Patent Grant
11028756
This application is a U.S. non-provisional application claiming the benefit of French Application No. 18 57410, filed on Aug. 9, 2018, which is incorporated herein by its entirety.
The present invention relates to a thermal system, in particular for a motor vehicle.
Standard internal combustion engines have a low performance. Indeed, only 20 to 30% of the energy from the fuel is converted into mechanical energy, while the rest is dissipated into the environment in the form of heat energy, this energy loss being dissipated in the exhaust gases and in a cooling device of the vehicle.
In order to recover part of this energy, a thermal system already exists in the state of the art comprising a Rankine cycle heat recovery device including a Rankine circuit, in which a working fluid (called Rankine fluid) circulates, the circuit including a first heat exchanger in which the Rankine fluid recovers heat from a heat source, an expander, a condenser, and a first pump.
Such a heat recovery device with Rankine cycle makes it possible to convert the heat energy into mechanical or electrical energy.
The first pump makes it possible to compress and circulate the Rankine fluid. This Rankine fluid enters the first heat exchanger, in which the heat from the exhaust gases or the cooling device is used to evaporate the Rankine fluid. This high-pressure vapor passes through an expander, where it is expanded into low-pressure vapor. This expander can be a volumetric expander, such as a piston or a spiral, or a dynamic expander, like a turbine. This expander produces mechanical energy and this mechanical energy can be converted into electricity using an electrical generator. The low-pressure vapor is next cooled and condensed in the condenser.
It should be noted that the Rankine fluid can be subject to pressure variations between the expander and the pump, which may in some cases cause cavitation of the pump.
A thermal system is provided in which the pressure between the expander and the pump of the Rankine cycle heat recovery device is regulated automatically, without requiring a regulating valve.
To that end, a thermal system is provided, in particular for a motor vehicle, of the type including:
The pressure regulating device is an additional device, therefore separate from the expander of the Rankine circuit and separate from the second pump.
The pressure in the cooling device is used to control the pressure between the expander and the pump of the Rankine cycle heat recovery device.
A thermal system can further include one or several of the following features, considered alone or according to all technically possible combinations:
The invention also relates to an exhaust line, in particular of a motor vehicle, comprising a thermal system as previously described.
The invention also relates to a vehicle, in particular a motor vehicle, comprising an exhaust line as previously described.
The invention will be better understood upon reading the following description, provided solely as an example and done in reference to the appended figures, in which:
The thermal system 10 comprises a Rankine cycle heat recovery device 12 including a Rankine circuit 14, in which a Rankine fluid 16 circulates, the Rankine circuit 14 including a first heat exchanger 18 in which the Rankine fluid 16 recovers heat from a heat source 20, an expander 22, a condenser 23 and a first pump 24.
For example, the heat source 20 is an exhaust gas EG.
According to this first embodiment, the condenser 23 is included in a device 26 for regulating the pressure, shown in detail in
The thermal system 10 also comprises a cooling device 28 including a cooling circuit 30, in which a refrigerant 32 circulates. The cooling circuit 30 includes a second heat exchanger 34 in which the refrigerant 32 gives heat to a cold source, a second pump 36, and a third heat exchanger 38 with a device to be cooled, the device to be cooled, for example, being an engine E of the motor vehicle V.
The cooling circuit 30 also conventionally includes an expansion tank 40.
Advantageously, the expansion tank 40 meets the following operating conditions:
Under these operating conditions, the Rankine fluid 16 is ethanol.
As previously indicated, the thermal system 10 according to the invention comprises the device 26 for regulating the pressure in the Rankine circuit 14, shown in more detail in
The pressure regulating device 26 includes an enclosure 42 delimiting a space, and housing a movable part 44 separating the space into first 46 and second 48 chambers. The first chamber 46 communicates with the Rankine circuit 14, and it is therefore filled with Rankine fluid 16, and the second chamber 48 communicates with the cooling circuit 30, and it is therefore filled with refrigerant 32.
According to this embodiment, the first chamber 46 houses the condenser 23, which is formed by a heat exchange pipe, preferably provided with fins, and in which the refrigerant 32 circulates.
Owing to the pressure regulating device 26, the pressure is transmitted to the Rankine fluid 16 by the movable part 44 that separates the Rankine fluid 16 from the refrigerant 32.
It will be noted that the movable part 44 can be formed by a membrane 44a, a bladder 44b, or in a variant by a piston 44c as shown in
The pressure in the pressure regulating device 26 is the same as that in the expansion tank 40 of the cooling circuit 30. This pressure depends on the thermal expansion of the refrigerant 32, therefore its temperature.
It should be noted that the saturation pressure upstream from the first pump 24 is lower than the pressure in the expansion tank 40.
According to the embodiment shown in
Advantageously, the inlet pipe 50 is connected to the cooling circuit 30 via a valve 54, making it possible to control the flow rate of refrigerant 32 through the second chamber 48.
The valve 54 is, for example, a three-way valve comprising a first path connected to the cooling circuit 30, a second path connected to the second chamber 48 and more specifically to the refrigerant 32 inlet pipe 50 into the second chamber 48, and a third path connected to the heat exchange pipe of the condenser 23. Thus, the valve 54 also makes it possible to control the flow of refrigerant 32 through the condenser 23, in order to control the temperature of the Rankine fluid 16 leaving this condenser 23, therefore at the inlet of the first pump 24.
The operation of the thermal system 10 according to the first embodiment will now be described.
The Rankine fluid 16 takes heat in the first exchanger 18, then is expanded in the expander 22, before arriving in gaseous form in the first chamber 46, where it is condensed in liquid form before leaving the first chamber 46 toward the first pump 24.
In the cooling circuit 30, the refrigerant 32, driven by the second pump 36, recovers calories from the third heat exchanger 38, to restore them to the second heat exchanger 34, conventionally.
Part of the refrigerant 32 is, however, deflected toward the pressure regulating device 26, and more specifically toward the condenser 23 and toward the second chamber 48. The flow rate of this refrigerant portion 32 is regulated by the valve 54.
The pressure of the refrigerant 32 is transmitted to the Rankine fluid 16 by the movable part 44, thus compensating the volume variations of the Rankine fluid 16.
The refrigerant 32 leaving the pressure regulating device 26 next enters the second heat exchanger 34, where it is cooled.
The thermal system 10 according to this second embodiment differs from that of the first embodiment in that the condenser 23′ and the pressure regulating device 26′ are separate.
The condenser 23′ is then arranged downstream from the expander 22 and upstream from the pressure regulating device 26′.
The pressure regulating device 26′ includes an enclosure 42′ delimiting a space, and housing a movable part 44′ separating the space into first 46′ and second 48′ chambers. The movable part 44′ is, for example, a membrane, a piston or a bladder.
The first chamber 46′ communicates with the Rankine circuit 14, and more specifically with a first branch 56 connecting the condenser 23′ to the first pump 24.
The second chamber 48′ communicates with the cooling circuit 30, and more specifically with a second branch 58 connecting the second heat exchanger 34 to the second pump 36.
The operation of the pressure regulation in the Rankine circuit 14 is similar to that previously described for the first embodiment.
The thermal system 10 according to this third embodiment differs from that of the second embodiment in that the second chamber 48′ is connected to the cooling circuit 30 via a valve 60.
More specifically, the valve 60 is a three-way valve arranged in parallel with the second pump 36, including a first channel connected to the second chamber 48′, a second channel connected upstream from the second pump 36, and a third channel connected downstream from the second pump 36.
The operation of the pressure regulation in the Rankine circuit 14 is similar to that previously described for the second embodiment, with the exception of the fact that, owing to the valve 60, the second chamber 48′ can be connected to the cooling circuit 30 upstream or downstream from the second pump 36, depending on the desired pressure.
It will be noted that the invention is not limited to the embodiments previously described, but could take the form of various variants.
Although an embodiment of this invention has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this disclosure. For that reason, the following claims should be studied to determine the true scope and content of this disclosure.
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