this efforts, some vibrations caused by movement of the vehicle are present, all this efforts and vibrations could, at the end, cause damages to the heat exchange, raising the necessity of maintenance for the heat exchanger.
Some solutions have been brought to solve this problem, for example with the augmentation of the wall thickness of the heat exchanger or the pipes. But, those solutions are not satisfactory because this augmentation of the wall thickness limits the fluids circulation and increases the production cost of a heat exchanger.
The invention aim at proposing a unit that resists to the rise of pressure inside the heat exchangers, and consequently to increase heat exchangers' lifespan without the drawbacks listed above.
The object of this invention is a heat exchanger for vehicle arranged to allow an internal circulation of at least one fluid, comprising at least a heat exchanger bundle and at least a duct at least partially outside the heat exchanger bundle, the duct penetrating into the heat exchanger bundle by a hole arranged in a terminal plate of the heat exchanger bundle, the duct comprising at least a collar lining the hole, characterized in that the heat exchanger comprises a reinforcing mean in touch with the collar of the duct and with the terminal plate of the heat exchanger bundle.
Heat exchanger according to the invention comprises optionally at least one of the following characteristics, taken alone or in combination:
The heat exchanger of the invention is having a first internal path adapted to a refrigerant fluid and a second internal path adapted to a liquid coolant. In other words, said heat exchanger may be called a fluid-cooled condenser.
The invention also concerns a vehicle equipped with a heat exchanger such as described above.
Other characteristics, details and advantages of the invention will stand out more clearly in the reading of the description given below for information purposes in connection with drawings in which:
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It is necessary to note first of all that figures expose the invention in great detail to implement the invention, the aforementioned figures which can naturally serve to define better the invention if necessary.
During the description, the longitudinal, vertical or transverse, lower, upper, internal or external refer to the orientation of the heat exchanger according to the invention. The longitudinal direction corresponds to the main axis of the heat exchanger in which its biggest dimension extends. The vertical direction corresponding to the sense of pile of tubes forming the bundle of the heat exchanger, the transverse direction being the perpendicular direction of the two other directions. The internal or external directions refer to the heat exchanger, the internal direction indicating the direction tending to get closer to the bundle of heat exchanger, the external directions indicating the directions tending to go away from the bundle of the heat exchanger. The longitudinal, transverse and vertical directions are also visible in a trihedron L, V, T represented on figures.
The
The heat exchanger 1 is a component of a refrigerant circuit which equips a vehicle, in particular a motor vehicle. According to the invention, the heat exchanger 1 implements an exchange of heat between a first fluid and second fluid, the first fluid being cooled by the second fluid. In such a configuration, the heat exchanger 1 is used as condenser for a sub-critical or super-critical refrigerant fluid. The second fluid is advantageously a coolant liquid, such as a mixture water-glycol.
The heat exchanger 1 includes a bundle of plates 2 where the exchange of heat between the first fluid and the second fluid takes place. The bundle 2 is globally formed by a pile of plates 4, stacked one onto the other along a direction of pile 3 of these plates 4. The bundle 2 includes in particular a first terminal plate 8 and a second terminal plate 9 which delimits the bundle 2 along the direction of pile 3. Between the first terminal plate 8 and the second terminal plate 9 is arranged the plurality of plates 4 which bounds two different circuits: a first circuit configured to be used by the first fluid and the second circuit configured to be used by the second fluid.
The heat exchanger 1 includes also ways of fluidically connecting these circuits with, on one hand an external circuit of the first fluid and, on the other hand, with an external circuit of the second fluid. The heat exchanger 1 includes a first duct 10 by which the first fluid can enter the heat exchanger 1 and a first conduit 12 by which the first fluid can go out of the heat exchanger 1. This heat exchanger 1 includes another second duct 13 by which the second fluid can enter the bundle 2, as well as a second conduit 11 by which the second fluid can go out of the bundle 2. It shall be noted that the bundle 2 includes a first opening and the second opening used by the second fluid and are in communication with a base 5 interposed fluidly between the heat exchanger 1 and the separation phase component 6, the latter being mechanically carried by the base 5. The base 5 is so a part of the heat exchanger 1, and is arranged in front of the second terminal plate 9.
The
The first terminal plate 8 is of a rectangular shape, and presents a cut 16 at a first longitudinal end 17. This cut 16 is configured to allow the insertion in the bundle 2 of the second duct 11. The insertion of the first duct 10 in the first terminal plate 8 is also made in the first longitudinal end 17. The first duct 10 fits into the first terminal plate 8, in particular at the level of a cavity 24 of lengthened form, extending between the first longitudinal end 17 and the second longitudinal end 18 of the first terminal plate 8.
The cavity 24 forms a swelling, of semicircular section, oriented towards the outside of the heat exchanger 1. This cavity 24 extends between a first edge 26 where the first duct 10 fits into the first terminal plate 8, and the second edge 28 was arranged in the second longitudinal end 18. The cavity 24 is arranged in particular to allow the flow of the fluid of the first edge 26, that is starting from the junction of the cavity 24 with the first duct 10, towards the second edge 28, where the fluid can pass by in the bundle 2 of the heat exchanger 1.
The insertion of the first duct 10 in the first terminal plate 8 allows the circulation of the fluid of the first duct 10 in the heat exchanger bundle 2. The first duct 10 is however external of the heat exchanger bundle 2, that is the majority of the first duct 10 extend outside the heat exchanger bundle 2. This insertion is strengthened by a reinforcing mean 20, configured at the interface between the first duct 10 and the first terminal plate 8. The reinforcing mean 20 takes in particular the shape of a flange 22, arranged radially around the first duct 10.
An example of such flange 22 is represented on
The flange 22 such as illustrated in the
The flange 22 includes more particularly a concave face and a convex face. The concave face of the flange 22 is a lower surface 68 of the flange 22, the convex face being an upper surface 66 of the flange 22. This measure is more clearly represented on
Still on
The flange 22 includes an opening 34 arranged to allow the insertion of the first duct 10 in the flange 22. The diameter of a part of the flange 22 surrounding the opening 34 is slightly bigger than an outside diameter of the first duct 10, and more particularly the first extremity of the first duct 10 as illustrated in
The example of flange 22 given above is not restrictive at all the invention, other forms of flange being possibly used. In particular, a flange 22 including a different number of radial extensions, or even no radial extension radial, is all the same able of strengthening the interaction between the first duct 10 and the first terminal plate 8 and enters consequently within the framework of the invention.
Several examples of arrangement of the first duct 10, of the first terminal plate 8 and of the reinforcing mean 20, illustrated in
On the
We can observe on this
The first duct 10 includes a collar 40. This collar 40 is of a first type, that is to say formed by a fold at 180° of the first duct 10. This arrangement confers on the collar 40 an aspect of annular swelling going out of the outside face 21 of the first duct 10. The collar 40 is configured in particular to fulfill the role of abutment, to limit the penetration of the first duct 10 within the first terminal plate 8 via the hole 58.
The flange 22 is positioned in contact of the first duct 10 and the first terminal plate 8.
On one hand, the flange 22 is more particularly positioned so that its lower surface 68, of concave conformation, is configured against the first terminal plate 8. In this arrangement, the first flat section 60 of the flange 22 is touching the neck 50, whereas the second flat section 62 is touching with a portion 52 surrounding the neck 50.
On the other hand, the flange 22 is located against the first duct 10, around said first duct 10. By this way, the first duct 10 is positioned in the opening 34 of the flange 22. In this arrangement, the upper surface 66 of the flange 22 is in touch with the collar 40 of the first duct 10. In a more specific way, the upper surface 66 is in touch with a lower face 80 of the collar 40, which is the face of the collar 40 in front of the first terminal plate 8. The flange 22 is so pinched between the first duct 10 and the first terminal plate 8.
In this arrangement, the forces and the vibrations supported by the first duct 10 are transferred to the flange 22 by the collar 40, in particular by the lower face 80 of the collar 40, the flange 22 passing on at least partially these forces and vibrations to the first terminal plate 8, in particular to the neck 50 and to the portion 52 surrounding the neck 50, what improves the resistance and the longevity of the assembly.
Peripherally to the neck 50, in the chamber 54, a brazing ring 56 is arranged so as to allow a contribution of metal to attach the first duct 10, the flange 22 and the first terminal plate 8, and so facilitate a step of brazing used during the manufacturing of the heat exchanger 1.
The collar 40 of the first duct 10 can be configured in a different way. In particular, a collar 42 of the second type is illustrated in the
A third embodiment of the invention is illustrated in the
In this embodiment, the first duct 10 includes a collar 40 identical to the collar exposed in the first embodiment illustrated in the
The second lower surface 74 of the flange 22 is in touch with the portion 52 arranged around the neck 50. Furthermore, because of the modification of position of the flange 22 with regard to the first embodiment, the lower face 80 of the collar 40 is touching, for example via a direct contact, with the neck 50 of the first terminal plate 8.
The third embodiment shares the other structural and functional characteristics of the first embodiment as described in the
In this embodiment, the first flat section 60 of the flange 22 extends in a third plan 76, the second flat section 62 spreading into a fourth plan 78. The third plan 76 and the fourth plan 78 are parallel one another, leaving tolerances aside. Furthermore, the portion 52 surrounding the neck 50 is flat and parallel simultaneously to the third plan 76 and to the fourth plan 78.
Another difference with regard to the other embodiments is the absence of a brazing ring in the chamber 54. It is nevertheless possible to add such a brazing ring in the chamber 54, as it is also possible to remove the one presents in the other embodiments, without escaping from the scope of the invention.
The configuration and the layout of the first duct 10 and the first terminal plate 8 are identical to those of the first duct 10 and the first terminal plate 8 of the first embodiment or of the third embodiment.
The preceding description clearly illustrate how the invention fulfills its objectives, as laid out in the preamble, and offers in particular to propose a heat exchanger comprising at least a reinforcing mean in touch with a collar of a duct and a terminal plate of a heat exchanger bundle, in order to limit torsion or movement of the duct versus the terminal plate.
Several modifications and improvement might be applied by the person skilled in the art to the heat exchanger as defined above, as long as a reinforcing mean as described above is implemented.
In any case, the invention cannot and should not be limited to the embodiments specifically described in this document, as other embodiments might exist. The invention shall spread to any equivalent mean and any technically operating combination of means.
Number | Date | Country | Kind |
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17461589 | Aug 2017 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/072012 | 8/14/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/034646 | 2/21/2019 | WO | A |
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5297823 | Dubost | Mar 1994 | A |
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5975193 | Tokita | Nov 1999 | A |
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20070000639 | Ozawa | Jan 2007 | A1 |
20180299054 | Person | Oct 2018 | A1 |
Number | Date | Country |
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1884960 | Dec 2006 | CN |
105659050 | Jun 2016 | CN |
19805439 | Aug 1999 | DE |
19805439 | Jun 2005 | DE |
1065463 | Jan 2001 | EP |
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Entry |
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International Search Report and Written Opinion corresponding to International Patent Application No. PCT/EP2018/072012, dated Oct. 31, 2018 (8 pages). |
First Office Action in corresponding Chinese Application No. 201880064070.X, dated Mar. 5, 2021 (11 pages). |
Number | Date | Country | |
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20200217601 A1 | Jul 2020 | US |