EP3504075A1

EP3504075A1 - Thermal system, in particular a motor vehicle air conditioning system

Info

Publication number: EP3504075A1
Application number: EP17764427.5A
Authority: EP
Inventors: Samer Saab; François CHARBONNELLE; Philippe Jouanny
Original assignee: Valeo Systemes Thermiques SAS
Current assignee: Valeo Systemes Thermiques SAS
Priority date: 2016-08-26
Filing date: 2017-08-22
Publication date: 2019-07-03
Also published as: WO2018037186A1; FR3055251B1; FR3055251A1

Abstract

The invention relates to a motor vehicle thermal system (1), in particular an air-conditioning system, this system comprising: - a main thermal circuit (20) comprising a compressor (2) designed to compress a refrigerant circulating in this circuit and an evaporator (10) designed to cool an air flow that circulates in contact with the evaporator (10), this cooling being produced by thermal exchange between the flow of air to be cooled and of the refrigerant circulating in this evaporator (10), - a secondary thermal device (21) comprising a frigorie storage unit (22), a device (27) creating an expansion between the outlet of the evaporator (10) and the inlet of the frigorie storage unit (22), and a pump (23).

Description

THERMAL SYSTEM, IN PARTICULAR A SYSTEM OF

AIR CONDITIONING OF A MOTOR VEHICLE

The invention relates to a thermal system for a motor vehicle, in particular an air-conditioning system for a motor vehicle.

At present, ventilating, heating and / or air-conditioning apparatus for a passenger compartment of a motor vehicle generally comprise a closed thermodynamic loop comprising at least, according to the direction of circulation of a cooling fluid, an evaporator on the air, a compressor, a condenser and a valve or expansion device. In this configuration, the air is cooled by passing on the evaporator before being expelled to the passenger compartment by pipes.

These ventilation units operate thanks to the drive of the air-conditioning compressor by the internal combustion engine, the output of which varies greatly according to its speed and its load (low idle efficiency, good acceleration efficiency and no consumption deceleration). ); thus for a given load to the air conditioning compressor, the motor vehicle will overconsumption more or less fuel

Also, when the vehicle stops, the ventilation devices are poor, or do not work at all.

In addition, in newer vehicles that are equipped with an engine management system called "Stop and Go", that is, stopping the internal combustion engine when the vehicle is at neutral, for example to a fire or a stop, then restart of it when the advance of the vehicle is again desired, thanks to an alternator starter, the engine can not drive the compressor when the engine is stopped. Air conditioning is frequently interrupted, which affects the overall comfort of passengers.

In general, there is a need to be able to manage the air conditioning by minimizing the fuel consumption of the vehicle. It is known from patent application US20100018231 a storage of frigories in an evaporator of the air conditioning system.

However storing the frigories in the evaporator of the ventilation apparatus (HVAC) implies the presence of phase change materials (PCM) which reduces its performance, increases its size accordingly and does not allow to control the desired moment for the restitution of the frigories.

In order to overcome these problems, other documents JP2000313226, US7228705, US20030159455 and WO2014012873 describe storing frigories in systems outside the HVAC. Among these external systems, there are so-called "parallel" systems such as JP2000313226, where a portion of refrigerant flow flowing towards the evaporator flows to a storage device, other systems called "in series" as in documents US7228705, US20030159455, WO2014012873 and JP2009229014 where the entire refrigerant flow can flow to a storage device at the outlet of the evaporator.

The best systems described in these documents are the systems that combine the serial architecture, for the reactivity in storage mode, the presence of a refrigerant pump for efficiency in the restitution mode, and the presence of a bypass or by-pass. pass for the insulation of the storage device in "normal" operating mode of the air conditioning loop.

However, in all these architectures, the pressure level prevailing in the storage devices is equivalent to that of the evaporator at its pressure drop, which is penalizing during the storage phase.

The subject of the invention is thus a thermal system for a motor vehicle, in particular an air-conditioning system for a motor vehicle, this system comprising:

a main thermal circuit comprising a compressor arranged to compress a refrigerant circulating in this circuit and an evaporator arranged to cool a flow of air flowing in contact with the evaporator, this cooling being obtained by heat exchange between the air flow to cool and refrigerant circulating in this evaporator,

a secondary thermal device comprising a frigory storage unit, a device creating a detent between the outlet of the evaporator and the inlet of the frigory storage unit, and a pump, this secondary device being arranged in a manner:

o to establish a pressure in the frigory storage unit at a level lower than the pressure in the evaporator when the system is in storage mode,

o to regulate the pressure difference between the frigory storage unit and the evaporator according to the conditions of use,

o to prevent the exchange of refrigerant between the storage unit and the main thermal circuit when the system is in normal mode,

o be connected, preferably in series, to the evaporator of the main thermal circuit when the compressor of the main thermal circuit is at a standstill or is operating at low speed so that refrigerant from the frigory storage unit is sent, using the pump, through the evaporator of the main thermal circuit.

Thanks to the invention, which is in particular to prevent the exchange of refrigerant between the secondary thermal device and the main thermal circuit during normal operation, this normal operation is not affected by an unwanted passage of refrigerant through the cold storage unit, which would have had the effect of reducing the performance of air conditioning. This also makes it possible not to degrade the performance of the storage unit because it is maintained at a pressure lower than that of the evaporator when it is filled with frigories.

The fact that the cold storage unit is in series with the evaporator makes it possible to take full advantage of the refrigerant flow during a phase of storage of frigories in this unit.

According to one aspect of the invention, the pump is arranged to be bypassed when the frigory storage unit receives frigories of the refrigerant which passes through it. The pump is then stopped.

According to one aspect of the invention, the secondary thermal device comprises at least a first bypass valve arranged to selectively prevent refrigerant circulation between the frigory storage unit and the main thermal circuit in normal mode.

According to one aspect of the invention, the secondary thermal device is arranged so that the flow direction of the refrigerant in the cold storage unit is reversed respectively: when this frigory storage unit receives frigories of the refrigerant which passes through it and

when this cold storage unit returns frigories to the refrigerant which passes through it.

According to one aspect of the invention, the first bypass valve is a 3-way valve arranged at a junction between the secondary thermal device and the main thermal circuit. This 3-way valve can be replaced by two 2-way valves, if desired. According to one aspect of the invention, the secondary thermal device comprises a second bypass valve, in particular a two-way valve, arranged to be traversed selectively by refrigerant which flows from the evaporator of the main thermal circuit to the storage unit of frigories to allow a relaxation that will transfer frigories of the refrigerant to the storage unit of frigories in storage mode.

According to one aspect of the invention, the secondary thermal device comprises a secondary branch on which is disposed this second bypass valve, this branch making fluid junction with a primary branch on which are arranged the cold storage unit and the pump.

According to one aspect of the invention, this junction between the primary branch and the secondary branch is disposed between the frigory storage unit and the pump. According to one aspect of the invention, the secondary thermal device comprises a non-return valve disposed on the primary branch downstream of the pump. This valve or non-return valve can be integrated in the pump. According to one aspect of the invention, the secondary thermal device is arranged so that:

- In operating mode of the main thermal circuit without use of the secondary thermal device, the cold storage unit is bypassed and the pump is stopped.

- In operating mode of the main thermal circuit with charging in frigories of the cold storage unit of the secondary thermal device by expansion through the expansion device, the cold storage unit is traversed by refrigerant and the pump is when stationary, the storage unit and the evaporator being preferably in series,

- In operating mode of the secondary thermal device to return frigories to the evaporator of the main thermal circuit, the compressor is stopped or runs at low speed, the refrigerant storage unit is traversed by refrigerant and the pump is running,

In so-called "cold boost" mode, namely in operating mode of the secondary thermal device to restore frigories to the evaporator of the main thermal circuit, whose compressor operates at low or high load, the cold storage unit is refrigerant and the pump is running.

According to one aspect of the invention, the secondary thermal device is arranged so that the flow direction of the refrigerant in the cold storage unit is the same respectively:

when this frigory storage unit receives frigories of the refrigerant which passes through it and

when this cold storage unit returns frigories to the refrigerant which passes through it. According to one aspect of the invention, a non-return valve is disposed at the outlet of the frigory storage unit.

According to one aspect of the invention, two bypass valves are provided. According to one aspect of the invention, one of the bypass valves is disposed at the entrance of the frigory storage unit, on a primary branch, and allows relaxation.

According to one aspect of the invention, the other of the bypass valves is arranged between the evaporator and the pump, on a secondary branch to allow the bypass, or bypass, of the cold storage unit in normal mode .

According to one aspect of the invention, the two bypass valves can be replaced by a 3-way valve.

According to one aspect of the invention, the conduit leading the refrigerant flow from the cold storage unit to the pump can be located downstream or upstream of the non-return valve thus allowing the refrigerant pump to be arranged. directly at the outlet of the frigory storage unit.

According to one aspect of the invention, the frigory storage unit is arranged to be at a lower pressure than the evaporator.

According to one aspect of the invention, the second bypass valve disposed between the evaporator and the frigory storage unit is arranged to generate two pressure levels respectively for the evaporator and the storage unit. According to one aspect of the invention, this second bypass valve may be a variable passage section valve, a single passage section valve or a three way valve. This valve can be an on / off valve that precedes a calibrated orifice. To maintain the comfort of passenger unchanged, the pressure must remain stable at the evaporator.

So depending on the conditions and to maximize storage without altering the comfort of passengers, it is possible to have to change the passage section of the valve then its pressure drop. In this way pressures and temperatures will be controlled.

According to one aspect of the invention, an expansion device, either thermostatic or electrical, is arranged upstream of the evaporator to generate an expansion of the refrigerant before it passes through the evaporator.

According to one aspect of the invention, the opening of this expansion device is controlled by overheating at the inlet of an internal heat exchanger or at the compressor inlet or at the outlet of the evaporator. According to one aspect of the invention, the cold storage unit is arranged inside an HVAC or outside an HVAC.

According to one aspect of the invention, the system comprises an air path disposed parallel to the evaporator, a path through which air can circulate bypassing the evaporator, and this air can, at the exit of this path, be mix with air from the evaporator. The passage section of this track is particularly controlled by a component. This flap is in particular in parallel with the evaporator.

Thus the position of the valve downstream of the evaporator can help to adjust the air temperature at the evaporator outlet by mixing the cold air from the evaporator and the warmer air coming from the track. aforementioned air. This is advantageous during the frigory storage phase. The valve may be for example a simple closing valve with a fixed diameter. The 2-way valve is, for example, arranged to generate a fixed pressure drop so as to protect the evaporator from the formation of ice. The valve protects the evaporator from icing, and the flap regulates the air temperature at the outlet of the evaporator.

The invention will be better understood and other details, characteristics and advantages of the invention will become apparent on reading the following description given by way of nonlimiting example with reference to the appended drawing in which:

FIG. 1 illustrates, schematically and partially, a first embodiment of the system according to the invention,

FIGS. 2 to 4 illustrate the system of FIG. 1 during different modes of operation,

FIG. 5 illustrates, schematically and partially, a second embodiment of the system according to the invention,

FIG. 6 schematically and partially illustrates a third embodiment of the system according to the invention,

FIG. 7 illustrates an operation of the system of FIG.

6

FIGS. 2a, 3a and 4a are Mollier diagrams corresponding to the operating phases of FIGS. 2, 3 and 4, respectively,

- Figures 4b, 5a-5c illustrate other embodiments of the invention.

FIG. 1 represents an air conditioning system 1 which comprises, according to the direction of closed-circuit circulation of a refrigerant such as R134A: a compressor 2, a condenser 3, a storage bottle 4, an internal heat exchanger 5, an expansion or expansion device 6 and an evaporator on the air 10. These components form a main thermal circuit 20.

The evaporator 10 is placed in an air circulation duct leading to different zones of the passenger compartment to be cooled or heated. such as an area for defogging the windshield, an aeration zone and a foot zone.

The compressor 2 is arranged to compress the refrigerant circulating in this circuit 20 and the evaporator 10 is arranged to cool a flow of air flowing in contact with the evaporator, this cooling being obtained by heat exchange between the air flow. to cool and refrigerant circulating in this evaporator.

The system 1 further comprises a secondary thermal device 21 comprising a frigory storage unit 22, an expansion or pressure loss device 27 and a pump 23, this secondary device being arranged in such a way as:

establishing a pressure in the storage unit 22 at a level below the pressure in the evaporator 10 when the system is in storage mode (see FIGS. 3 and 3a),

o to regulate the pressure difference between the storage unit 22 and the evaporator as a function of the conditions of use, o to prevent the exchange of refrigerant between the storage unit and the main thermal circuit 20 when the system is in normal mode, ie when the compressor 2 is running and the evaporator 10 cools the air flow (see Figures 2 and 2a). Thus the storage unit 22 can be maintained at a pressure lower than that of the evaporator when it is filled with frigories,

o to be connected in series to the evaporator 10 of the main thermal circuit 20 when the compressor 2 of the main thermal circuit is at a standstill (return mode) so that refrigerant from the frigory storage unit 22 is sent , using the pump 23, through the evaporator 10 of the main thermal circuit 20 or (storage mode) that refrigerant from the evaporator is sent to the storage unit of frigories 22 (see Figures 4 and 4a),

o to be in parallel with the compressor in "cold boost" mode as shown in Figure 4b.

Figures 2a, 3a and 4a are Mollier diagrams corresponding to the phases of operation of Figures 2, 3 and 4, respectively.

The secondary thermal device 21 comprises a first bypass valve 25 or 35 or 37, arranged to selectively prevent refrigerant circulation between the cold storage unit 22 and the main thermal circuit 20, in normal mode.

The secondary thermal device 21 is arranged so that:

- In operating mode of the main thermal circuit 20 without use of the secondary thermal device 21 (see Figure 2), the frigory storage unit 22 is bypassed and the pump 23 is stopped,

In the operating mode of the main thermal circuit 20 with charging in frigories of the cold storage unit 22 of the secondary thermal device 21 (see FIG. 3), the refrigerating storage unit 22 is traversed by refrigerant and the pump 23 is stopped,

- In the operating mode of the secondary thermal device 21 to return frigories to the evaporator of the main thermal circuit 20 (see Figure 4), the compressor 2 is stopped, the frigory storage unit 22 is traversed by refrigerant and the pump 23 is running, In so-called "cold boost" mode, namely in operating mode of the secondary thermal device to restore frigories to the evaporator of the main thermal circuit, whose compressor operates at low or high load, the cold storage unit is refrigerant and the pump is running (see Figure 4b).

In the frigory storage phase in the frigory storage unit 22 (FIG. 3), the pump 23 is arranged to be bypassed and is then stopped.

The secondary thermal device 21 is arranged so that the direction of circulation of the refrigerant in the frigory storage unit 22 is reversed respectively:

when this frigory storage unit 22 receives frigories of the refrigerant which passes through it (phase of storage of frigories illustrated in FIG. 3) and

when this refrigeration storage unit 22 renders frigories to the refrigerant which passes through it (phase of return of frigories illustrated in FIG. 4). In this system, the bypass of the circuit is carried out by the valve

36, the expansion in the frigory storage unit 22 by the valve 35 and the insulation of the frigory storage unit 22 by the valve 35 and the non-return valve 37.

The first bypass valve 25 is a 3-way valve arranged at a junction between the secondary thermal device 21 and the main thermal circuit 20.

In the phase of Figure 2, the valve 25 prevents the flow to the secondary thermal device 21 which is not used. In the phase of FIG. 3, the valve 25 allows circulation of the frigory storage unit 22 to the compressor 2.

In the phase of FIG. 3, the valve 25 allows the evaporator 10 to be circulated to the cold storage unit 22. The secondary thermal device 21 comprises a second bypass valve 27, which is a two-way valve, arranged to be selectively traversed by refrigerant which flows from the evaporator 10 of the main thermal circuit to the frigory storage unit 22 to enable refrigerants to be transferred from the refrigerant to the frigory storage unit via a refrigerant. relaxation in this valve.

The valve 27 is blocking in the operating phases of Figures 2 and 4, and passing in the operating phase of Figure 3.

The second bypass valve 27 is arranged to generate two pressure levels respectively for the evaporator 10 and the storage unit 22.

This second bypass valve may be a variable flow section valve, a single passage section valve or a 3-way valve (35b).

The secondary thermal device 21 comprises a secondary branch 28 on which this second bypass valve 27 is arranged, this branch 28 making a fluid junction 30 with a primary branch 29 on which the frigory storage unit 22 and the pump 23 are arranged.

This junction 30 between the primary branch 28 and the secondary branch 29 is arranged between the frigory storage unit 22 and the pump 23.

The secondary thermal device 21 comprises a non-return valve 31 disposed on the primary branch 29 downstream of the pump 23. Of course, the invention is not limited to the example just described.

For example, as illustrated in FIG. 5, the secondary thermal device 21 is arranged such that the direction of circulation of the refrigerant in the frigory storage unit 22 is the same, respectively:

when this storage unit 22 of frigories receives frigories of the refrigerant which passes through it and

- When this frigory storage unit 22 restores frigories to the refrigerant that passes through it.

Two bypass valves 35 and 36 are provided as explained below.

One of the bypass and expansion valves 35 is disposed at the inlet of the cold storage unit 22, on a primary branch 29. The other of the bypass valves 36 is disposed between the evaporator

10 and the pump 23, on a secondary branch 28.

According to one aspect of the invention, the valves 35 and 36 can be replaced by a 3-way valve 35b (see Figure 5a).

A check valve 37 is disposed at the outlet of the frigory storage unit 22.

In the above examples, the cold storage unit 22 is arranged to be at a lower pressure than that of the evaporator.

An expansion device 39, either thermostatic or electrical, is arranged upstream of the evaporator 10 to generate an expansion of the refrigerant before it passes through the evaporator 10.

The frigory storage unit 22 is arranged inside an HVAC or outside an HVAC. According to a variant illustrated in FIGS. 6 and 7, the system comprises an air channel 40 arranged parallel to the evaporator 10, a channel through which air can circulate bypassing the evaporator 10, and this air can, on leaving in this way, mix with the air coming from the evaporator. Thus, the position of the valve 27 downstream of the evaporator can help to adjust the temperature of the air at the outlet of the evaporator by mixing the cold air coming from the evaporator and the warmer air coming from the evaporator. see above air. This is advantageous during the frigory storage phase. The valve may be for example a simple closing valve with a fixed diameter. The 2-way valve referenced 27 is for example arranged to generate a fixed pressure drop so as to protect the evaporator from ice formation.

The refrigerant may be a material, in this case a fluid, with a phase change for working in latent heat in order to reduce the necessary mass and to limit the temperature variations of the storage.

For example, the refrigerant is a two-phase fluid type R134a or 1234yf.

The storer may contain a phase change material to limit temperature variations. In the above examples, the valves 27 or 35 provide an intermediate expansion so that the pressure of the compressor and that of the storage unit are different.

The pressure and temperature of the refrigerant being linked, so to continue to blow air at the right temperature for the passengers, it is necessary to limit the variation of pressure.

But to store, it is necessary to lower the temperature thus the pressure.

Intermediate expansion by the valves mentioned above makes it possible to have two pressure levels then two temperature levels. According to one aspect of the invention, the duct leading refrigerant flow of the frigory storage unit 22 to the pump 23 may be located downstream or upstream of the check valve or check valve 37 thus allowing the refrigerant pump to be disposed directly at the outlet of the frigory storage unit.

The difference between the mode of FIG. 5b and that of FIG. 5c is that, in the mode of FIG. 5c, the 3-way valve of FIG. 5b is replaced by two 2-way valves (see box in FIG. 5c).

Claims

1. A motor vehicle thermal system (1), in particular an air conditioning system, this system comprising:

a main thermal circuit (20) comprising a compressor arranged to compress a refrigerant circulating in this circuit and an evaporator arranged to cool a flow of air flowing in contact with the evaporator (10), this cooling being obtained by heat exchange between the flow of air to be cooled and the refrigerant circulating in this evaporator, a secondary thermal device (21) comprising a frigory storage unit (22), a device creating a detent between the outlet of the evaporator and the inlet of the cold storage unit, and a pump, this secondary device being arranged in a manner:

o to be connected, preferably in series, to the evaporator of the main thermal circuit when the compressor of the main thermal circuit is at a standstill or is operating at low speed so that refrigerant from the cold storage unit is sent, by means of the pump (23), through the evaporator of the main thermal circuit.

2. System according to the preceding claim, the pump (23) is arranged to be bypassed when the frigory storage unit receives frigories of the refrigerant which passes through it.

3. System according to one of the preceding claims, the secondary thermal device comprises at least a first bypass valve (25) and a second bypass valve and expansion (27) arranged to selectively prevent the exchange of refrigerant between the unit frigory storage and the main thermal circuit in normal mode.

4. System according to one of the preceding claims, the secondary thermal device (21) is arranged so that the flow direction of the refrigerant in the frigory storage unit is reversed respectively:

5. System according to the preceding claim, the first bypass valve is a 3-way valve disposed at a junction between the secondary thermal device and the main thermal circuit.

6. System according to one of claims 4 and 5, the secondary thermal device is arranged so that: - In operating mode of the main thermal circuit without use of the secondary thermal device, the cold storage unit (22) is bypassed and the pump is stopped.

- In operating mode of the main thermal circuit with charging in frigories of the cold storage unit of the secondary thermal device, the cold storage unit is traversed by refrigerant and the pump is stopped,

7. System according to one of claims 1 to 3, the secondary thermal device is arranged so that the direction of flow of the refrigerant in the frigory storage unit (22) is the same respectively:

8. System according to one of the preceding claims, the frigory storage unit is arranged to be at a lower pressure than that of the evaporator.

9. System according to one of the preceding claims, the valves (35 and 36) being replaced by a 3-way valve,

10. System according to one of the preceding claims, the conduit leading the refrigerant flow of the cold storage unit to the pump is located downstream or upstream of the non-return valve thus allowing the refrigerant pump to be placed directly at the outlet of the frigory storage unit.

1 1. System according to one of the preceding claims, the frigory storage unit is arranged inside an HVAC or outside an HVAC.

12. System according to one of the preceding claims, the system comprises an air path (40) disposed parallel to the evaporator, a path through which can circulate air bypassing the evaporator, and this air can, in out of this way, mix with the air coming from the evaporator.

13. System according to the preceding claim, the passage section of this channel being controlled by a flap.