FR3059407B1 - DEVICE FOR MIXING A REFRIGERANT FLUID INSIDE A COLLECTOR BOX OF A HEAT EXCHANGER - Google Patents

Abstract

The invention relates to a mixing device (18) for mixing a gas phase with a liquid phase of a refrigerant fluid (FR). The mixing device (18) is configured to be housed inside a manifold (7) of a heat exchanger (5). The mixing device (18) comprises a duct (14) of longitudinal axis (A1) provided with an inlet mouth (10) for the admission of the refrigerant fluid (FR) into the duct (14) and at least one orifice (17) for spraying the refrigerant (FR) out of the conduit (14). The duct (14) comprises at least one mixing member (19a, 19b) provided on an inner face (14c) of the duct (14) and capable of modifying the flow of refrigerant (FR) flowing inside the duct (14).

Description

Device for mixing a coolant inside a manifold of a heat exchanger

The field of the present invention is that of heat exchangers equipping air conditioning installations for a vehicle, in particular an automobile. The invention relates more specifically to the methods of distributing a refrigerant fluid inside a manifold that includes such a heat exchanger.

A vehicle is commonly equipped with an air conditioning installation for heat treatment of the air present or sent into the passenger compartment of the vehicle. Such an installation comprises a closed circuit inside which a coolant circulates. Following the direction of circulation of the coolant through it, the circuit essentially comprises a compressor, a condenser, a pressure reducer and at least one heat exchanger. The heat exchanger commonly includes a bundle of tubes interposed between a manifold and a coolant return box. The refrigerant is admitted through an inlet mouth inside a manifold, circulates in successive paths in the tubes of the bundle between the manifold and a return box, then is evacuated from the exchanger thermal through an outlet. The outlet mouth may be formed through the manifold or through the return box. The heat exchanger is for example an evaporator providing a heat exchange between the refrigerant and an air flow passing through it. In this case, the refrigerant circulates inside the bundle tubes and the air flow circulates along the bundle tubes for its cooling.

One problem is that the refrigerant is in the liquid / gaseous two-phase state when it is admitted inside the heat exchanger. Due to the difference between the physical properties between the liquid and the gas, the refrigerant tends to separate between its liquid phase and its gas phase. This results in heterogeneity in the supply of the tubes of the bundle with regard to the different phases of the coolant, depending on their position relative to the inlet of the coolant inside the manifold. More particularly, the tubes of the bundle located closest to the inlet mouth are mainly supplied with liquid and conversely the bundle tubes furthest from the inlet mouth are mainly supplied with gas.

This phenomenon generates a heterogeneity in the temperature of the air flow which has passed through the heat exchanger in operation. This heterogeneity complicates the thermal management of the device that receives the heat exchanger and ultimately involves temperature differences between two areas of the passenger compartment, while the same air flow temperature is requested. It is known to house a conduit provided with a plurality of orifices inside a manifold. The liquid phase refrigerant is thus sprayed through the orifices in the form of droplets over the entire length of the duct, as shown in document EP 2 392 886 A2.

However, such an organization is not optimal from the point of view of the homogenization of the temperature of the air flow leaving the heat exchanger.

The subject of the present invention is a device for mixing a refrigerant configured to be housed inside a manifold of a heat exchanger into which tubes emerge from a bundle of tubes which the heat exchanger includes. . The mixing device is in particular intended to mix a gaseous phase with a liquid phase of the refrigerant fluid distributed by the mixing device inside the manifold. The invention also relates to a heat exchanger comprising a manifold housing a mixing device according to the invention. The heat exchanger is in particular arranged to equip an air conditioning installation of a vehicle, in particular an automobile.

An object of the invention is to perfect the uniformity of the temperature of the heat exchanger in operation and finally to improve its efficiency. It is more specifically targeted by the invention to perfect a distribution in the manifold of the refrigerant fluid homogeneously between its liquid phase and its gaseous phase. It is even more specifically targeted by the invention to provide a homogeneous supply of coolant to the tubes of the bundle opening onto the manifold. It is in particular intended to propose a manifold housing a mixing device capable of supplying refrigerant fluid to the tubes of the heat exchanger bundle, by providing efficient homogenization of the refrigerant fluid between its liquid phase and its gaseous phase, and a distribution homogeneous coolant inside each of the bundle tubes.

Another object of the invention is to propose a mixing device which can be obtained industrially at lower costs.

Another object of the invention is to propose a mixing device whose organization allows its easy adaptation and at lower costs to heat exchangers of various structures.

Such a diversity of structures of the heat exchangers is in particular to be appreciated with regard to the number of tubes of the bundle which they comprise, the modalities of circulation of the refrigerant fluid inside the heat exchanger and / or relative positions between the mouth inlet and outlet of the refrigerant contained in the heat exchanger.

The mixing device of the invention comprises a duct with a longitudinal axis provided with an inlet mouth for the admission of the refrigerant fluid into the duct and with at least one orifice for spraying the coolant fluid out of the duct. The duct comprises at least one mixing member formed on an internal face of the duct and capable of modifying the flow of the refrigerant fluid circulating inside the duct.

In other words, the internal face of the duct is configured as a mixing means comprising at least one mixing member capable of mixing the refrigerant fluid between a liquid phase and a gaseous face inside the duct. The mixing device is disruptive of a laminar flow of the refrigerant circulating inside the conduit from the inlet mouth to the orifice (s).

More particularly, the internal face of the conduit comprises at least one mixing member which modifies the regularity of the extension of the internal face of the conduit along a guideline, or more specifically along a generatrix, which is parallel to the longitudinal axis of the leads. The mixing member thus spares a relief on the internal face of the conduit which protrudes towards the interior of the conduit with respect to a direction of extension of the internal face of the conduit parallel to its longitudinal axis. The extension of the projection of the relief towards the inside of the duct is liable to vary between two mixing members.

Thus, the mixing member generates disturbances in the flow of the refrigerant fluid inside the duct, which promotes its mixing between a liquid phase and a gaseous phase inside the duct. A mixture of the refrigerant between a liquid phase and a gaseous phase is thus produced inside the conduit prior to its evacuation through the orifice (s). The refrigerant sprayed at each of the orifices is thus formed of a more homogeneous liquid / gas mixture, and this for each of the orifices distributed over the length of the duct.

The methods providing a mixture of the refrigerant between its liquid phase and its gaseous phase inside the conduit are thus advantageously dissociated from the methods of spraying the refrigerant out of the conduit further causing a mixture of the refrigerant between its liquid phase and its phase. gas at the outlet of the mixing device.

The refrigerant is thus mixed between its liquid phase and its gas phase by means of the mixing device in successive stages. A first mixing step is carried out inside the duct by one or more mixing members and a second mixing step is carried out during the spraying of the refrigerant fluid out of the duct through the opening (s).

A heat exchanger equipped with a manifold housing the mixing device is thus obtained particularly efficient, in particular having a temperature substantially balanced over the whole of its heat exchange surface formed by the tubes of a bundle of tubes which it includes.

More particularly, the mixing member extends inside the duct at least transversely to its longitudinal axis and partially inside the recess of the duct delimited by its wall, by forming an obstacle opposing a laminar flow of coolant inside the duct. The transverse extension of the mixing member with respect to the conduit may be perpendicular or inclined with respect to the longitudinal axis of the conduit. The obstacle formed by the mixing member is notably configured in a relief extending partially towards the interior of the duct. The central zone of the duct is unoccupied by the relief and provides a passage for the coolant inside and along the duct. The obstacle is capable of disturbing a laminar flow of the refrigerating fluid inside the duct and of forcing its passage through the orifice or orifices located downstream of the mixing member. The upstream and downstream concepts are relative concepts considered with regard to the intended direction of circulation of the refrigerant fluid inside the conduit or in other words with regard to a path of circulation of the refrigerant fluid formed inside the conduit from the inlet to the orifice.

According to an advantageous embodiment, the mixing member is incorporated into the wall of the duct.

The mixing device can thus be obtained at moderate costs by incorporating the mixing member into the internal face of the duct. The mixing device is easily adaptable for conduits having different extension dimensions along their longitudinal axis according to the configuration of the heat exchanger, in particular with regard to the number of tubes of a bundle to be supplied with refrigerant that the exchanger comprises. which lead to a manifold housing the mixing device. The incorporation of the mixing member into the wall of the duct can be carried out at low cost according to various techniques. For example, the mixing member is incorporated into the wall of the duct by brazing, by molding, by adding material, by deformation of the wall of the duct or by machining of the wall of the duct.

More particularly according to one embodiment, the mixing member is incorporated into the wall of the duct by brazing, the mixing member and the duct being at least in this case made of metallic material, in particular based on aluminum.

The brazing between the mixing member and the wall of the duct is notably carried out during a brazing operation between them of the components that a heat exchanger comprises and comprising at least one manifold housing the mixing device and preferably also tubes of a bundle of tubes to be supplied with refrigerant by the mixing device.

Brazing between the mixing device and the wall of the duct can also be carried out prior to the installation of the mixing device inside the manifold. The mixing device then forms a unitary assembly which can be easily mounted and positioned inside the manifold.

More particularly still according to one embodiment, the mixing member is incorporated into the wall of the molding duct or in other words during the manufacturing by molding of the duct. A molding operation can be carried out to simultaneously form in the same body the conduit provided with the mixing member. The incorporation by molding of the mixing member into the duct can also be carried out in several stages, including a first step of molding the duct and a second step of overmolding the mixing member inside the duct.

More particularly still according to one embodiment, the mixing member is incorporated into the wall of the duct by machining the wall of the duct providing at least one projecting relief oriented towards the inside of the duct, the relief then forming the mixing. More particularly still according to another embodiment, the mixing member is incorporated into the wall of the duct by deformation of the wall of the duct causing a discharge of material towards the interior of the duct which spares at least the relief then forming the mixing device.

According to one characteristic, the incorporation of the mixing member into the duct induces a variation in the thickness of its wall. More particularly, the thickness of the wall of the duct varies in planes perpendicular to the longitudinal axis of the duct and longitudinally distant. The thickness of the wall of the conduit is notably increased by at least one mixing member. The internal section of the duct is reduced by at least one mixing member. The mixing member then modifies the conformation of the wall of the duct by varying its thickness longitudinally. In other words, a first thickness of the wall of the conduit measured in a first perpendicular plane passing through a relief formed by the mixing member is greater than a second thickness of the wall of the conduit measured in a second perpendicular plane considered at the longitudinal edge of the relief .

According to one embodiment, at least one mixing member extends perpendicular to the longitudinal axis of the conduit.

According to another embodiment, at least one mixing member is inclined at least in a longitudinal extension plane and relative to the longitudinal axis of the duct, forming a ramp for guiding the refrigerant towards the orifice. The mixing member is in particular oriented according to the intended direction of circulation of the refrigerant fluid inside the conduit to direct the refrigerant fluid towards the internal face of the conduit defining its recess and more particularly towards the orifice (s).

For example, the mixing device can be of flat configuration, in particular being arranged in a ring. Such a ring can be oriented perpendicular to the longitudinal axis of the conduit. The ring can also be inclined relative to the longitudinal axis of the conduit in a longitudinal extension plane parallel to the longitudinal axis of the conduit and / or be oriented along a transverse plane inclined at an angle less than 90 ° by in relation to the longitudinal extension plan. The inclination of the mixing member can also imply its extension inside the duct along a curve defined by a combination between a perpendicular direction and a longitudinal direction relative to the longitudinal axis of the duct, in particular a helical extension. For example, at least one mixing member is formed by at least one helical thread formed in the wall of the duct and wound around the longitudinal axis of the duct.

The orifice (s) may be oriented perpendicular to the longitudinal axis of the duct or be inclined towards one and / or the other of the longitudinal ends of the duct.

The section of at least one orifice along a plane perpendicular to the longitudinal axis of the duct can be for example of circular, oblong and / or polygonal conformation such as triangular, hexagonal or cross for example. By way of indication, the section of the orifice (s) along a plane perpendicular to the longitudinal axis of the duct has a maximum surface area of between 2 mm and 5 mm.

Preferably, several orifices are distributed along the duct along its longitudinal axis. Various configurations for distributing the orifices along the conduit can be applied. For example, the orifices can be distributed by being aligned along several straight lines parallel to the longitudinal axis of the conduit. For example again, the orifices can be distributed in staggered rows along the duct. For example again, the orifices can be distributed along a line configured as a helix wound around the duct.

According to a preferred embodiment intended to simplify the structure of the mixing device and / or to allow it to be obtained at moderate costs, the orifices are distributed along a straight line parallel to the longitudinal axis of the conduit.

In addition, the inlet mouth is preferably formed at a first longitudinal end of the duct. A second longitudinal end of the conduit is closed. The second longitudinal end is understood as being the longitudinal end of the duct axially situated opposite its first longitudinal end provided with the inlet mouth.

The inlet mouth is in particular formed by an outlet from the recess of the conduit towards the outside of the conduit. In this case, the inlet mouth is notably connectable to a source of refrigerant fluid directly via the first end of the conduit or via a hydraulic member interposed between the conduit and the source of fluid. The fluid source is in particular formed of a refrigerant fluid circuit comprising the heat exchanger.

The second end of the duct is for example closed by a plug, by an end cap covering the second end of the duct and / or by a cover which can be integrated into the duct, in particular by soldering. The plug can also, for example, also be formed by a wall of the manifold placed in abutment against an end section of the conduit.

The characteristics relating to orifices presented below relate to a plane which extends parallel to the longitudinal axis of the duct and which passes through the duct (s). This plane is designated below longitudinal plane passing through at least one orifice.

According to one embodiment and in a longitudinal plane passing through at least one orifice, several mixing members are distributed along the longitudinal axis of the duct. It is understood here that in this plane, the mixing members are separated from each other by a non-zero longitudinal distance along the longitudinal axis of the conduit.

In this longitudinal plane passing through at least one orifice, at least one mixing member is arranged upstream of at least one orifice, in a direction of flow of the coolant inside the duct defined from the inlet mouth to the orifice. The obstacle formed by the mixing device disturbs the flow of the refrigerant and promotes its entrainment towards the orifice located downstream from the mixing device.

According to one feature and in a longitudinal plane passing through at least one orifice, at least one mixing member is interposed between at least two orifices distributed along the longitudinal axis of the conduit.

Thus, the mixture between a liquid phase and a gaseous phase of the coolant can be obtained homogeneously between the fractions of coolant flowing through each of the orifices. For this purpose, the relative positions between the orifices and the mixing members along the duct are adapted, taking into account in particular the speed of the refrigerant fluid inside the duct and / or the variation in the state of the mixture of the refrigerant circulating along the pipe.

According to one embodiment, in a longitudinal plane passing through at least one orifice, the mixing members are arranged at a first separation distance between two adjacent mixing members which is equal to a second separation distance from two adjacent orifices. According to an exemplary embodiment, at least one orifice is equidistant from two mixing members.

According to another embodiment, in a longitudinal plane passing through at least one orifice, the mixing members are arranged at a first separation distance between two adjacent mixing members which is greater than a second separation distance from two adjacent orifices.

According to one embodiment, in a longitudinal plane passing through at least one orifice, at least one mixing member is interposed between two groups of orifices each comprising, for information only, a number of orifices between one and four.

According to one embodiment, the mixing member is shaped as a ring, the opening of which passes through it through a passage for the refrigerant.

The periphery of the ring espouses in particular the internal face of the wall of the duct or in other words is in contact with the internal face of the duct along its circumference. The ring is preferably centered on the longitudinal axis of the duct. Such a ring can advantageously be secured by brazing to the pipe or, for example, it can also be formed by deformation of the wall of the pipe causing a discharge of material constituting the ring. As an indication, the dimension of the opening of the ring is between 10% and 70% of the largest dimension of the recess of the conduit measured in a plane perpendicular to the longitudinal axis of the conduit.

According to one embodiment, the openings of at least two successive rings along the longitudinal axis of the duct are of identical sections in the plane of the rings.

According to one embodiment, the openings of at least two successive rings along the longitudinal axis of the duct are of different sections in the plane of the rings.

Preferably, the sections of the openings of the rings vary according to their position along the longitudinal axis of the duct. The variations in the sections of the ring openings can be regular or irregular, in particular as a function of the successive positions of the rings, along the longitudinal axis of the duct.

More particularly according to one embodiment, the openings of the rings are progressively narrowed along the longitudinal axis of the duct from the first longitudinal end to the second longitudinal end of the duct or in other words according to the direction of circulation of the coolant from the inlet mouth towards the openings.

According to one embodiment, at least one mixing member is shaped into at least one portion of a helix wound around the longitudinal axis of the duct. It will be noted that at least one mixing member is capable of being shaped into a ring and at least one mixing member is capable of being shaped into at least one portion of a propeller.

According to one embodiment, several mixing members are shaped into helices of the same angularly distributed around the longitudinal axis of the conduit. More particularly, each of the propellers is wound around the longitudinal axis of the duct, extending along the duct in its part comprising the orifice (s).

According to one embodiment, at least one orifice passes through at least one mixing member. Such an arrangement is particularly applicable in the case where the conduit comprises mixing members shaped as helices, at least one orifice capable of passing through the projecting relief formed by a helix and at least one orifice capable of passing through the wall of the conduit between two helices. Such an arrangement is also applicable in the case where the conduit comprises mixing members shaped into rings, at least one orifice which can pass through a ring and at least one orifice which can pass through the wall of the conduit between two rings. Thus, transverse to the longitudinal axis of the conduit, a length of the orifices measured between these outlets is liable to vary, depending on its position along the longitudinal axis of the conduit. At least one orifice is capable of extending through the wall of the conduit by passing through a mixing member and at least one orifice is capable of extending through the wall of the conduit in an area of the conduit free of the mixing member .

The mixture of the refrigerant between a gas phase and a liquid phase can thus be controlled by varying the length of the orifices along the pipe. Depending on the character of the orifices passing through a mixing member or not, the mixture of refrigerant discharged through each of the orifices can be adjusted to provide a distribution of the refrigerant outside the mixing device which is generally homogeneous along the longitudinal axis of the leads.

More particularly, the mixture of the refrigerant between its gaseous phase and its liquid phase inside the duct can be controlled as a function of the relative positions of the orifices relative to the mixing members. It can in particular be taken into account a proximity between the obstacles formed by the mixing members and the outlet of at least a portion of the orifices inside the conduit, and / or the crossing character or not of at least one member. mixing by at least one orifice. The invention also relates to a heat exchanger equipped with a mixing device according to the invention.

More particularly, a heat exchanger of the invention comprises a manifold providing a chamber housing a mixing device according to the invention. The heat exchanger also comprises tubes of a bundle of tubes opening onto the chamber for their supply of coolant by the mixing device.

The mixing device is in particular incorporated into a wall of the manifold by brazing. The positioning of the mixing device inside the manifold can advantageously be achieved via at least one angular and / or axial positioning device interposed between the mixing device and a wall of the manifold. One or more such positioning devices are preferably provided at at least one of the longitudinal ends of the duct along its longitudinal axis. Brazing between the mixing device and a wall of the manifold can be carried out via at least one such positioning device.

According to one embodiment, a space for circulation of the coolant is provided inside the chamber at least partially around the mixing device towards the outlets of the bundle tubes on the chamber.

Thus, an additional step of mixing the refrigerant between its liquid phase and its gaseous phase can be carried out inside the chamber prior to its admission inside the tubes of the bundle.

According to one embodiment, the orifices and outlets of the tubes of the bundle on the chamber are angularly offset with respect to each other around the longitudinal axis of the conduit. The path of circulation of the coolant inside the manifold can thus be adjusted according to the mixture of coolant to be obtained inside the chamber. Such an adjustment is in particular provided via one or more angular and / or axial positioning devices interposed between the mixing device and a wall of the manifold.

For example, the orifices and outlets of the bundle tubes on the chamber are arranged diametrically opposite each other with respect to the longitudinal axis of the duct, to optimize the path of circulation of the coolant inside bedroom.

Preferably, the outlets of the bundle tubes on the chamber are formed through a wall of the manifold delimiting the chamber.

More particularly according to an advantageous embodiment, the tubes of the bundle are formed between plates incorporating the manifold by being stacked along the longitudinal axis of the conduit. The plates have eyelets which delimit the chamber and which are extended by extensions of the plates providing the bundle tubes with each other. The eyelets are crossed by the mixing device. The mixing device can be placed in contact with the eyelets at at least one of its ends. The heat exchanger is more particularly configured to be used as an evaporator. The heat exchanger can be used to cool an air flow passing through it or to cool a liquid dedicated to the cooling of an organ, such as at least one battery of a vehicle supplying the necessary energy at least in part to its propulsion. The invention also relates to a refrigerant circuit comprising at least one compressor, a condenser, an expansion device and a heat exchanger according to the invention, traversed by a refrigerant. The invention also relates to a ventilation, heating and / or air conditioning installation, or air conditioning installation, configured to equip a vehicle. The air conditioning installation of the invention comprises at least one heat exchanger according to the invention. Other characteristics, details and advantages of the invention will emerge more clearly on reading the detailed description given below by way of indication and for example in relation to the drawings of the appended plates, in which: - Figure 1 is a schematic illustration of a refrigerant circuit participating in an air conditioning installation of a vehicle. - Figure 2 is a schematic illustration of a heat exchanger that includes the circuit shown schematically in Figure 1. - Figure 3 is a perspective illustration of a mixing device according to the invention. - Figures 4 and 5 are partial illustrations of a mixing device according to an exemplary embodiment of the invention, shown in perspective in Figure 4 and in longitudinal section in Figure 5. - Figures 6 and 7 are partial illustrations of a mixing device according to another exemplary embodiment of the invention, shown in perspective in Figure 6 and in longitudinal section in Figure 7. - Figures 8 and 9 are partial illustrations of a device mixing according to another embodiment of the invention, shown in perspective in Figure 8 and in longitudinal section in Figure 9. - Figure 10 is a partial illustration in longitudinal section of an embodiment of a heat exchanger equipped with a mixing device of the type shown in Figures 6 and 7.

The figures and their description show the invention in detail and according to specific methods of its implementation. They can of course be used to better define the invention.

In FIG. 1, an air conditioning installation for a vehicle, in particular a motor vehicle, comprises a closed circuit 1 inside which a LR refrigerant fluid circulates. In the illustrated embodiment, the circuit 1 essentially comprises, successively in the direction SI of circulation of the refrigerant fluid LR, a compressor 2, a condenser 3 or gas cooler, an expansion member 4 and at least one heat exchanger 5 The example given of a minimum architecture of circuit 1 is given as an indication and is not restrictive as to the scope of the invention with regard to various potential architectures of circuit 1. The heat exchanger 5 is for example dedicated to cooling an air flow LA passing through it, as illustrated in FIG. 2. Such an air flow LA is used in particular to heat treat the air in the passenger compartment of the vehicle or for example also for cool an organ of the vehicle in operation. For example again, the heat exchanger 5 is dedicated to cooling a liquid used to cool an organ of the vehicle in operation, such as one or more batteries supplying electrical energy to a propulsive electric motorization of the vehicle.

In FIG. 1 and FIG. 2, the heat exchanger 5 comprises a bundle 6 interposed between a manifold box 7 and a return box 8. The manifold box 7 extends in a longitudinal direction DI oriented perpendicular to a direction D3 d extension of the tubes 12 of the bundle 6 between the manifold 7 and the return box 8. The manifold 7 defines a chamber 9 supplied with FR refrigerant through an inlet mouth 10. The FR refrigerant circulates at the inside the heat exchanger 5 to cool at least the tubes 12 of the bundle 6 and the air FA passing therethrough, then is evacuated from the heat exchanger 5 through an outlet mouth 11.

In the example illustrated, the outlet mouth 11 is formed through the manifold 7, which implies that the heat exchanger 5 is a heat exchanger with "U" circulation. Alternatively, the outlet mouth 11 can be formed through the return box 8, which then implies that the heat exchanger 5 is a heat exchanger with circulation in "I".

In FIG. 2, the heat exchanger 5 is of the U-shaped type of the refrigerating fluid FR. In the example illustrated, the heat exchanger 5 is intended for cooling an air flow FA. The tubes 12 of the bundle 6 comprise fins 13 promoting the heat exchange between the air flow FA and the tubes 12 of the bundle 6. The air flow FA crosses the bundle 6 transversely to the general plane PI of the heat exchanger 5, flowing along the tubes 12.

The refrigerant FR flows from the manifold 7 to a first layer 12a of tubes 12 of the bundle 6 dedicated to supplying the return box 8 with FR refrigerant. Then the refrigerant FR flows from the return box 8 to the manifold 7 through a second ply 12b of tubes 12 of the bundle 6. The first ply 12a and the second ply 12b are superimposed according to the direction of flow of the flow of FA air through the heat exchanger 5.

Such a configuration of the heat exchanger 5 makes it particularly useful to obtain a homogeneous distribution of the FR refrigerant fluid between its liquid phase and its gas phase and a homogeneous distribution of the FR refrigerant fluid along the manifold 7 towards each of the tubes 12 of the first ply 12a of the bundle 6. The example described of the architecture of the heat exchanger 5 and of the modes of circulation of the refrigerant fluid FR between the manifold 7 and the return box 8, are given as indicative and are not restrictive as to the scope of the invention.

In FIG. 1 and FIG. 2, the chamber 9 houses a mixing device 18 extending in a longitudinal direction D2 parallel to the longitudinal direction DI of extension of the manifold 7. The mixing device 18 comprises a conduit 14 extending along a longitudinal axis A1 between a first end 15 and a second end 16 of the mixing device 18. The duct 14 is in particular intended to provide a homogenization of the refrigerant fluid FR between its liquid phase and its gaseous phase during its evacuation outside the conduit 14. The longitudinal axis A1 of the conduit 14 is oriented parallel to the direction DI of extension of the manifold 7 and defines the longitudinal direction D2 of extension of the mixing device 18. The mixing device 18 is potentially centered inside the manifold 7 as illustrated in FIG. 1. Alternatively, the mixing device 18 can be offset eccentrically eur of the manifold 7 with respect to a median longitudinal axis A2 of extension of the manifold 7.

The mixing device 18 includes an inlet mouth 10 for its supply of refrigerant fluid FR. In the example illustrated in FIG. 1 and FIG. 2, the inlet mouth 10 is formed at a first longitudinal end of the duct 14. The inlet mouth 10 is capable of receiving the refrigerant fluid FR from outside the mixing device 18 either directly or via a junction member of the heat exchanger 5 with the fluid circuit 1 illustrated in FIG. 1. The second end of the conduit 14 is closed.

At least one orifice 17 is formed through the conduit 14 for the evacuation of the refrigerant fluid FR from the conduit 14 towards the chamber 9. The conduit 14 preferably comprises a plurality of orifices 17 formed over at least part of its length to promote the homogenization of the refrigerating fluid FR discharged along the conduit 14 between its liquid phase and its gaseous phase.

With reference also to FIG. 1 and to FIG. 2, the mixing device 18 illustrated for example in FIGS. 3 to 9 is arranged to be housed inside a chamber 9 of a manifold 7 which includes a heat exchanger 5, as illustrated for example in FIG. 10. The mixing devices 18 comprise the conduit 14 provided with the orifices 17 which are formed through the wall 14a of the conduit 14 while being aligned along a straight line L1 oriented parallel to the longitudinal axis Al of the duct 14.

As illustrated in FIG. 3, the duct 14 has the inlet mouth 10 at its first longitudinal end 15 and is closed at its second longitudinal end 16. The duct 14 is for example closed by a tip 16a which is brazed on the conduit 14 at its second longitudinal end 16. The conduit 14 can optionally also be equipped with an angular and / or axial positioning device 15a of the conduit inside the manifold 7. In FIGS. 4 and 6, the conduit 14 is for example still closed by a cover 16b which is formed and / or brazed on the conduit 14 at its second longitudinal end 16. The orifices 17 extend along a straight line L1, advantageously parallel with the longitudinal axis of duct 14.

In FIGS. 4 to 10, the duct 14 houses a mixing means 19 disposed inside its recess 14b, the latter being delimited by the wall 14a of the duct 14. The mixing means 19 comprises several mixing members 19a or 19b which are integrated into the internal face 14c of the conduit 14.

In FIGS. 4 to 7 for example, the mixing members 19a are integrated by brazing into the internal face 14c of the wall 14a. In FIGS. 8 and 9 for example, the mixing members 19b are integrated into the internal face 14c of the wall 14a by machining the duct 14 or by forming the mixing members 19b during a molding of the duct 14. Thus, the conduit 14 and the mixing members 19a or 19b form a unitary assembly or in other words a monobloc assembly forming the mixing device 18.

The mixing members 19a or 19b extend partially inside the duct 14 at least in a transverse direction DT to its longitudinal axis A1. The dimension DTI of the transverse extension pours mixing members 19a or 19b towards the inside the duct 14, or in other words perpendicularly in the direction of its longitudinal axis A1, is for information between 30% and 90% of the largest transverse dimension DT2 of the recess 14b of the duct 14.

In a longitudinal plane PL, the mixing members 19a or 19b form obstacles opposing a laminar flow of the refrigerant fluid FR inside the duct 14. The obstacles are formed at least partially upstream of an orifice 17 in the direction SI of circulation of the refrigerant fluid FR inside the duct 14 from the inlet mouth 10 towards the orifices 17.

The mixing members 19a or 19b thus disturb the laminar flow of the refrigerant fluid FR which promotes its mixing between a gas phase and a liquid phase inside the duct 14. In addition, the flow of the refrigerant fluid FR is broken against the obstacles formed by the mixing members 19a or 19b, with the effect of promoting the forced passage of the refrigerant fluid FR towards the orifices 17 and thus again improving its mixture between its gaseous phase and its liquid phase during its spraying through the holes 17.

A central zone Za of the conduit 14 is delimited locally along the longitudinal axis Al of the conduit 14 by the mixing members 19a or 19b, extending perpendicularly between the longitudinal axis Al of the conduit 14 and the mixing members 19a or 19b . A passage for the refrigerating fluid FR is thus formed along the duct 14 from its first longitudinal end 15 which is provided with the inlet mouth 10 towards its second longitudinal end 16 which is closed.

The FR refrigerant is evacuated from the conduit 14 by fractions of FR refrigerant, the amounts of which are dependent on the disturbances generated by the mixing members 19a or 19b opposing the flow of the FR refrigerant towards the second longitudinal end 16 of the conduit 14. It is remarkable that the thickness of the wall 14a of the conduit 14 varies along the conduit 14 due to the integration into its wall 14a of the mixing members 19a or 19b. More particularly in a longitudinal plane PL, the thickness Epi of the duct in its areas free of mixing members 19a or 19b is less than its thickness Ep2 in the areas of the duct 14 comprising the mixing members 19a or 19b. In other words and as visible in FIG. 4, the thickness Epi, Ep2 of the wall 14a of the conduit 14 varies in perpendicular planes PP distant from each other along the longitudinal axis Al of the conduit 14, depending on the presence or not of the mixing members 19a or 19b in the perpendicular planes PP considered.

More particularly in FIGS. 4 to 7, the mixing members 19a are formed by rings 20a which are oriented in their plane perpendicular to the longitudinal axis Al of the duct 14. According to a variant, the rings 20a can also be inclined in the longitudinal plane PL with respect to the longitudinal axis Al of the conduit 14 to form ramps forcing the refrigerant fluid FR to go towards the internal face 14c of the wall 14a of the conduit 14 and more particularly towards the orifices 17. The opening 21 rings 20a delimits the central zone Za of the duct 14 forming a passage allowing the refrigerant fluid FR to flow towards the second longitudinal end 16 of the duct 14.

The rings 20a are distributed along the duct 14, being arranged at a first distance Lgl from one another along the longitudinal axis Al of the duct 14. In the examples illustrated, the rings 20a are arranged at an equal distance Lgl from each other and each ring 20a is interposed between two orifices 17. The orifices 17 are aligned along the straight line L1 while being distant from each other by a second distance Lg2 equal to the first distance Lgl of separation of the rings 20a from each other .

In FIGS. 4 and 5, the openings 21 of the rings 20a are of identical sections in the plane of the rings 20a or in other words in a plane perpendicular PP to the longitudinal axis Al of the duct 14.

In FIGS. 6 and 7, the openings 21 of the rings 20a are of different sections in the plane of the rings 20a. More particularly, the sections of the openings 21 of the rings 20a vary along the longitudinal axis Al of the duct 14, gradually decreasing from the first longitudinal end 15 of the duct 14 towards its second longitudinal end 16 of the duct 14 in its part comprising the rings 20a .

In the example illustrated, the variation in the section of the openings 21 rings 20a is regular. In the plane of the rings 20a, the variation in the section of the openings 21 of the rings 20a is defined by a cone C1 which delimits the openings 21 of each of the rings 20a and the top of which is oriented towards the second longitudinal end 16 of the conduit 14. The angle B1 of the cone C1 can be adapted according to the length dimension of the conduit 14, at least in its part comprising the orifices 17 and / or the mixing members 19a. As an indication, the angle B1 of the cone C1 is between 3 ° and 6 ° for a length of the part of the conduit 14 comprising the orifices 17 between 200 mm and 300 mm and / or for a number of orifices 17 included between 15 and 30.

In FIGS. 8 and 9, the mixing members 19b are inclined at least in a longitudinal plane PL extending along the longitudinal axis Al of the duct 14. More particularly, the mixing members 19b are formed by threads 20b arranged in propellers of the same pitch wound around the longitudinal axis A1 of the conduit 14. The threads 20b extend along the conduit 14 according to a helical curve defined by a combination between a perpendicular direction and a longitudinal direction relative to the longitudinal axis Al of the conduit 14. In a plane perpendicular PP to the longitudinal axis Al of the conduit 14, the threads 20b are angularly distributed around the longitudinal axis Al of the conduit 14.

The mixing members 19b thus each form a ramp 19c for guiding the refrigerant fluid LR towards the internal face 14c of the conduit 14. The ramps 19c progressively direct the refrigerant fluid LR towards at least part of the orifices 17 from the central zone Za of the conduit 14.

More specifically in a plane perpendicular PP to the longitudinal axis Al of the conduit 14, the ramps 19c gradually direct the refrigerant fluid FR towards each of the orifices 17a located immediately downstream of the mixing members 20b in the direction SI of circulation of the refrigerant fluid FR inside the duct 14 from the inlet mouth 10 towards the orifices 17.

According to the embodiment illustrated in FIG. 9 and in the longitudinal plane PL passing through the orifices 17, the threads 20b are arranged at a first distance Lgl from one another and the orifices 17 are arranged at a second distance Lg2 from each other others along the longitudinal axis Al of the conduit 14. More particularly in a longitudinal plane PL passing through the orifices 17 and along the longitudinal axis Al of the conduit 14, the threads 20b are arranged equidistant from each other and the orifices 17 are arranged equidistant from each other.

The second distance Lg2 is of the order of half the first distance Lgl and each thread 20b is interposed between two first holes 17a separated from each other by a second hole 17b passing through a thread 20b. In other words, in a longitudinal plane PL crossing the orifices 17 and along the longitudinal axis Al of the conduit 14, the threads 20b are equidistant from the first orifices 17a situated immediately downstream of the threads 20b, and the threads 20b are crossed by second orifices 17b interposed equidistant between two successive first orifices 17a.

The orifices 17 thus have transverse extensions Epi, Ep2 which are different between two successive orifices 17a, 17b along the longitudinal axis Al of the conduit 14. Holes 17b extend through the wall 14a of the conduit 14 through a member of mixing 19b, and have a transverse extension Ep2 greater than that Epi of other orifices 17a which pass through an area of the wall 14a of the conduit 14 which is free of mixing member 19b.

In FIG. 10, a heat exchanger 5 is equipped with a mixing device 18 housed inside a manifold 7 which includes the heat exchanger 5. The mixing device 18 is installed inside a chamber 9 delimited by a wall 7a of the manifold 7 for supplying refrigerant fluid FR to tubes 12 of a bundle 6 of tubes 12 which open onto chamber 9 while being aligned in the longitudinal direction D2 of extension of the device mixing 18.

According to the exemplary embodiment illustrated, the chamber 9 is delimited by eyelets 23 successively abutted and fixed to each other, in particular by brazing, in the longitudinal direction D2 of extension of the dispensing device 18. The eyelets thus form the wall 7a of the manifold delimiting the chamber 9. The eyelets 23 have flanges 25 which are traversed by the distribution device 18 at a transverse distance relative to the longitudinal axis Al of the conduit 14.

The eyelets 23 are formed at the end of plates 26 forming between them the tubes 12 of the bundle 6. The outlets 24 of the tubes 12 of the bundle 6 are thus formed by openings made through the wall 7a of the manifold 7 delimiting the chamber 9, the outlets 24 of the tubes 12 of the bundle 6 being more specifically formed through the eyelets 23. The outlets 24 of the tubes 12 of the bundle 6 are configured in a funnel to increase the velocity of the refrigerant fluid FR evacuated from the chamber 9 towards the tubes 12 of the bundle 6.

A space E1 for circulation of the refrigerant fluid FR around the first conduit 14 is thus formed inside the chamber 9 between the wall 7a of the manifold and the mixing device 18. The orifices 17 are oriented diametrically opposite outlets 24 of the tubes 12 of the bundle 6 with respect to the first longitudinal axis Al of the first conduit 14. The refrigerant fluid FR sprayed by the mixing device 18 is admitted inside the chamber 9, then circulates inside the space El around the conduit 14 towards the outlets 24 of the tubes 12 of the bundle 6 for their supply of refrigerant fluid FR.

The foregoing description clearly explains how the invention makes it possible to achieve the objectives which it has set for itself, and in particular to propose a mixing device which homogenizes the distribution of the refrigerant fluid along the manifold box to guarantee an almost identical refrigerant in each tube of the bundle that includes the heat exchanger. In addition, the structural organization of the mixing device gives it easy adaptability which can be achieved at lower cost depending on the arrangement of a specific heat exchanger, in particular with regard to the number of tubes in the bundle that it comprises.

Of course, various modifications can be made by a person skilled in the art to the mixing device according to the invention, in particular as regards the methods of integration of the mixing device in the manifold. The mixing device which has just been described by way of nonlimiting example and its use will be made up as soon as the mixing device will comprise a conduit whose internal face is configured as a means of mixing the refrigerant between a liquid phase and a gas phase, the mixing means comprising at least one mixing member formed on the internal face of the duct.

In any event, the invention cannot be limited to the embodiments specifically described in this document, and extends in particular to all equivalent means and to any technically effective combination of these means.

Claims (16)

1. Mixing device (18) intended for mixing a gaseous phase with a liquid phase of a refrigerant fluid (FR) and configured to be housed inside a manifold box (7) of a heat exchanger (5 ), the mixing device (18) comprising a duct (14) with a longitudinal axis (Al) provided with an inlet mouth (10) for the admission of the coolant (FR) into the duct (14) and at least one orifice (17) for spraying the coolant (FR) out of the conduit (14), characterized in that the conduit (14) comprises at least one mixing member (19a, 19b) formed on one side internal (14c) of the duct (14) and capable of modifying the flow of the refrigerant fluid (FR) circulating inside the duct (14). 2. Mixing device (18) according to claim 1, in which the mixing member (19a, 19b) extends inside the duct (14) at least transversely to its longitudinal axis (Al) and partially at the interior of the recess (14b) of the duct (14) delimited by its wall (14a), forming an obstacle opposing a laminar flow of the coolant (FR) inside the duct (14). 3. Mixing device (18) according to any one of the preceding claims, in which the mixing member (19a, 19b) is incorporated into the wall (14a) of the duct (14). 4. Mixing device (18) according to any one of the preceding claims, in which the thickness (Epi, Ep2) of the wall (14a) of the duct (14) varies in planes perpendicular (PP) to the axis longitudinal (A1) of the duct (14) and longitudinally spaced from each other, the thickness (Ep2) of the wall (14a) of the duct (14) being increased by at least one mixing member (19a, 19b). 5. Mixing device (18) according to any one of the preceding claims, in which at least one mixing member (19a, 19b) extends perpendicular to the longitudinal axis (Al) of the conduit (14). 6. Mixing device (18) according to any one of the preceding claims, in which at least one mixing member (19a, 19b) is inclined at least in a longitudinal plane (PL) relative to the longitudinal axis (Al ) of the duct (14) by forming a ramp (19c) for guiding the coolant (FR) towards the orifice (17). 7. Mixing device (18) according to any one of the preceding claims, in which several orifices (17) are distributed along the duct (14) along its longitudinal axis (Al). 8. Mixing device (18) according to claim 7, in which the orifices (17) are distributed along a straight line (L1) parallel to the longitudinal axis (Al) of the conduit (14). 9. Mixing device (18) according to any one of the preceding claims, in which in a longitudinal plane (PL) passing through at least one orifice (17), at least one mixing member (19a, 19b) is arranged upstream at least one orifice (17) in a direction (SI) of flow of the coolant (FR) inside the conduit defined from the inlet mouth (10) towards the orifice (17). 10. Mixing device (18) according to any one of the preceding claims, in which in a longitudinal plane (PL) passing through at least one orifice (17), at least one mixing member (19a, 19b) is interposed between the minus two orifices along the longitudinal axis of the conduit. 11. Mixing device (18) according to any one of the preceding claims, in which in a longitudinal plane (PL) passing through at least one orifice (17), several mixing members (19a, 19b) are distributed along the axis longitudinal (Al) of the conduit (14). 12. Mixing device (18) according to claim 11, in which in a longitudinal plane (PL) passing through at least one orifice (17), the mixing members (19a, 19b) are arranged at a first distance (Lgl) from separation between two adjacent mixing members (19a, 19b) which is equal to a second distance (Lg2) of separation between two adjacent orifices (17). 13. Mixing device (18) according to any one of claims 11 or 12, in which in a longitudinal plane (PL) passing through at least one orifice (17), the mixing members (19a, 19b) are arranged at a first separation distance (Lgl) between two adjacent mixing members (19a, 19b) which is greater than a second separation distance (Lg2) between two adjacent orifices (17). 14. Mixing device (18) according to any one of the preceding claims, in which the mixing member (19a) is shaped as a ring (20a), the opening (21) of which passes through a passage for the fluid. refrigerant (FR). 15. Mixing device (18) according to claim 14, wherein the dimension of the opening (21) of the ring (20a) is between 10% and 70% of the largest dimension (DT2) of the recess (14b) of the conduit (14), measured in a plane perpendicular (PP) to the longitudinal axis (Al) of the conduit (14). 16. Heat exchanger (5) comprising a manifold (7) providing a chamber (9) which houses a mixing device (18) according to any one of claims 1 to 15, and comprising tubes (12) of a bundle (6) of tubes (12) opening onto the chamber (9) for their supply of coolant (FR) by the mixing device (18).