The present invention relates to a vortex separation device for a fluid transfer circuit, in particular of a motor vehicle, such as a motor vehicle heat transfer circuit.
Some fluids may contain gas bubbles. This is in particular the case for the heat transfer fluid used in a heat transfer circuit of a motor vehicle, which comprises a mixture of water and glycol and may comprise air or steam bubbles.
It is preferable to separate these gas bubbles from the fluid in order to optimize the performance of the circuit, and it is known to use a vortex separation device for this.
Such a device comprises an internal chamber connected to a fluid inlet and to two outlets, respectively of a liquid fraction and a gaseous fraction of the fluid. The device is configured so that the fluid arriving through the inlet is rotated around an axis A in the chamber to form a vortex for separating liquid and gaseous fractions. The centrifugal effect of the vortex allows to separate the liquid fraction radially outwards (with respect to the axis A) and the gaseous fraction radially inwards by density difference. The liquid fraction is expelled from the chamber through the liquid outlet which is generally positioned at the external periphery of the chamber, and its gaseous fraction is expelled from the chamber through the gaseous outlet which is generally located at the level of the axis A.
There are also devices for double circuits, i.e. two circuits for circulating two fluids (identical or different) are connected to the same vortex separation device. However, the solutions of the prior art do not allow an optimized operation of the device, in particular for fluid flow rates higher than about 10 L/min. Furthermore, these devices do not allow for effective isolation of the two independent circuits, which can have negative consequences, in particular in terms of heat exchange between the two circuits, in particular when the latter operate at different temperatures.
In particular, the present invention is intended to solve some or all of the above problems.
The invention relates to a vortex degassing device for a fluid transfer circuit, in particular of a motor vehicle, this device comprising:
The invention thus proposes to provide in particular the first chamber with a second outlet of a gaseous fraction that rises to the level of the fourth outlet. In particular, this arrangement allows to prevent the bubbles collected in the first chamber and discharged through the second outlet from being carried into the second chamber. This arrangement also allows to avoid the flow exchanges between the two chambers, and thus to limit the heat exchanges between the two chambers and thus between two independent sub-circuits of the circuit supplying the first and second chambers respectively. This limitation of the thermal exchanges allows in particular sub-circuits to operate at different temperatures while sharing a common separation device.
The invention also allows efficient operation at high flow rates, in particular above 10 L/min.
The device according to the invention may comprise one or more of the following characteristics, taken alone or in combination with each other:
The invention also relates to a fluid transfer circuit, in particular of a motor vehicle, comprising at least one device as described above.
The first and second chambers are connected by means of the fourth outlet to a common surge tank, for example.
The invention further relates to a method for using a device as described above in a fluid transfer circuit, in particular of a motor vehicle, in which a same fluid, for example a heat-transfer fluid, circulates in the first and second chambers, these fluids being at the same pressure and at different temperatures.
The invention will be better understood and other details, characteristics and advantages of the present invention will become clearer from the following description made by way of non-limiting example and with reference to the attached drawings, in which:
In particular, the device 1 is made of plastic material.
The device 1 comprises a first internal chamber 10 connected to a first inlet 11 of the first fluid F1 as well as to a first outlet 12 of a liquid fraction and to a second outlet 13 of a gaseous fraction. The second outlet 13 extends upwardly along an axis A. The first inlet 11 and the first outlet 12 are for example located at different positions along the axis A. The first inlet 11 is for example located above the first outlet 12.
The first chamber 10, the first inlet 11, the first outlet 12 and the second outlet 13 are part of the first sub-circuit.
The device 1 further comprises a second internal chamber 20. The second chamber 20 is located above the first chamber 10 along the axis A. The second internal chamber 20 is connected to a second inlet 21 of the second fluid F2 as well as to a third outlet 22 of a liquid fraction and to a fourth outlet 23 of a gaseous fraction. The fourth outlet 23 of a gaseous fraction extends at least partially upward along the axis A. The second inlet 21 and the third outlet 22 are for example located at different positions along the axis A. The second inlet 21 is for example located above the third outlet 22.
The second chamber 20, the second inlet 21, the third outlet 22 and the fourth outlet 23 are part of the second sub-circuit.
Unless otherwise specified, the adjectives inner/internal and outer/external are used in reference to a radial direction such that the inner (i.e. radially inner) part of an element is closer to the axis A than the outer (i.e. radially outer) part of the same element. Similarly, the terms above/below and upper/lower are used in reference to the position of the elements along the axis A relative to the ground.
In particular, the first and second inlets 11, 21 each have an average internal diameter of between 8 and 32 mm, preferably between 12 and 20 mm, and for example 16 mm.
In particular, the first and third outlets 12, 22 each have an average internal diameter of between 8 and 32 mm, preferably between 12 and 20 mm, and for example 16 mm.
The fourth outlet 23 has an average internal diameter of between 6 and 22 mm, preferably between 12 and 20 mm, and for example 16 mm.
The device 1 also comprises a first deflector 14 projecting into the first chamber 10. The first deflector 14 allows to guide and accelerate the first fluid F1 arriving through the first inlet 11. Thus, upon arrival through the first inlet 11, the first fluid F1 is forced to form a vortex in the first chamber 10 around the axis A, in order to separate the liquid and gaseous fractions of the first fluid F1. The liquid and gaseous fractions of the first fluid F1 are expelled through the first 12 and second 13 outlets respectively.
The device 1 also comprises a second deflector 24 projecting into the second chamber 20. The second deflector 24 allows to guide and accelerate the second fluid F2 arriving through the second inlet 21. Thus, upon arrival through the second inlet 21, the second fluid F2 is forced to form a vortex in the second chamber 20 around the axis A, in order to separate the liquid and gaseous fractions of the second fluid F2. The liquid and gaseous fractions of the second fluid F2 are expelled through the third 22 and fourth 23 outlets respectively.
The second outlet 13 extends through the second chamber 20 to the level of the fourth outlet 23. The second outlet 13 extends along the axis A in particular to above the second inlet 21. Thus, the bubbles in the lower circuit, i.e. in the first sub-circuit, are not entrained by the fluid circulating in the second chamber 20, i.e. in the second sub-circuit.
The second outlet 13 comprises a free upper end 13a which is axially spaced from the fourth outlet 23 or surrounded by the fourth outlet 23. The distance L1 measured along the axis A, between the upper free end 13a of the second outlet 13 and the second inlet 21 is greater than or equal to 5 mm, and preferably less than or equal to 15 mm. The second outlet 13 has a minimum passage cross-section S1 and the fourth outlet 23 has a minimum passage cross-section S2, with S1=k·S2, k being in particular between 0.8 and 1.2 and preferably equal to 1. Thus, the passage cross-sections S1, S2 of the bubbles in the two chambers 10, 20 are identical or very similar. The degassing and filling capacities of each of the chambers 10, 20 are then balanced.
In particular, the second outlet 13 is located in the center of the second chamber 20 so that it does not interfere with the tangential and/or peripheral flow of the second fluid F2 in the second chamber 20.
The internal shapes of the chambers, and in particular those of the deflectors 14, 24 are not necessarily identical. This allows to adapt to the particular conditions of fluid flow rate and gas quantity of each sub-circuit.
The device 1 comprises a generally cylindrical body 2 whose axis of revolution is coincident with the axis A and extends vertically here. The body 2 comprises a lower portion 3 comprising the first chamber 10. The body 2 comprises an upper portion 4 comprising the second chamber 20.
The device 1 or the body 2 has an external diameter D1, measured perpendicularly to the axis A, of between 40 and 80 mm, preferably between 50 and 60 mm, and for example of the order of 55 mm.
The device 1 or the body 2 has a length or height H1, measured along the axis A, which is between 80 and 180 mm, preferably between 110 and 150 mm, and for example 130 mm.
The device 1 also comprises fluidic connection end caps 11a, 21a, 12a, 22a, 23a projecting from the body 2 which form the first 11 and second 21 inlets, as well as the first 12, third 22 and fourth 23 outlets respectively.
The end cap 11a corresponds to the first inlet 11. Here it extends along an axis B. The axis B lies in a plane perpendicular to the axis A. This axis B is oriented tangentially to a circumference centered on the axis A.
The end cap 21a corresponds to the second inlet 21. Here it extends along an axis D. The axis D lies in a plane perpendicular to the axis A. This axis D is oriented tangentially to a circumference centered on the axis A.
The end cap 12a corresponds to the first outlet 12. Here it extends along an axis C. The axis C lies in a plane perpendicular to the axis A. This axis C is oriented tangentially to a circumference centered on the axis A. The end cap 12a is located here below the end cap 11a along the axis A.
The end cap 22a corresponds to the third outlet 22. Here it extends along an axis E. The axis E lies in a plane perpendicular to the axis A. This axis E is oriented tangentially to a circumference centered on the axis A. The end cap 22a is located here below the end cap 21a along the axis A.
The axes B, C, D, E are here in the same plane, in particular parallel to the axis A, but could be arranged in different planes.
The tangential position of the first and second inlets 11, 21, allows to reinforce the vortex effect of the device 1. Similarly, the tangential position of the first and third outlets 12, 22, allows to reinforce the vortex effect of the device 1. The first and second inlets 11, 21, as well as the first and third outlets 12, 22 may be located in a relative orientation different from the embodiment illustrated in
Thus, in the present invention, the inlets of the fluid to each chamber are optimized (vertically and horizontally) to reinforce the vortex effect for the two sub-circuits and the two chambers have been superimposed. Each chamber is thus similar to an optimized single flow system.
As shown in
As shown in
As shown in
As shown in
The third piece P3 is in the form of an inverted funnel. The third piece P3 comprises an upper chimney 31 forming the second outlet 13. The third piece P3 also comprises a lower dome 32.
The lower dome 32 is mounted in the body 2 so as to delimit the first and second chambers (not shown in
The first deflector 14 is for example integrated into the third piece P3. In particular, the first deflector 14 is connected to the dome 32 and extends along the axis A from the inside to the outside of the dome 32.
Thanks to the invention, a single piece (the third piece P3) separates the two internal volumes of the two chambers and ensures the guidance of the bubbles captured in the first chamber.
As illustrated in
Thus, the first fluid F1 enters the chamber 10 through the inlet 11 and is then set in rotation due to in particular the tangential position of this first inlet 11. The first fluid F1 thus undergoes a rotational movement and is further guided and accelerated by the first deflector 14. The first fluid F1 rotates and flows from top to bottom in the first chamber 10 forming the vortex along a direction referenced V1 in
Also, the second fluid F2 enters the second chamber 20 through the second inlet 21 and is then set in rotation due to the tangential position of this second inlet 21. The second fluid F2 thus undergoes a rotational movement and is further guided and accelerated by the second deflector 24. The second fluid F2 rotates and circulates from top to bottom in the second chamber 20 forming the vortex along a direction referenced V2 in
As shown in
As illustrated in
As shown in
The invention further relates to a method for using a device 1 as described above in a fluid transfer circuit F1, F2, in particular of a motor vehicle, in which the same fluid F1, F2, for example heat-transfer fluid, circulates in the first 10 and second 20 chambers. These fluids F1, F2 are at the same pressure and at different temperatures.
The invention can be applied to any type of fluid that may comprise gas bubbles. It is preferably developed in the case of a thermal control circuit of a motor vehicle.
The invention can in particular be used in the automotive sector in the broad sense (truck, bus, public works machines, agricultural machines, etc.), on all vehicles equipped with a fluid transfer circuit, such as a heat transfer circuit, and this regardless of their propulsion mode (combustion engine, electric motor, hybrid engine, etc.).
Number | Date | Country | Kind |
---|---|---|---|
2008788 | Aug 2020 | FR | national |
Number | Name | Date | Kind |
---|---|---|---|
3049343 | Helming | Aug 1962 | A |
3146998 | Golucke | Sep 1964 | A |
3969096 | Richard | Jul 1976 | A |
4211641 | Jager | Jul 1980 | A |
4271010 | Guarascio | Jun 1981 | A |
4783254 | Shah | Nov 1988 | A |
6193075 | Plas | Feb 2001 | B1 |
6746500 | Park | Jun 2004 | B1 |
7014671 | Oh | Mar 2006 | B2 |
7390339 | Warrick | Jun 2008 | B1 |
8690979 | Nagasawa | Apr 2014 | B2 |
9289782 | Hajash | Mar 2016 | B2 |
10758843 | Mendez | Sep 2020 | B2 |
11002645 | Wiederin | May 2021 | B2 |
11007541 | Chen | May 2021 | B2 |
11338232 | Schafrik | May 2022 | B2 |
20030172632 | Matsubara | Sep 2003 | A1 |
20100213118 | Tandon | Aug 2010 | A1 |
20180238619 | Baxter | Aug 2018 | A1 |
20190321756 | Kompala | Oct 2019 | A1 |
Number | Date | Country |
---|---|---|
2222597 | Jul 2007 | CA |
105903580 | Aug 2016 | CN |
841977 | Jun 1952 | DE |
102004019154 | Nov 2005 | DE |
0726386 | Aug 1996 | EP |
3082441 | Dec 2019 | FR |
2080706 | Feb 1982 | GB |
2004001204 | Dec 2003 | WO |
Number | Date | Country | |
---|---|---|---|
20220063373 A1 | Mar 2022 | US |