IT202100015125A1 - Refrigerant circuit for the air conditioning of a motor vehicle - Google Patents

Description

DESCRIPTION OF THE INDUSTRIAL INVENTION ENtitled: "Refrigerant circuit for the air conditioning of a motor vehicle"

DESCRIPTION

The present invention relates to a refrigerant circuit for the air conditioning of a motor vehicle, said circuit being configured for the circulation of a refrigerant and comprising an evaporator and an internal heat exchanger associated with a unit? vehicle air conditioning,

a group of external heat exchangers configured to be installed on a frontal side of the motor vehicle, said external heat exchangers having a surface for a heat exchange between the circuit refrigerant and an air flow intended to pass through said heat exchange surface ,

an additional heat exchanger configured for a heat exchange between the refrigerant in the circuit and a fluid intended for thermal management of a vehicle battery, in which the evaporator? arranged on a first branch of the circuit and the additional heat exchanger ? arranged on a second branch of the circuit in parallel with the first branch of the circuit.

An object of the present invention ? that of modifying the circuit indicated above to increase the heat removal performance from the connected utilities, i.e. the cabin and the vehicle battery.

For this purpose, the object of the invention is a circuit having the characteristics defined above, in which the group of external heat exchangers comprises

a main heat exchanger without a subcooling section, an auxiliary heat exchanger with the function of condensing and subcooling the refrigerant and an auxiliary bypass arranged in parallel with the auxiliary heat exchanger, and

valve means switchable between a first position in which the auxiliary heat exchanger is connected in series with the main heat exchanger and the refrigerant ? able to pass between the main heat exchanger and the auxiliary heat exchanger, and a second location where the auxiliary bypass is connected in series with the main heat exchanger and the refrigerant ? able to pass through the main heat exchanger and the auxiliary bypass.

Therefore, the auxiliary heat exchanger serves to support the main heat exchanger in operation mode. cooling, to increase its capacity? to meet the high demands in terms of capacity? of condensation in harsh conditions, such as:

- in a fast charging situation for the high voltage battery B combined with passenger compartment cooling;

- in conditions of intensive road use; for an electric vehicle.

On the other hand, the valve configuration allows for individual operation of the main heat exchanger under low load conditions or other modes. operation of the air conditioning system.

Further characteristics and advantages of the circuit according to the invention will become more? clear with the following detailed description of an embodiment, made with reference to the attached drawings, provided for illustrative and non-limiting purposes only, wherein:

- figure 1 ? a diagram of a refrigerant circuit according to the invention; And

- figures 2 and 3 are perspective views from opposite sides of a group of external heat exchangers of the circuit of figure 1.

In figure 1 ? shown is a circuit for the circulation of a coolant, indicated as a whole with 1. This circuit forms part of an air conditioning system of a motor vehicle, and in particular it forms part of a heat pump system of an electric vehicle.

The circuit 1 comprises an internal heat exchanger 2 and a group of external heat exchangers, indicated as a whole with 3. The internal heat exchanger 2 ? configured to be installed? inside a? unit? air conditioning system H provided for air conditioning inside the vehicle passenger compartment. The outdoor heat exchanger group 3 ? configured to be installed on the front side of the vehicle, and will come? described more in detail below.

The circuit 1 comprises a compressor 10 and, downstream of the compressor in the direction of the refrigerant flow, the indoor heat exchanger 2 and the outdoor heat exchanger set 3. Upstream of the outdoor heat exchanger set 3 ? a first expansion valve 4 is arranged. Further downstream, the circuit 1 comprises a first branch 12 and a second branch 14 in parallel with each other, which are arranged between the group of heat exchangers 3 and the compressor 10.

The first branch 12 comprises a second expansion valve 18 and an evaporator 20. The evaporator 20 is part of the unit? of air conditioning H and ? configured to allow a heat exchange between the refrigerant and a flow of air intended to cool the passenger compartment of the vehicle. The unit of air conditioning H pu? further comprising a fan 21 configured to generate the aforementioned air flow, a group of doors 22 configured to orient/deflect the aforementioned air flow according to predetermined paths, and an electric heater 23, for example a PTC heater, configured to heat the aforementioned air flow.

The second branch 14 of the circuit 1 comprises a third expansion valve 24 (identical in construction to the second expansion valve 18) and an additional heat exchanger 30. This heat exchanger 30, commonly known as a ?chiller?, ? configured to allow a heat exchange between the refrigerant of circuit 1 and a fluid for the thermal management of a battery B of the vehicle. The battery thermal management fluid circulates in a separate circuit TC dedicated to the thermal management of battery B, and represented in an extremely simplified way in figure 1.

Self ? cooling of coil B is required, the heat exchange between the refrigerant of circuit 1 and the fluid for thermal management of coil B inside chiller 30 causes evaporation of the refrigerant and, consequently, cooling of the fluid for management battery thermal.

Circuit 1 can? further comprise an accumulator 31, arranged downstream of a point of confluence between the first branch 12 and the second branch and upstream of the compressor 10.

Circuit 1 can? further comprise a first bypass branch 41, having one end? upstream connected to a pipe 43 of the circuit 1 which connects an inlet of the group of external heat exchangers 3 and the first expansion valve 4 to an outlet of the internal heat exchanger 2, and an? connected downstream to a pipeline 44 which connects a branch point of the first branch 12 and of the second branch 14 to an outlet of the group of external heat exchangers 3. The first bypass branch 41 comprises a two-way valve 42, the Which ? controllable to selectively assume a first position in which the first bypass branch 41 ? open and the circuit 1 ? configured to operate in a cooling configuration, and a second position in which the first bypass branch 41 is closed and the circuit 1 ? configured to operate in a warm-up configuration.

On pipeline 44, upstream from? downstream of the first bypass branch 41 pu? furthermore, a non-return valve 45 is arranged.

Circuit 1 can? further comprise a second bypass branch 51, having one end? upstream connected to the pipe 44 upstream of the relative non-return valve 45, and one end? connected downstream to an inlet of the accumulator 11. The second bypass branch 51 comprises a two-way valve 52, which ? controllable to selectively assume a first position in which the second bypass branch 51 ? open and the refrigerant coming from the group of external heat exchangers 3 is conveyed to the first branch 12 and to the second branch 14, and a second position in which the second bypass branch 51 is closed and the refrigerant from the external heat exchanger group 3 is conveyed into the accumulator 31.

With reference also to figures 2 and 3, the group of external heat exchangers 3 comprises a main heat exchanger or evaporator-condenser 61, and an auxiliary heat exchanger 62 with condensing and sub-cooling functions. The main heat exchanger 61 ? without an integrated accumulator and therefore without a sub-cooling section.

The main 61 and auxiliary 62 heat exchangers have respective surfaces 61a and 62a for heat exchange between the refrigerant and an air flow F intended to pass through the heat exchangers 61, 62. The heat exchangers 61, 62 are configured to allow condensation and possibly sub-cooling of the refrigerant. The heat exchangers 61, 62 therefore guarantee the dissipation in the air of the heat generated by the cooling of the coil B, through the chiller 30, and/or by the unit? air conditioning system H, via the evaporator 20.

By way of example, the heat exchange areas 61a, 62a comprise pipes for circulating the coolant, which are connected to headers of the heat exchangers 61 and 62. Fins are preferably disposed between such pipes to increase the surface area of the heat exchanger. heat exchange.

In the illustrated example, the main 61 and auxiliary 62 heat exchangers are arranged in an overlapping relationship with respect to the air flow direction F, i.e. a direction orthogonal to the heat exchange areas 61a, 62a. In particular, the main 61 and auxiliary 62 heat exchangers are fixed in the same block, with the interposition of a further heat exchanger 66 which serves to cool the electric motor, the electric auxiliaries and possibly the battery and all the devices high voltage. Isn't this provision however essential for the purposes of the invention.

The heat exchanger set 3 further comprises an auxiliary bypass 63 arranged in parallel with the auxiliary heat exchanger 62. The heat exchanger set 3 further comprises a valve arrangement switchable between a first position, in which the auxiliary heat exchanger 62 ? connected in series with the main heat exchanger 61 and the refrigerant ? capable of passing through the main heat exchanger 61 and the auxiliary heat exchanger 62, therefore without passing through the auxiliary bypass 63, and a second position in which the auxiliary bypass 63 is connected in series with the main heat exchanger 61 and the refrigerant ? capable of passing through the main heat exchanger 61 and the auxiliary bypass 63, therefore without passing through the auxiliary heat exchanger 62.

With reference to the figures, the main heat exchanger 61 comprises an inlet 61.1 connected, through the first expansion valve 4, to the internal heat exchanger 2, and an outlet 61.2 to which the auxiliary heat exchanger 62 and the bypass are connected auxiliary 63. The auxiliary heat exchanger comprises an inlet 62.1 connected to the outlet 61.2 of the main heat exchanger 61, and an outlet 62.2 connected to the pipe 44 which leads to the first branch 12 and to the second branch 14. In the illustrated example, The valving arrangement comprises two two-way valves indicated at 64 and 65, one disposed in series with the auxiliary heat exchanger 62 and the other disposed on the auxiliary bypass 63. Such valves may be controlled simultaneously (e.g., with the same signal electric control) to selectively enable or disable the auxiliary heat exchanger 62.

The auxiliary heat exchanger 62 therefore serves to support the main heat exchanger 61 in operation in the mode cooling, to increase its capacity? to meet the high demands in terms of capacity? of condensation in harsh conditions, such as:

- in a fast charging situation for the high voltage battery B combined with passenger compartment cooling;

- in conditions of intensive road use; for an electric vehicle.

On the other hand, the configuration of valves 63, 64 allows for individual operation of the main heat exchanger 61 under the conditions of reduced load or in other modes. operation of the air conditioning system.

It is understood that the invention is not limited to the embodiments described and illustrated herein, but ? on the other hand, it is susceptible to modifications relating to the shape and arrangement of parts, constructive and operating details, according to the numerous possible variations which will appear appropriate to those skilled in the sector, and which are to be understood as included within the scope of the invention, as as defined by the following claims.

Claims (2)

1. Refrigerant circuit (1) for the air conditioning of a motor vehicle, said circuit being configured for the circulation of a refrigerant and comprising an evaporator (20) and an internal heat exchanger (2) associated with a unit? of air conditioning (H) of the vehicle, a group of external heat exchangers (61, 62) configured to be installed on a front side of the motor vehicle, said external heat exchangers having a surface (61a, 62a) for a heat exchange between the circuit refrigerant (1) and a flow of air (F) intended to pass through said heat exchange surface, an additional heat exchanger (30) configured for a heat exchange between the circuit refrigerant (1) and a fluid intended for thermal management of a vehicle battery (B), in which the evaporator (20) ? arranged on a first branch (12) of the circuit (1) and the supplementary heat exchanger (30) ? arranged on a second branch (14) of the circuit (1) in parallel with the first branch (12) of the circuit (1), said cooling circuit being characterized in that the group of external heat exchangers comprises a main heat exchanger (61) without a subcooling section, an auxiliary heat exchanger (62) with the function of condensing and subcooling the refrigerant, and an auxiliary bypass (63) arranged in parallel with the heat exchanger auxiliary (62), e valve means (64, 65) switchable between a first position in which the auxiliary heat exchanger (62) is connected in series with the main heat exchanger (61) and the refrigerant ? capable of passing through the main heat exchanger (61) and the auxiliary heat exchanger (62), and a second location where the auxiliary bypass (63) is connected in series with the main heat exchanger (61) and the refrigerant ? capable of passing through the main heat exchanger (61) and the auxiliary bypass (63). The circuit according to claim 1, wherein the main heat exchanger (61) and the auxiliary heat exchanger (62) are arranged in an overlapping relationship with respect to a direction perpendicular to the respective heat exchange surfaces (61a, 62a) .