FR3135228A1 - Desiccant tank assembly within a thermal management circuit - Google Patents

Abstract

Assembly (1) for a drying tank (2) of refrigerant fluid for a thermal management circuit of a motor vehicle, said assembly (1) comprising a drying tank (2) and a connection and distribution block (3), the drying tank ( 2) extending along a longitudinal axis (L), said desiccant tank (2) comprising a first end (2a) closed and a second end (2b), opposite the first end (2a), comprising a d refrigerant fluid inlet (21) and a refrigerant fluid outlet (22), the connection and distribution block (3) comprising a first face (3a) for receiving the desiccant tank (2) on which said desiccant tank (2) ) is fixed, said first face (3a) comprising a first refrigerant fluid outlet (31) fluidly connected to the refrigerant fluid inlet (21) of the desiccant tank (2) and a first refrigerant fluid inlet (32) fluidly connected at the refrigerant fluid outlet (22) of the desiccant tank (2). Abstract Figure: Fig 2

Description

Desiccant tank assembly within a thermal management circuit

The present invention relates to an assembly for a desiccant tank within a thermal management circuit. More particularly, the invention relates to an assembly comprising a desiccant tank and a refrigerant fluid connection and distribution block intended to be integrated into a thermal management circuit for a motor vehicle, in particular for an electric and/or hybrid vehicle.

It is common to provide a thermal management circuit such as an inverter air conditioning circuit or a heat pump circuit, a desiccant bottle or tank in order to achieve phase separation of the refrigerant fluid. Such a desiccant tank is generally placed within the thermal management circuit upstream of the heat exchanger playing the role of evaporator in heat pump mode, for example an evapo-condenser of an invertible air conditioning circuit.

However, the desiccant tanks in the prior art are difficult to integrate into a compact structure due to their large volume. Installation, fixing and access can therefore be complicated within a compact thermal management circuit, particularly if it is necessary, for example, to carry out maintenance.

The aim of the present invention is therefore to at least partially remedy the drawbacks of the prior art and to propose an improved desiccant tank whose structure allows integration within a compact thermal management circuit and whose maintenance possibilities are improved.

The present invention therefore relates to an assembly for a refrigerant drying tank for a thermal management circuit of a motor vehicle, said assembly comprising a drying tank and a refrigerant connection and distribution block,
the desiccant tank extending along a longitudinal axis and being intended to receive refrigerant fluid, said desiccant tank comprising a first closed end and a second end, opposite the first end, comprising a refrigerant fluid inlet and a refrigerant outlet,
the connection and distribution block comprising a first receiving face of the desiccant tank on which said desiccant tank is fixed, said first face comprising a first refrigerant outlet fluidically connected to the refrigerant fluid inlet of the desiccant tank and a first inlet of refrigerant fluid fluidly connected to the refrigerant fluid outlet of the desiccant tank,
the connection and distribution block comprising, on one of its side faces, a second refrigerant fluid inlet connected to the first refrigerant fluid outlet of said block and a second refrigerant fluid outlet connected to the first refrigerant fluid inlet of said block.

According to one aspect of the invention, the second end of the desiccant tank further comprises at least one offset extending perpendicular to the longitudinal axis, said at least one offset comprising at least one means of fixing with the connection block and distribution.

According to another aspect of the invention, the fluid connection between the desiccant tank and the connection and distribution block is made by a male/female connection.

According to another aspect of the invention, the refrigerant fluid inlet of the desiccant tank comprises a male member of the fluidic connection and the first outlet of the connection and distribution block comprises a female member complementary to the fluidic connection.

According to another aspect of the invention, the refrigerant fluid inlet of the desiccant tank comprises a female member of the fluidic connection and the first outlet of the connection and distribution block comprises a male member complementary to the fluidic connection.

According to another aspect of the invention, the refrigerant fluid outlet from the desiccant tank comprises a male member of the fluidic connection and the first inlet of the connection and distribution block comprises a female member complementary to the fluidic connection.

According to another aspect of the invention, the refrigerant fluid outlet from the desiccant tank comprises a female member of the fluidic connection and the first inlet of the connection and distribution block comprises a male member complementary to the fluidic connection.

According to another aspect of the invention, the refrigerant fluid inlet and outlet of the desiccant tank as well as the first refrigerant fluid inlet and the first outlet of the connection and distribution block comprise a female member of the fluid connection, the set comprising:

• un deuxième organe male additionnel inséré conjointement dans la sortie de fluide réfrigérant du réservoir dessiccateur et la première entrée du bloc de connexion et de distribution.
• Selon un autre aspect de l’invention, le réservoir dessiccateur comporte en son sein un tube plongeur connecté à l’entrée de fluide réfrigérant dudit réservoir dessiccateur et s’étendant vers la première extrémité sur une longueur d’au moins 70% dudit réservoir dessiccateur.

a first additional male member inserted jointly into the refrigerant fluid inlet of the desiccant tank and the first outlet of the connection and distribution block,

• a second additional male member inserted jointly into the refrigerant fluid outlet of the desiccant tank and the first inlet of the connection and distribution block.
• According to another aspect of the invention, the desiccant tank comprises within it a dip tube connected to the refrigerant fluid inlet of said desiccant tank and extending towards the first end over a length of at least 70% of said desiccant tank .

According to another aspect of the invention, the desiccant tank comprises within it a dip tube connected to the refrigerant fluid outlet of said desiccant tank and extending towards the first end over a length of at least 70% of said desiccant tank.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description, provided by way of illustration and not limitation, and the appended drawings in which:

There shows a schematic perspective representation of an assembly for a desiccant tank,

there shows a schematic representation in exploded perspective and partial section of the desiccant tank assembly of the ,

there shows a schematic representation in perspective and in section of a connection and distribution block according to a first section plane,

there shows a schematic representation in perspective and in section of a connection and distribution block according to a second sectional plane,

there shows a schematic representation in exploded perspective and partial section of an assembly for a desiccant tank according to an alternative embodiment,

there shows an exploded and sectional schematic representation of an assembly for a desiccant tank according to a first embodiment,

there shows an exploded and sectional schematic representation of an assembly for a desiccant tank according to a second embodiment,

there shows an exploded and sectional schematic representation of an assembly for a desiccant tank according to a third embodiment,

there shows an exploded and sectional schematic representation of an assembly for a desiccant tank according to a fourth embodiment.

In the different figures, identical elements bear the same reference numbers.

The following achievements are examples. Although the description refers to one or more embodiments, this does not necessarily mean that each reference relates to the same embodiment, or that the features only apply to a single embodiment. Simple features of different embodiments may also be combined and/or interchanged to provide other embodiments.

In the present description, certain elements or parameters can be indexed, such as for example first element or second element as well as first parameter and second parameter or even first criterion and second criterion, etc. In this case, it is a simple indexing to differentiate and name elements or parameters or criteria that are close, but not identical. This indexing does not imply a priority of one element, parameter or criterion in relation to another and such denominations can easily be interchanged without departing from the scope of this description. This indexing does not imply an order in time either, for example to assess this or that criterion.

In the present description, “placed upstream” means that one element is placed before another with respect to the direction of circulation of a fluid. Conversely, by “placed downstream” we mean that one element is placed after another in relation to the direction of circulation of the fluid.

Figures 1 and 2 show an assembly 1 for a refrigerant drying tank 2 for a motor vehicle thermal management circuit. This assembly 1 can in particular be arranged within the thermal management circuit downstream of an internal condenser and upstream of an expansion valve, in the direction of circulation of a refrigerant fluid within the thermal management circuit in heat pump mode for example.

The assembly 1 more particularly comprises a desiccant tank 2 and a block 3 for connection and distribution of refrigerant fluid. The desiccant tank 2 is notably fixed on the connection and distribution block 3.

The desiccant tank 2 extends along a longitudinal axis L and is intended to receive refrigerant fluid. The desiccant tank 2 has a first closed end 2a and a second end 2b, opposite the first end 2a, comprising an inlet 21 of refrigerant fluid and an outlet 22 of refrigerant fluid, visible on the .

The connection and distribution block 3 comprises a first face 3a for receiving the desiccant tank 2 on which the desiccant tank 2 is fixed.

The first face 3a comprises a first refrigerant fluid outlet 31 fluidly connected to the refrigerant fluid inlet 21 of the desiccant tank 2 and a first refrigerant fluid inlet 32 fluidly connected to the refrigerant fluid outlet 22 of the desiccant tank 2.

The connection and distribution block 3 comprising, on one of its side faces 3b, a second refrigerant fluid inlet 33 connected to the first refrigerant fluid outlet 31 of said block 3 and a second refrigerant fluid outlet 34 connected to the first inlet 32 of refrigerant fluid of said block 3. By lateral face 3b, we mean more particularly a face of the connection and distribution block 3 contiguous to the first face and marks an angle with the latter, for example an angle substantially perpendicular to the first face 3a and parallel to the longitudinal axis L of the desiccant tank 2.

Such an assembly 1 allows in particular easy fixing of the desiccant tank 2 on the connection and distribution block 3 in particular for the manufacture of a compact thermal management circuit as well as for good access to the desiccant tank in the event of need for maintenance of this last. In addition, the use of a distribution and connection block 3 with a second inlet 33 and a second outlet 34 of refrigerant fluid on one of its side faces 3b allows simpler assembly and integration within a circuit thermal management system whose other elements, such as its pipes, valves, regulators or even elements such as the pump, are also integrated into hydraulic blocks for the sake of compactness of the thermal management circuit.

In the example illustrated in Figures 1 and 2, the same side face 3b carries the second inlet 33 and the second outlet 34 of refrigerant fluid. It is, however, entirely possible to imagine an embodiment in which the second inlet 33 and the second outlet 34 are arranged on different side faces 3b. The side face(s) 3c carrying the second inlet 33 and/or the second outlet 34 may also include fixing means 36 for fixing to another hydraulic block another element connecting to the second inlet 33 and/or at the second refrigerant fluid outlet 34 of the connection and distribution block 3.

In the example illustrated in Figures 1 and 2, the connection and distribution block 3 has a general parallelepiped shape comprising a first face 3a, a second face 3c, opposite the first face 3a, and lateral faces 3b connecting the first face 3a to the second face 3c, here four lateral faces. Other shapes of the connection and distribution block 3 can in particular be considered with more or fewer side faces for example.

As illustrated in Figures 1 and 2 as well as in the sectional views of Figures 3 and 4, the connection and distribution block 3 can be a hydraulic block. Block 3 can be a machined metal block, for example made of aluminum or aluminum alloy. The connection and distribution block 3 notably comprises within it a first pipe 36 between its first outlet 31 and its second inlet 33 as well as a second pipe 37 between its first inlet 32 and its second outlet 34.

Still according to Figures 1 and 2, the second end 2b of the desiccant tank 2 further comprises at least one offset 24 extending perpendicular to the longitudinal axis L. This at least one offset 24 can comprise at least one fixing means 25 with connection and distribution block 3. This fixing means 25 can for example be through orifices complementary to other orifices 35 provided on the first face 3a of the connection and distribution block 3. The orifices 35 of the block 3 can more particularly be tapped in order to receive fixing screws or bolts for fixing the desiccant tank 2.

In order to enable keying when fixing the desiccant tank 3 on the connection and distribution block 3, the fixing means 25 may in particular be of an odd number, for example three, or arranged irregularly around the desiccant tank 2 This thus makes it possible to connect the first refrigerant fluid outlet 31 of block 3 to the refrigerant fluid inlet 21 of the desiccant tank 2 and the first refrigerant fluid inlet 32 to the refrigerant fluid outlet 22 of the desiccant tank 2.

Another means of coding can also be to use different fluidic connection diameters between the desiccant tank 2 and the connection and distribution block 3, or even not to align these fluidic connections with the center of the desiccant tank 2.

As illustrated in Figures 2 and 5, the desiccant tank 2 may in particular comprise within it a dip tube 23 extending from its second end 2b towards its first end 2a, over a length of at least 70% of said desiccant tank 2 .

According to a first embodiment illustrated in , this dip tube 23 is connected to the refrigerant fluid inlet 21 of said desiccant tank 2. This thus makes it possible to connect the first end 2a of the desiccant tank 2 to the refrigerant fluid inlet 21 and thus to position the desiccant tank 2 with its first end 2a oriented upwards and its second end 2b, with the fluid connections, downwards. Here, up and down mean positioning relative to Earth's gravity. The outlet 22 is connected directly to the second end 2b and is thus positioned at the bottom, the latter due to gravity will only allow the evacuation of the refrigerant fluid in its liquid state.

This particular positioning with the second end 2b of the desiccant tank 2 can in particular allow assembly and improved maintenance of the desiccant tank 2, the latter being able to simply be placed on the block 3 before being fixed, without the need for means to keep it in place. place for example.

According to, a second embodiment illustrated in , the dip tube 23 is connected to the refrigerant fluid outlet 22 of said desiccant tank 2. This thus makes it possible to connect the first end 2a of the desiccant tank 2 to the refrigerant fluid outlet 22 and thus to position the desiccant tank 2 with its first end 2a oriented downwards and its second end 2b, with the fluidic connections, upwards. Due to gravity, outlet 22 will only allow the refrigerant to be evacuated in its liquid state. Input 21 is directly connected to the second end 2b and is positioned at the top

Figures 6 to 9 show different means of fluid connection between the desiccant tank 2 and the connection and distribution block 3. More particularly, the fluid connection between the desiccant tank 2 and the connection and distribution block 3 is made by a male/female connection.

According to a first embodiment illustrated in , the refrigerant fluid inlet 21 of the desiccant tank 2 comprises a male member of the fluidic connection and the first outlet 31 of the connection and distribution block 3 comprises a female member complementary to the fluidic connection. The refrigerant fluid outlet 22 of the desiccant tank 2 here also comprises a male member of the fluidic connection and the first inlet 32 of the connection and distribution block 3 comprises a female member complementary to the fluidic connection.

According to a second embodiment illustrated in , the opposite is also possible, that is to say that the refrigerant fluid inlet 21 of the desiccant tank 2 comprises a female member of the fluid connection and the first outlet 31 of the connection and distribution block 3 comprises a male organ complementary to the fluidic connection. The refrigerant fluid outlet 22 of the desiccant tank 2 here also comprises a female member of the fluidic connection and the first inlet 32 of the connection and distribution block 3 comprises a male member complementary to the fluidic connection.

According to a third embodiment illustrated in , an alternation is also possible. In this third embodiment, the refrigerant fluid inlet 21 of the desiccant tank 2 comprises a male member of the fluidic connection and the first outlet 31 of the connection and distribution block 3 comprises a female member complementary to the fluidic connection. The refrigerant fluid outlet 22 of the desiccant tank 2 comprises a female member of the fluidic connection and the first inlet 32 of the connection and distribution block 3 comprises a male member complementary to the fluidic connection.

A non-illustrated variant of this third embodiment is that the refrigerant fluid inlet 21 of the desiccant tank 2 comprises a female member of the fluid connection and the first outlet 31 of the connection and distribution block 3 comprises a complementary male member of the fluid connection. The refrigerant fluid outlet 22 of the desiccant tank 2 would comprise a male member of the fluidic connection and the first inlet 32 of the connection and distribution block 3 comprises a female member complementary to the fluidic connection.

This third embodiment as well as its variant makes it possible in particular to limit the risks of mounting the desiccant tank 2 upside down on the connection and distribution block 3.

According to a fourth embodiment illustrated in , the refrigerant fluid inlet 21 and outlet 22 of the desiccant tank 2 as well as the first refrigerant fluid inlet 32 and the first outlet 31 of the connection and distribution block 3 all four comprise a female member of the fluid connection. Set 1 further comprises:
- a first additional male member 41 inserted jointly into the refrigerant fluid inlet 21 of the desiccant tank 2 and the first outlet 31 of the connection and distribution block 3,
- a second additional male member 42 inserted jointly in the refrigerant fluid outlet 22 of the desiccant tank 2 and the first inlet 32 of the connection and distribution block 3.

The first 41 and the second 42 male member can also include a collar 411, 422 serving as a stop.

According to any embodiment of Figures 6 to 9, the fluid connections between the desiccant tank 2 and the connection and distribution block 3 may comprise at least one seal 50. Preferably, this seal 50 can be arranged around the male organ of the different fluidic connections.

Thus, we can clearly see that the assembly 1 for desiccant tank 2 allows easier installation and maintenance within a compact thermal management circuit due to the coupling between the desiccant tank 2 and the connection and distribution block 3 .

Claims (10)

Assembly (1) for a drying tank (2) of refrigerant fluid for a thermal management circuit of a motor vehicle, said assembly (1) comprising a drying tank (2) and a block (3) for connection and distribution of refrigerant fluid,
the desiccant tank (2) extending along a longitudinal axis (L) and being intended to receive refrigerant fluid, said desiccant tank (2) comprising a first closed end (2a) and a second end (2b), opposite the first end (2a), comprising a refrigerant fluid inlet (21) and a refrigerant fluid outlet (22),
the connection and distribution block (3) comprising a first face (3a) for receiving the desiccant tank (2) on which said desiccant tank (2) is fixed, said first face (3a) comprising a first outlet (31) of refrigerant fluid fluidly connected to the refrigerant fluid inlet (21) of the desiccant tank (2) and a first refrigerant fluid inlet (32) fluidly connected to the refrigerant fluid outlet (22) of the desiccant tank (2),
the connection and distribution block (3) comprising, on one of its side faces (3b), a second refrigerant fluid inlet (33) connected to the first refrigerant fluid outlet (31) of said block (3) and a second refrigerant fluid outlet (34) connected to the first refrigerant fluid inlet (32) of said block (3). Assembly (1) for a desiccant tank (2) according to claim 1, characterized in that the second end (2b) of the desiccant tank (2) further comprises at least one offset (24) extending perpendicular to the longitudinal axis (L), said at least one offset (24) comprising at least one fixing means (25) with the connection and distribution block (3). Assembly (1) for a desiccant tank (2) according to any one of the preceding claims, characterized in that the fluid connection between the desiccant tank (2) and the connection and distribution block (3) is made by a male connection /female. Assembly (1) for a desiccant tank (2) according to claim 3, characterized in that the refrigerant fluid inlet (21) of the desiccant tank (2) comprises a male member of the fluid connection and the first outlet (31) of the connection and distribution block (3) comprises a female member complementary to the fluid connection. Assembly (1) for a desiccant tank (2) according to claim 3, characterized in that the refrigerant fluid inlet (21) of the desiccant tank (2) comprises a female member of the fluid connection and the first outlet (31) of the connection and distribution block (3) comprises a male member complementary to the fluid connection. Assembly (1) for a desiccant tank (2) according to any one of claims 4 or 5, characterized in that the refrigerant fluid outlet (22) of the desiccant tank (2) comprises a male member of the fluidic connection and the first Inlet (32) of the connection and distribution block (3) comprises a female member complementary to the fluid connection. Assembly (1) for a desiccant tank (2) according to any one of claims 4 or 5, characterized in that the refrigerant fluid outlet (22) of the desiccant tank (2) comprises a female member of the fluid connection and the first Inlet (32) of the connection and distribution block (3) comprises a male member complementary to the fluidic connection. Assembly (1) for a desiccant tank (2) according to claim 3, characterized in that the inlet (21) and the outlet (22) of refrigerant fluid of the desiccant tank (2) as well as the first inlet (32) and the first outlet (31) of refrigerant fluid from the connection and distribution block (3) comprises a female member of the fluid connection, the assembly (1) comprising:

• a first additional male member (41) inserted jointly into the refrigerant fluid inlet (21) of the desiccant tank (2) and the first outlet (31) of the connection and distribution block (3),
• a second additional male member (42) inserted jointly in the refrigerant fluid outlet (22) of the desiccant tank (2) and the first inlet (32) of the connection and distribution block (3).

Assembly (1) for a desiccant tank (2) according to any one of claims 1 to 8, characterized in that the desiccant tank (2) comprises within it a dip tube (23) connected to the inlet (21) of refrigerant fluid from said desiccant tank (2) and extending towards the first end (2a) over a length of at least 70% of said desiccant tank (2). Assembly (1) for a desiccant tank (2) according to any one of claims 1 to 8, characterized in that the desiccant tank (2) comprises within it a dip tube (23') connected to the outlet (22) of refrigerant fluid from said desiccant tank (2) and extending towards the first end (2a) over a length of at least 70% of said desiccant tank (2).