EP3423354A1

EP3423354A1 - System comprising a hybrid air conditioning unit for an aircraft cabin

Info

Publication number: EP3423354A1
Application number: EP17711709.0A
Authority: EP
Inventors: David Lavergne; Jérôme ROCCHI
Original assignee: Liebherr Aerospace Toulouse SAS
Current assignee: Liebherr Aerospace Toulouse SAS
Priority date: 2016-02-29
Filing date: 2017-02-24
Publication date: 2019-01-09
Also published as: FR3048231B1; FR3048231A1; WO2017149228A1

Abstract

The present invention proposes a system comprising an air conditioning unit using an electric motor coupled to the rotary shaft of an air cycle machine (ACM) so that the rotation of the shaft of the ACM is accelerated during phases of flight in which the aircraft engine speed is low, this being when a pressure and flow rate of the air entering the air conditioning unit is below a predetermined threshold. Through this mechanism, the compressor can increase the compression ratio of the air handled by the ACM when the pressure or flow rate of the incoming air is not high enough to supply the air conditioning unit. The proposed system appears to be less complex and more lightweight than the system of the prior art, because it is possible to air-cool the power electronics and a single compressor is used instead of two.

Description

SYSTEM COMPRISING A HYBRID AIR CONDITIONING UNIT FOR AN AIRCRAFT CAB

Technical area

The present invention relates generally to a system comprising an air conditioning unit for a cabin of an aircraft.

The invention finds applications, in particular, in aircraft whose air intake is essentially sized for supplying the cabin air conditioning unit.

Prior art

Most aircraft marketed today include a cabin air conditioning unit that is part of an Environmental Control System (ECS). The air conditioning unit has several functions, namely, to deliver a certain fresh air flow to the pressurized zone to ensure a sufficient oxygen turnover rate for cabin occupants and a sufficient amount of air for the cabin occupant. Pressurizing system, dry the air sent to the pressurized zone and also provide air conditioning and heating functions. Generally, the air conditioning unit uses as power source the air intake on the engines of the aircraft through two sampling ports, namely, the IP sampling port (in English, Intermediate Pressure) to an intermediate pressure and the HP port (in English, High Pressure) at a higher pressure. The air sampled via the IP and HP ports is known in English as "bleed air".

Conventionally, the IP port is used when the engine speed of the aircraft is high, for example during the rise and cruise phases while the HP port is used when the engine speed of the aircraft is low, for example, in the taxiing, descent and waiting phases.

However, this kind of architecture requires the use of heavy pre-coolers that have a negative impact on the consumption of the aircraft.

In a first approach to solve this problem, some known aircraft, such as the B787, propose the use of an air conditioning unit based on a source of electrical energy instead of air sampling on the engines. In this context, electrical energy is used to supply motor compressors that themselves supply the air conditioning unit. However, this type of architecture requires the use of large motor compressors arranged upstream of the air conditioning unit, which causes significant power consumption. In addition, the power electronics of an electric air conditioning unit requires liquid loop cooling. This type of cooling is known to be heavy, complex and unreliable. This solution is therefore not satisfactory.

In another hybrid approach that seems to have not yet put into production, the document US 2013/0040545 A1 (hereinafter D1) plans to use only the IP port to supply the air conditioning unit. D1 has identified that in flight phases where the engine speed of the aircraft is low, the pressure of the air drawn on the IP port is not sufficient to properly operate the air conditioning unit. To solve this problem, D1 proposes to use an auxiliary compressor arranged upstream of the air conditioning unit and which is powered by an electric motor. Thus, when the engine speed of the aircraft is low and the pressure of the air drawn on the IP port is below a certain threshold, the auxiliary compressor is activated to compress the air taken from the IP port in order to obtain air at a required pressure and then injected into the air conditioning unit.

However, this solution is not totally satisfactory because it requires the addition of an auxiliary compressor for each group of air packs, which is expensive, complex and causes an increase in the weight that the aircraft must bear.

Summary of the invention

The object of the present invention is to propose a system having a new architecture comprising an air conditioning unit that can operate solely on the basis of a single air intake port without, however, requiring the addition of an auxiliary compressor for ensure the operation of the air conditioning unit during flight phases where the engine speed of the aircraft is low. To this end, the invention proposes a system comprising an air conditioning unit for a cabin of an aircraft, the air conditioning unit of which comprises an air cycle machine (ACM). The ACM of the air conditioning unit comprises at least one expansion turbine and a compressor, the turbine being mechanically coupled to the compressor via a first rotary shaft so as to drive the compressor. The system is characterized by:

a single port designed to take air on at least one of the engines of the aircraft so as to supply an inlet of the air conditioning unit, the air taken from having at least one fluidic characteristic making it suitable supplying the air conditioning unit when the aircraft is in the climbing or cruising phase;

at least one measuring sensor designed to measure the fluidic characteristic of the air entering the inlet of the air conditioning unit;

the ACM further comprising a first electric motor coupled to the first shaft; and,

a control unit coupled to the measurement sensor and to the first electric motor, the control unit being configured to control the operation of the first electric motor, when the measurement of the fluidic characteristic is lower than a predetermined threshold, so that the rotation of the first shaft is accelerated so that the air output of the compressor has a fluidic characteristic making it able to feed the cabin when the aircraft is in flight phase taxiing, descent or waiting. Where appropriate, the first electric motor has an electric power of less than 30 kW, for example between 10 and 20 kW.

In one implementation, the fluidic characteristic of the air is chosen from: a pressure and a flow rate.

In one example, the predetermined threshold is of the order of 18 psia or 0.30 kg / s when, respectively, the fluidic characteristic is a pressure or a flow rate. Advantageously, the system may further comprise a fan disposed on a second rotary shaft disjoint from the first rotary shaft.

In a first example, the second rotary shaft is provided to be driven by a second electric motor disposed on the second shaft and configured to supply the fan.

Where appropriate, the second electric motor has an electric power greater than 3 kW, for example between 4 and 5 kW.

In a second example, the second rotary shaft is provided to be driven by a second turbine mechanically coupled to the fan via the second shaft so as to drive the fan.

In a first implementation of the second example, the second turbine is pneumatically coupled to the compressor inlet.

In a second implementation of the second example, the second turbine is pneumatically coupled to the inlet of the air conditioning unit.

Brief Description of Drawings

Other features and advantages of the invention will become apparent on reading the description which follows. This is purely illustrative and should be read in conjunction with the accompanying drawings in which: - Figure 1 is a block diagram showing a system according to the invention;

FIG. 2 is a functional diagram showing an improvement of the system of FIG. 1, according to a first embodiment; and, - Figure 3 is a functional diagram showing an improvement of the system of Figure 1, according to a second embodiment;

Similar references used in different figures designate similar elements.

DETAILED DESCRIPTION OF EMBODIMENTS As part of this description, all the power and rate values provided relate to an aircraft of about one hundred passengers. Those skilled in the art will be able to extrapolate these values for other capabilities of the number of passengers. In the context of the invention, contrary to known techniques, it is not proposed to add an auxiliary compressor to the air conditioning unit to ensure the operation of the group during flight phases where the engine speed of the plane is weak. In the invention, it is proposed to use the compressor of the air cycle machine (in English, "Air Cycle Machine") ACM which is already included in the air conditioning group. In addition, the invention proposes to use an electric motor coupled to the rotary shaft of the ACM so that the rotation of the ACM shaft is accelerated during phases of flight where the engine speed of the The aircraft is weak when a pressure or flow rate of air entering the air conditioning unit is below a predetermined threshold. By this mechanism, the compressor can increase the compression rate of the air treated by the ACM when the pressure or the flow of the incoming air is not sufficient to supply the air conditioning unit. The system proposed appears less complex and lighter than the system of the prior art, because a cooling of the power electronics by air is possible and a single compressor is used instead of two.

In the context of the invention, consider an aircraft whose air intake is essentially sized for the supply of the air conditioning unit. This concerns, for example, airplanes that favor the use of electrical energy to perform the function of icing protection so that the intake of air on the engines can be dedicated to the supply of the air conditioning unit. This may also concern, for example, airplanes that perform the deicing function pneumatically, including through inflatable tubes.

In the rest of the description, it will be considered for illustration, a turboprop type aircraft such as a regional transport aircraft. However, this choice is only illustrative and the invention can be applied to other types of aircraft having the characteristics of air sampling as described above, in the phases of flight where the engine speed is low.

FIG. 1 illustrates the general structure of an embodiment of a system according to the invention, comprising an air conditioning unit (hereinafter air conditioning unit) 100. The system according to the invention comprises a single port (not shown) for taking air on at least one of the engines of the aircraft.

In Fig. 1, the air conditioning unit 100 includes an inlet 110 which is configured to be powered by air drawn from the single port of the system. The air conditioning unit 100 then comprises a flow control valve FCV 130 which is configured to regulate the flow rate of the air entering the inlet 1 10. Thereafter, the withdrawn air is directed to a heat exchanger 130 which comprises a primary heat exchanger (PHX 131) and a main heat exchanger (MHX 132.) heat exchanger 130 also includes an outside air circulation circuit (in English, "ram air") 133 extending between an inlet 1331 and an outside air outlet 1332. The air received at the inlet 1 10 which passes through the heat exchanger 130 is cooled by the absorption of its heat by the air circulation circuit 133. In a known manner, as the aircraft is on the ground, a fan 141 is used to ventilate the heat exchanger 130, the fan 141 being disposed downstream of the heat exchanger 130. 1332. In the conventional manner, on the ground, pneumatic energy is supplied by a small turbine engine, forming an Auxiliary Power Unit (APU 170). 1, the heat exchanger PHX 131 is configured to cool the air regulated by the valve FCV 120. Thereafter, there is a compressor 142, coupled to the heat exchanger PHX 131 and the heat exchanger MHX 132 The compressor 142 is configured to compress the air cooled by the PHX heat exchanger while the heat exchanger MHX 132 is configured to cool the compressed air by the compressor 142. This air cooled by the heat exchanger MHX 132 is then injected into a water extraction device 150 which is configured to dehydrate the air.

The water extraction device 150 generally comprises a condenser (not shown) and a water separator (not shown) mounted downstream of the condenser. The condenser is configured to cool the cooled air by the MHX heat exchanger 132.

Subsequently, a turbine 143, coupled to the water extraction device 150, is provided to vent the dehydrated air by the water extraction device 150. The turbine 143 is also configured to direct the relaxed air in heat exchange through the condenser of the water extraction device 150 for cooling the compressed air by the compressor 142 to the temperature required for the separation of water in the water extraction device 150. Finally, the Expelled air is directed out of the air conditioning unit 100 to be mixed in a mixing chamber (not shown) in the form of fresh air to recirculate air from the cabin of the aircraft. In the air conditioning unit 100 of FIG. 1, the turbine 143, the compressor 142 and the fan 141 are disposed on a rotary common shaft 144 and form an air cycle machine (in English, "Air cycle Machine"). ) ACM 140, also referred to as a three-wheel machine. The assembly consisting of the turbine 143 and the compressor 142, which are mechanically linked, is also called turbocharger. By this arrangement, the energy produced by the turbine 143 drives the compressor 142 and the fan 141.

The air conditioning unit 100 of Figure 1 further comprises an electric motor 145 disposed in the ACM 140 and coupled to the rotary shaft 144. In one example, the electric motor 145 is a permanent magnet synchronous motor. In a particular implementation, the electric motor 145 has an electric power of less than 30 kW, where appropriate between 10 and 20 kW. The air conditioning unit 100 of FIG. 1 also comprises a measurement sensor 160 disposed at the inlet 1 10 and configured to measure a fluidic characteristic of the air entering the inlet 1 10. For example, the fluidic characteristic of the received air is chosen from an air pressure and an air flow rate. In the remainder of the description, it will be considered by way of example that the fluidic characteristic measured by the measurement sensor 160 is an air pressure. In addition, the air conditioning unit 100 of FIG. 1 comprises a control unit 146 coupled to the electric motor 145 and the measurement sensor 160. The control unit 146 is configured to control the start-up of the electric motor 145, when a measurement of the fluidic characteristic is lower than a predetermined threshold, so that the rotation of the rotary shaft 144 is accelerated so that the air at the outlet of the compressor or at the outlet of the turbine has a fluidic characteristic on the making it possible to feed the cabin when the airplane is in the taxi phase of taxiing, descent or waiting. In one example, the fluidic characteristic is a pressure at the outlet of the compressor or a flow rate at the outlet of the turbine. In a particular embodiment, the control unit 146 may be cooled by cabin outlet air 10. Thus, in operation, when, for example, an air pressure measured by the measuring sensor 160 is greater than a predetermined pressure value, the electric motor 145 is not started and the compressor 142 is only energized. mechanical mechanism via the rotary shaft 144 driven by the turbine 143. In one example, the predetermined value is of the order of 18 psia when the fluidic characteristic is an air pressure. In another example, when the fluidic characteristic is a flow of air, the predetermined value is of the order of 0.30 kg / s.

Continuing the operation, when, for example, the air pressure measured by the measuring sensor 160 is lower than the predetermined value, the control unit 146 controls the starting of the electric motor 145 to accelerate the rotation of the the rotary shaft 144 so that the air output of the compressor 142 has a pressure making it able to provide the right level of flow in the cabin when the aircraft is in the rolling phase, descent or waiting. In other words, the actuation of the electric motor 145 has the effect that the air at the outlet of the compressor 142 has an air pressure that corresponds to that which it would have had if the air pressure at the level of the input 1 10 was sufficient to power the air conditioning unit 100 without the need to start the electric motor 145. In the example above, it was indicated that the predetermined value is of the order of 18 psia. at the level of the input 1 10. Continuing on the basis of this example, the effect of the start of the electric motor 145 would have the effect that the pressure measurement at the input 1 10 is the same. order of 23 psia. However, an air pressure of 23 psia at the inlet 1 10 is sufficient to supply the group 100 without requiring the start of the electric motor 145, when the aircraft is in the rolling phase, descent or waiting. In another example, if one considers the airflow as a relevant characteristic for a predetermined value of 0.30 kg / s, then the effect of starting the electric motor 145 will have the effect that the measurement of flow rate at the input 1 10 is of the order of 0.30 kg / s while without the start of the electric motor 145, the flow measurement at the input 1 10 would be of the order of 0.20 kg / s. The new architecture of the system according to the invention, as shown in FIG. 1, thus relates to a hybrid configuration of the air conditioning unit 100 insofar as the compressor 142 can be powered by a source of pneumatic energy generated by the turbine 143 or by the source of pneumatic energy combined with a source of electrical energy generated by the electric motor 145.

Figure 2 illustrates an improvement of the system of Figure 1, comprising an air conditioning unit 200, according to a first embodiment. In the air conditioning unit 200, the same elements are designated by references similar to those of the air conditioning unit 100.

In the air conditioning unit 200 of Figure 2, the fan 241 is not disposed on the rotary shaft 244 of the motorized turbocharger (242, 243, 245). In the particular embodiment of Figure 2, the fan 241 is disposed on another rotating shaft 247 disjoint from the rotary shaft 244 of the motorized turbocharger (242, 243, 245). Thus, in Figure 2, the fan 241 is no longer part of the ACM 240.

In the example of Figure 2, the rotary shaft 247 is configured to be driven by an electric motor 248 disposed on the rotary shaft 247 and which is configured to supply the fan 241. For example, the electric motor 248 is a permanent magnet synchronous motor. In a particular embodiment, the electric motor 248 has an electric power greater than 3 kW, where applicable between 4 and 5 kW. In another implementation, the control unit 246 as described above, is also used to control the electric motor 248 of the fan 241. In this case, it is possible to use a known switching device, such as a switch for the control unit 246 to control the electric motor 245 when the air conditioning unit 200 needs it or only the electric motor 248 of the fan 241. when the ACM 240 does not need it, as mentioned above.

Finally, the air conditioning unit 200 also comprises a conventional arrangement with a non-return valve 249 disposed in the air-conditioning circuit. outside air recirculation 233 which allows either the use of the dynamic outside air in flight, or the use of the fan 241 on the ground, to cool the heat exchanger 230.

The architecture of the system of FIG. 2 thus presents an electric fan (241, 248) no longer part of the ACM 240 and therefore no longer being powered mechanically via the common shaft 244 of the ACM 240 as it does. was the case in the air conditioning unit 100 of FIG. Preferably, the electric fan (241, 248) of Figure 2, is adapted to circulate air at a temperature of about 150 ° C. This distinguishes it from electric recirculating or cabin extracting fans which have a lower power ranging from 1 to 5 kW and can not circulate air at a temperature of less than 70 ° C.

The architecture of Figure 2 has the advantage of being able to operate on the ground in cooling mode at low power (in English, "low cooling power") without APU 270 group, only with the motorized compressor (242, 246). In this case, the supply of the motorized compressor (242, 246) and the fan 241 could be made from an electric park group. This solution would reduce polluting and acoustic emissions on the tarmac. Figure 3 illustrates an improvement of the system of Figure 1, comprising an air conditioning unit 300, according to a second embodiment. In the air conditioning unit 300, the same elements are designated by references similar to those of the air conditioning unit 100. As in the air conditioning unit 200 of Figure 2, the fan 341 is not disposed on the rotary shaft 344 of the motorized turbocharger (342, 343, 345). In the particular embodiment of Figure 3, the fan 344 is also disposed on another rotating shaft 347 disjoint from the rotational shaft 344 of the motorized turbocharger (342, 343, 345). Thus, as in Figure 2, the fan 341 is no longer part of the ACM 340. However, in the example of Figure 3, the rotary shaft 347 is configured to be driven by a second turbine 390 mechanically coupled to the fan 341 via the rotary shaft 347 to drive the fan 341.

In a first implementation of the architecture of the system of FIG. 3, the turbine 390 is pneumatically coupled to the input 1 10. In a second implementation of the architecture of the system of FIG. is pneumatically coupled to the inlet of the compressor 340.

The architecture of FIG. 3 therefore has a turbofan (341, 390) that is not part of the ACM 340 and is therefore no longer fed mechanically by the common shaft 344 of the ACM 340.

In general, it may be noted that the architectures of FIGS. 2 and 3 have the advantage of being particularly suitable in cases where the dynamics of the rotary shaft (244, 344) would not allow integration on a single common shaft. , a turbine wheel, an electric motor, a compressor wheel and a fan wheel. Thus, by removing the fan function from the ACM (240, 340), this possible tree dynamics problem can be overcome. This solution also has the advantage of allowing the operation of the fan at its optimum speed and therefore to improve its efficiency.

The present invention makes it possible to propose a system comprising an air conditioning unit which relies on the withdrawal of air from a single sampling port without, however, requiring the addition of an auxiliary compressor to ensure the operation of the air conditioning unit during flight phases where the engine speed of the aircraft is low, as is the case in the known prior art. This particular arrangement makes it possible to envisage reducing or even eliminating the pre-cooler of the airplane (in English, precooler), whose function is to ensure the cooling of the air taken before sending it, in particular to the air conditioning unit and / or the wing de-icing system. Reducing the pre-cooler is particularly beneficial for planes flying at more than 25,000 feet, as it will no longer be necessary to cool the air taken from the HP port. On the other hand, for planes flying up to 25,000 feet, it is possible to delete the ECP. Another advantage of the invention lies in the cooling of the control unit (146, 246, 346) which can be achieved by the cabin exhaust air 10. In fact, unlike an all-electric air-conditioning unit, it is not necessary to use a liquid loop to cool the heat dissipated by the power electronics required for its operation. Indeed, as explained above, in the context of the invention, the power electronics used does not cause an electrical consumption comparable to that which is generated by the all-electric air conditioning unit.

The system comprising the air conditioning unit (100, 200, 300) as described above can in particular, find applications on all ranges of regional aviation such as turboprops or aircraft using a defrost fully electric wing that does not require air sampling on the compression stages of the aircraft engines. Of course, the present invention is not limited to the preferred embodiment and embodiments described above by way of non-limiting examples. It also relates to the variants within the scope of those skilled in the art within the scope of the claims below. For example, it is also to use the invention in a plane several groups of air conditioners. In addition, those skilled in the art will note that all power and flow values provided in the description as well as in the claims are valid for a hundred-passenger airplane. However, it is contemplated that those skilled in the art will be able to extrapolate these values for other capabilities of the number of passengers of a particular aircraft.

Claims

A system comprising an air conditioning unit (100, 200, 300) for a cabin of an aircraft, the aircraft being arranged so that the air bleed is substantially sized to supply the air conditioning unit , the air conditioning unit comprising an air cycle machine (ACM, 140), the ACM comprising an expansion turbine (143, 243, 343) and a compressor (142, 242, 342), the turbine being mechanically coupled to the compressor via a first rotary shaft (144, 244, 344) to drive the compressor, the system being characterized by:

a single port designed to draw air on at least one of the engines of the aircraft so as to feed an air intake (110, 210, 310) of the air conditioning unit, the air sampled having at least one fluidic characteristic making it suitable for supplying the air conditioning unit when the aircraft is in a climbing or cruising phase;

at least one measuring sensor (160, 260, 360) for measuring the fluidic characteristic of the air entering the inlet of the air conditioning unit;

the ACM further comprising a first electric motor (145, 245, 345) coupled to the first rotary shaft;

a control unit (146, 246, 346) coupled to the measurement sensor and to the first electric motor, the control unit being configured to control the operation of the first electric motor, when the measurement of the fluidic characteristic is less than one predetermined threshold, so that the rotation of the first shaft is accelerated so that the air output of the compressor or turbine inlet has a fluidic characteristic making it able to feed the cabin when the aircraft is in flight phase of taxiing, descent or waiting; and,

characterized in that the system is arranged to cool the control unit from cooling air from within and / or from outside the aircraft.

2. System according to claim 1, wherein

the aircraft comprises a turboprop engine, and

the cooling air comes from an air outlet of the cabin of the aircraft and / or from an outside air intake of the aircraft.

3. System according to any one of claims 1 or 2, wherein the first electric motor has an electric power less than 30 kW, where appropriate between 10 and 20 kW.

The system of any one of claims 1, 2 or 3, wherein the fluidic characteristic of the air is selected from: a pressure and a flow rate and wherein the predetermined threshold is of the order of 18 psia or 0.30 kg / s when, respectively, the fluidic characteristic is a pressure or a flow rate.

5. System according to any one of claims 1, 2, 3 or 4, further comprising a fan (141, 241, 341) disposed on a second rotary shaft (247, 347) disjoint from the first rotary shaft.

The system of claim 5, wherein the second shaft is adapted to be driven by a second electric motor (248) disposed on the second shaft and configured to power the fan.

7. System according to claim 6, wherein the second electric motor has an electric power greater than 3 kW, where appropriate between 4 and 5 kW.

The system of claim 5, wherein the second shaft is adapted to be driven by a second turbine (390) mechanically coupled to the fan via the second shaft to drive the fan.

The system of claim 8, wherein the second turbine is pneumatically coupled to the compressor inlet.

The system of claim 8, wherein the second turbine is pneumatically coupled to the inlet of the air conditioning unit (110, 210, 310). CLAIMS

1. System comprising an air conditioning unit (100, 200, 300) for a cabin of an aircraft, the air conditioning unit comprising an air cycle machine (ACM, 140), the ACM comprising a turbine an expansion device (143, 243, 343) and a compressor (142, 242, 342), the turbine being mechanically coupled to the compressor via a first rotary shaft (144, 244, 344) to drive the compressor, the system being characterized by :

a single port designed to draw air on at least one of the engines of the aircraft so as to feed an air inlet (1 10, 210, 310) of the air conditioning unit, the sampled air having at least one fluidic characteristic making it suitable for supplying the air conditioning unit when the aircraft is in the climbing or cruising phase;

the ACM further comprising a first electric motor (145, 245, 345) coupled to the first rotary shaft; and,

a control unit (146, 246, 346) coupled to the measurement sensor and to the first electric motor, the control unit being configured to control the operation of the first electric motor, when the measurement of the fluidic characteristic is less than one predetermined threshold, so that the rotation of the first shaft is accelerated so that the air output of the compressor or turbine inlet has a fluidic characteristic making it able to feed the cabin when the aircraft is in flight phase of taxiing, descent or waiting.

2. System according to claim 1, wherein the first electric motor has an electric power less than 30 kW, where appropriate between 10 and 20 kW.

3. System according to any one of claims 1 or 2, wherein the fluidic characteristic of the air is selected from: a pressure and a flow rate.

The system of claim 3, wherein the predetermined threshold is of the order of 18 psia or 0.30 kg / s when, respectively, the fluidic characteristic is a pressure or a flow rate.

The system of claim 5, wherein the second shaft is adapted to be driven by a second turbine (390) mechanically coupled to the fan via the second shaft to drive the fan. The system of claim 8, wherein the second turbine is pneumatically coupled to the compressor inlet.

The system of claim 8, wherein the second turbine is pneumatically coupled to the inlet of the air conditioning unit (10, 210, 310).