FR3092523A1 - Thermal management device of a motor vehicle with constant pressure valve - Google Patents

Abstract

The present invention relates to a thermal management device (1) of a motor vehicle, said thermal management device (1) comprising a refrigerant circuit in which a refrigerant fluid is intended to circulate, said refrigerant circuit comprising an evaporator (9) intended to be crossed by an internal air flow (100) and a constant pressure valve (15) disposed downstream of said evaporator (9), the refrigerant circuit comprising a bypass pipe (B) of the constant pressure valve (15), said first bypass line (B) comprising a shut-off valve (51). Figure for the abstract: Fig. 1

Description

Motor vehicle thermal management device with constant pressure valve

The invention relates to the field of thermal management devices for a motor vehicle and more particularly to a thermal management device configured to manage the comfort of the occupants in the passenger compartment.

In the automobile field, it is known to manage the comfort of the occupants by means of an air conditioning circuit inside which a refrigerant fluid circulates. This air conditioning circuit thus comprises a heat exchanger, also called an evaporator, arranged in an internal air flow intended for the passenger compartment in order to cool the latter. It is also known to have a constant pressure valve downstream of the evaporator in the air conditioning circuit. This constant pressure valve makes it possible to maintain a minimum pressure of the refrigerant fluid passing through the evaporator. This makes it possible to limit the temperature of the refrigerant fluid at the outlet of the evaporator and thus reduces the risk of causing the evaporator to ice up and of damaging the compressor of the air conditioning circuit.
However, the fact of limiting the temperature of the refrigerant fluid at the outlet of the evaporator also limits the cooling power available and therefore limits the cooling capacity of the air conditioning circuit at the level of the evaporator.

One of the aims of the present invention is to remedy at least partially the drawbacks of the prior art and to propose an improved thermal management device allowing greater cooling power at the level of the evaporator.

The present invention therefore relates to a thermal management device of a motor vehicle, said thermal management device comprising a refrigerant circuit in which a refrigerant fluid is intended to circulate, said refrigerant fluid circuit comprising an evaporator intended to be traversed by an internal air flow and a constant pressure valve arranged downstream of said evaporator,
the refrigerant circuit comprising a bypass pipe of the constant pressure valve, said first bypass pipe comprising a shut-off valve.

According to one aspect of the invention, the constant pressure valve and the shut-off valve are grouped together within a common block.

According to another aspect of the invention, the constant pressure valve has a diameter greater than or equal to 10 mm.

According to another aspect of the invention, the thermal management device is configured according to a first mode of operation in which the refrigerant fluid at the outlet of the evaporator circulates only in the valve at constant pressure.

According to another aspect of the invention, the thermal management device being configured according to a second operating mode in which the refrigerant fluid leaving the evaporator circulates both in the constant pressure valve and in the bypass line.

According to another aspect of the invention, the thermal management device comprises an air conditioning circuit.

According to another aspect of the invention, the thermal management device comprises a reversible air conditioning circuit.

According to another aspect of the invention, the reversible air conditioning circuit is direct.

According to another aspect of the invention, the reversible air conditioning circuit is indirect.

shows a schematic representation of a thermal management device according to a first embodiment,

shows a schematic representation of a thermal management device according to a second embodiment,

shows a schematic representation of a thermal management device according to a third embodiment.

In the various 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 is to the same embodiment, or that the features apply only to a single embodiment. Simple features of different embodiments may also be combined and/or interchanged to provide other embodiments.

In the present description, it is possible to index certain elements or parameters, 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 with respect to another and one can easily interchange such denominations without departing from the scope of the present description. This indexing does not imply an order in time either, for example to assess such and such a 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, “placed downstream” means that one element is placed after another in relation to the direction of flow of the fluid.

Figure 1 shows a representation of a thermal management device 1. The thermal management device 1 illustrated in Figure 1 is the simplest possible device and includes the elements necessary for operation as part of an air conditioning circuit in order to to cool an internal air flow 100 destined for the passenger compartment. The thermal management device 1 thus comprises a refrigerant fluid circuit comprising a main loop A in which a refrigerant fluid is able to circulate. This main loop A comprises, in the direction of circulation of the refrigerant fluid:
- a compressor 3,
- a first heat exchanger 5, here an external condenser intended to be crossed by an external air flow 200,
- a first expansion device 7, and
- an evaporator 9, here an internal evaporator intended to be crossed by the internal air flow 100.

By internal airflow 100 is meant an airflow passing through a heat exchanger (here the evaporator 9) arranged within a heating, ventilation and/or air conditioning device (not shown) and intended for the passenger compartment of the motor vehicle. In order to create the interior air flow 100, the heating, ventilation and/or air conditioning device may in particular comprise a fan (not shown). By external air flow 200 is meant an air flow external to the motor vehicle passing through the first heat exchanger 5, in particular disposed on the front face of the motor vehicle.

The main loop A can also include a phase separation device 50, such as for example a desiccant accumulator, arranged upstream of the compressor 3, between the evaporator 9 and said compressor 3.

The main loop A also comprises, downstream of the evaporator 9, a constant pressure valve 15. More precisely, this constant pressure valve 15 is arranged on the main loop A between the evaporator 9 and the compressor 3.
This constant pressure valve 15 regulates the pressure of the refrigerant fluid to a value greater than or equal to a predetermined pressure. This constant pressure valve 15 thus makes it possible to maintain a minimum pressure according to its setting within the evaporator 9.
Controlling the pressure of the refrigerant fluid at the level of a heat exchanger makes it possible to control the evaporation temperature of the refrigerant fluid at the level of this heat exchanger. The higher this pressure, the higher the evaporation temperature of the refrigerant fluid and the less heat energy it will be able to recover. Thus, if the pressure of the refrigerant fluid has a minimum, this makes it possible to limit the temperature of the refrigerant fluid at the outlet of the evaporator 9 and therefore, for example, to protect said evaporator 9 by avoiding icing of the latter due to a temperature too low refrigerant.

The refrigerant circuit further comprises a bypass line B of the constant pressure valve 15. This bypass line B includes a stop valve 51. More specifically, the bypass line B connects a first connection point 31 to a second connection point 32. The first connection point 31 is disposed downstream of the evaporator 9, between said evaporator 9 and the constant pressure valve 15. The second connection point 33 is in turn disposed downstream of the constant pressure valve 15, between said constant pressure valve 15 and compressor 3.
The stop valve 51 of the bypass line B must allow the passage of the refrigerant fluid in said bypass line B with much lower pressure drops than passing through the constant pressure valve 15. Thus, the valve d stop 15 may in particular have a diameter greater than or equal to 10mm.
The use of the bypass line B, in particular in the second mode of operation described later in this description, makes it possible to substantially increase the cooling power produced by the thermal management device 1 and available at the level of the evaporator 9.
In order to limit the space of the thermal management device 1 within the vehicle and also in order to facilitate assembly, it is quite possible to imagine that the constant pressure valve 15 and the shut-off valve 51 are grouped together in a common block.

As illustrated in Figures 2 and 3, the thermal management device 1 may comprise an invertible air conditioning circuit, that is to say that it is configured to operate according to different operating modes such as a cooling mode in order to cool the internal airflow 100 or a heat pump mode in order to heat the internal airflow 100.

Figure 2 shows an example of a direct reversible air conditioning circuit. This direct reversible air conditioning circuit is a derivative of the air conditioning circuit of FIG. 1. It therefore uses the same elements and components. The first heat exchanger 5 is here no longer a simple external condenser as illustrated in the example of FIG. 1 but an external evaporator/condenser. The direct reversible air conditioning circuit also comprises a second heat exchanger 23 which is here arranged in the heating, ventilation and/or air conditioning device so as to be crossed by the internal air flow 100. Within the heating device, ventilation and/or air conditioning, this second heat exchanger 23 is more precisely placed downstream of the evaporator 9 in the direction of circulation of the internal air flow 100. Within the main loop A, this second heat exchanger 23 is arranged downstream of the compressor 3, between said compressor 3 and the first heat exchanger 5. This second heat exchanger 23 here plays the role of an internal condenser in order to heat in particular the internal air flow 100.
The direct reversible air conditioning circuit also comprises a second expansion device 25 arranged upstream of the first heat exchanger 5, between the second heat exchanger 23 and said first heat exchanger 5. This second expansion device 25 can in particular open completely so as to allow the refrigerant to pass through without loss of pressure. An alternative solution (not shown) is that this second expansion device 25 can be bypassed.
The direct reversible air conditioning circuit further comprises a bypass branch C of the first expansion device 7 and of the evaporator 9. This bypass branch C connects a third connection point 33 to a fourth connection point 34. The third point connection 33 is arranged upstream of the first expansion device 7, between the first heat exchanger 5 and said first expansion device 7. The fourth connection point 34 is arranged downstream of the constant pressure valve 15, between said constant pressure valve 15, more precisely downstream of the second connection point 32 of the bypass line C, and the compressor 3.
This bypass branch C comprises a means of redirecting the refrigerant fluid, such as a shut-off valve 52, for example.

Figure 3 shows an example of an indirect reversible air conditioning circuit. This indirect reversible air conditioning circuit is identical to that of the thermal management device 1 of FIG. 2 except that the second heat exchanger 23 is not an internal condenser intended to be crossed by the internal air flow 100 but a two-fluid heat exchanger configured to exchange with a heat transfer fluid circulating within a secondary loop F. This secondary loop F comprises a pump 28 and a third heat exchanger 27. This third heat exchanger 27 plays the role of a internal condenser and is arranged in the heating, ventilation and/or air conditioning device so as to be crossed by the internal air flow 100. Within the heating, ventilation and/or air conditioning device, this third heat exchanger 27 is more precisely disposed downstream of the evaporator 9 in the direction of circulation of the internal air flow 100.

These thermal management devices illustrated in Figures 1 to 3 are examples and other more complex or simpler architectures can also be considered without departing from the scope of the invention.

The thermal management device 1 can thus be configured according to a first mode of operation in which the refrigerant fluid leaving the evaporator 9 circulates only in the constant pressure valve 15. The stop valve 51 of the bypass line B is configured so as to prevent the refrigerant fluid from passing through said bypass pipe B. Thus, the shut-off valve 51 is closed.
This first mode of operation is particularly useful so that the pressure of the refrigerant fluid within the evaporator does not fall below a pressure limit determined by the adjustment of the constant pressure valve 15. This thus makes it possible to avoid the risk of icing at the evaporator 9.

The thermal management device 1 can also be configured according to a second mode of operation in which the refrigerant fluid leaving the evaporator 9 circulates both in the constant pressure valve 15 and in the bypass pipe B. For this, the shut-off valve 51 is open so as to allow the refrigerant fluid to pass through said bypass line B.
This second mode of operation is particularly useful, for example, when a high cooling power is necessary at the level of the evaporator 9 to cool the internal air flow 100. Because the refrigerant fluid passes through the first bypass pipe C, the pressure drops are much lower and the pressure of the refrigerant fluid within the evaporator 9 is lower than for the first mode of operation. The cooling power of the internal air flow 100 via the evaporator 9 is therefore greater and makes it possible to cool it more strongly.
In this second mode of operation, the major part of the refrigerant fluid passes through the bypass pipe B because the pressure drops are less significant in this bypass pipe B. A small part of the refrigerant fluid nevertheless also passes through the valve at constant pressure 15.

Thus, it is clearly seen that the thermal management device 1 according to the invention makes it possible, by the presence of the bypass pipe B and of the shut-off valve 51, to temporarily increase the cooling power at the level of the evaporator 9 by bypassing the constant pressure valve 15 and allowing a lower pressure of the refrigerant fluid within said evaporator 9.

Claims (9)

Thermal management device (1) of a motor vehicle, said thermal management device (1) comprising a refrigerant fluid circuit comprising a main loop A in which a refrigerant fluid is intended to circulate, the main loop A comprising, in the direction of circulation of the refrigerant fluid: a compressor (3), a first heat exchanger (5), a first expansion device (7), an evaporator (9) intended to be crossed by an internal air flow (100) and a constant pressure valve (15) disposed downstream of said evaporator (9),
characterized in that the refrigerant circuit comprises a bypass pipe (B) of the constant pressure valve (15), said first bypass pipe (B) comprising a shut-off valve (51),
the bypass line (B) connecting a first connection point (31) disposed downstream of the evaporator (9), between said evaporator (9) and the constant pressure valve (15), to a second connection point ( 32) disposed downstream of the constant pressure valve (15), between said constant pressure valve (15) and the compressor (3). Thermal management device (1) according to Claim 1, characterized in that the constant-pressure valve (15) and the shut-off valve (51) are grouped together within a common block. Thermal management device (1) according to any one of the preceding claims, characterized in that the constant pressure valve (15) has a diameter greater than or equal to 10 mm. Thermal management device (1) according to one of claims 1 to 3, said thermal management device being configured according to a first mode of operation in which the refrigerant fluid at the outlet of the evaporator (9) circulates only in the valve at constant pressure (15). Thermal management device (1) according to one of claims 1 to 3, said thermal management device being configured according to a second mode of operation in which the refrigerant fluid leaving the evaporator (9) circulates both in the constant pressure valve (15) and in the bypass line (B). Thermal management device (1) according to any one of Claims 1 to 5, characterized in that it comprises an air conditioning circuit. Thermal management device (1) according to any one of Claims 1 to 5, characterized in that it comprises a reversible air conditioning circuit. Thermal management device (1) according to Claim 7, characterized in that the reversible air conditioning circuit is direct. Thermal management device (1) according to Claim 7, characterized in that the reversible air conditioning circuit is indirect.