EP3758823A1

EP3758823A1 - Reduction of contrails during operation of aircraft

Info

Publication number: EP3758823A1
Application number: EP19714307.6A
Authority: EP
Inventors: Hermann Klingels
Original assignee: MTU Aero Engines AG
Current assignee: MTU Aero Engines AG
Priority date: 2018-03-02
Filing date: 2019-02-27
Publication date: 2021-01-06
Also published as: US20210001269A1; US11904272B2; DE102018203159A1; DE102018203159B4; WO2019166040A1

Abstract

Disclosed is a method for reducing contrails during operation of an aircraft (100, 100') having a heat engine (10). The method comprises: bringing about condensation of the moisture contained in the exhaust gas (A) of the heat engine by mixing at least part of the exhaust gas with ambient air (U) of the aircraft and separating the condensed-out water on the aircraft. Further disclosed is an aircraft (100, 100') having a heat engine (10). The aircraft comprises at least one nozzle (30), which is designed to guide at least some exhaust gas (A) out of the heat engine of the aircraft into ambient air (U) of the aircraft and thus generate a gas mixture, and at least one separating device (40) for separating condensed-out water out of the gas mixture.

Description

Reduction of contrails when operating aircraft

description

The present invention relates to a method for reducing contrails in the operation of aircraft with heat engine. The invention further relates to an aircraft with a heat engine.

Many aircraft are powered by heat engines in combination with suitable propulsion engines (propulsors). Propulsion and blowers (which are also referred to as "fans") used as propulsion generators, also contributes to the

Exhaust jet from the heat engine for propulsion at.

The most widely used heat engines are gas turbines and piston engines (reciprocating pistons, rotary pistons), the latter being used today only in relatively small aircraft.

Currently, almost exclusively fossil fuels are used as energy sources. There were also experiments with liquid hydrogen or liquid natural gas. Burning these fuels creates undesirable environmental impacts that contribute to climate change:

The burning of fossil fuels produces mainly carbon dioxide (C0 ₂ ) and water (H ₂ 0); In addition, however, nitrogen oxides (NO _x ), sulfur oxides (SO _x ), unburned hydrocarbons (C _x H _y ) carbon monoxide (CO) etc. can be found in the exhaust gas. When using hydrogen mainly water and because of the high process temperatures and nitrogen oxides (NO _x ) are produced.

The water present in the exhaust gas generates contrails under certain conditions. These are formed when the warm, moist exhaust gas mixes with colder ambient air.

The impact of contrails and the resulting cirrus clouds on global climate change is a controversial issue among experts. Many professionals think that the impact of contrails is more similar - if not more

CONFIRMATION COPY larger - is important than the C0 ₂ emissions of aircraft and that contrails thus have a significant share in the climate impact of all air traffic.

For dehumidifying exhaust gas streams of a gas turbine engine, US Pat. No. 7,971,438 B2 proposes a system of several heat exchangers (recuperators) with which water vapor present in the exhaust gas is at least partially condensed out.

The recuperators are pure gas / gas heat exchangers. Since these are to work at low pressure and also with low temperature differences, they must be a big one

Have volume. The usable heat exchangers are therefore heavy and also generate large pressure losses. In particular, this is the fuel consumption of the

Aircraft increased.

The present invention is based on the technical problem of a technique

to provide, with the formation of contrails in the operation of aircraft can be reduced while avoiding the disadvantages mentioned.

The object is achieved by a method according to claim 1 and an aircraft according to claim 7. Advantageous embodiments are in the subclaims, the

Description and the figures disclosed.

An inventive method serves to reduce contrails in the operation of aircraft with heat engine. It involves causing condensation of moisture contained in the exhaust of the heat engine by mixing at least a portion of the exhaust with ambient air from the aircraft (ie, at least partially circulating around the aircraft or flowing along a surface of the aircraft). The condensed water is deposited on the aircraft, for example on an outer surface or at least partially within a cavity of the aircraft.

An aircraft according to the invention comprises a heat engine and at least one nozzle, which is adapted to exhaust gas arising during operation of the aircraft from the exhaust gas

Heat engine at least partially in ambient air of the aircraft to initiate and to produce a gas mixture; Preferably, the at least one nozzle (which may in particular be a Kemtriebwerksdüse) in the operation of the aircraft at least partially from the Surrounding air flows around and / or arranged to emit the exhaust gas in the flow direction of the ambient air. An aircraft according to the invention also has a

Separating device for separating condensed water from the gas mixture. In particular, the aircraft is suitable for carrying out a method according to the invention in accordance with one of the embodiments disclosed in this document.

The inventive mixing of the exhaust gas with the ambient air (which has a lower temperature than the exhaust gas) allows effective cooling of the exhaust gas with the simplest means, in particular without large or heavy heat exchanger in the

Aircraft integrated and must be mitgefuhrt with this. The moisture contained in the exhaust gas can be cooled in this way below the dew point at which the relative humidity is 100% and thus saturation is reached; Below the dew point, condensation nuclei (such as dust, soot particles and / or electrically charged molecules) produce microscopically small water droplets.

Preferably, the separated condensed water is collected, for example by means of a gutter of the aircraft. From there, the water can by means of a

Be sucked condensate pump. At least a portion of the water may then be left overboard by a drain, and / or at least a portion of the water may be supplied to a water treatment and thereafter to the heat engine; in the latter case, for example, the water may be at least partially injected into the combustion chamber and / or at least partially fed to a steam generator, which may be adapted to generate heat from the water using exhaust gas. On

Aircraft according to the invention may accordingly comprise a collecting gutter, condensate pump, discharge, water treatment device and / or a steam generator designed for said functions.

The mixing may be at least partially on an outer surface of the aircraft

(In particular, take place in a forming on the aircraft (fluid dynamic) boundary layer), flows along the at least a portion of the ambient air. The surface may be arranged, for example, on the fuselage, on a wing, a tail unit or an engine nacelle of the aircraft. Such a surface can be arranged behind the heat engine, with reference to an intended direction of flight, so that the exhaust gas, after it has left the engine

Heat engine flows directly to the surface.

Alternatively or additionally, according to an advantageous embodiment of a

According to the invention at least a portion of the exhaust gas are passed through a conduit system to such, overflowed by ambient air surface; In this way, it is possible, for example, to utilize a surface structure which is particularly advantageous for mixing and / or separation and / or, if necessary, collecting.

Such a conduit system preferably discharges into a nozzle (e.g., a nuclear engine nozzle) through which the exhaust (or a portion thereof) may be discharged for mixing (preferably in the direction of flow of ambient air); the nozzle is preferably arranged so that it is at least partially flowed around by the ambient air during operation. Accordingly, an aircraft according to the invention may comprise such a conduit system, at the end of which the at least one nozzle may be arranged.

In particular, by means of such a conduit system, the exhaust gas, for example, at several different locations (eg on the fuselage and at least one of the wings, or at the top and bottom of at least one blade) passed to the aircraft and thus widely distributed, so that a particularly advantageous mixing ratio with a large proportion of cool ambient air: and a relatively small proportion of hot exhaust gas can be achieved.

According to an advantageous embodiment of a method according to the invention, the mixing takes place at least partially in one of at least part of the ambient air:

flowed through, formed in the aircraft mixing channel; accordingly one can

Flight device according to the invention for this purpose have such a mixing channel in which the at least one nozzle can be arranged and / or in which it can be directed.

Such a mixing channel may have a variable inlet opening, by means of which an inflow of ambient air may be adjustable. A method according to the invention can accordingly adjust the inflow by influencing such a variable

Include inlet opening, for example, depending on a respective current power of the heat engine and / or a temperature of the ambient air. This way you can a mixing ratio which is advantageous for the condensation can be achieved while avoiding a high flow which complicates the separation and / or collection of the separated water. An aircraft according to the invention may comprise a corresponding actuation and control unit for setting such a variable intake opening.

A supply of the exhaust gas (or a portion of the exhaust gas) from the engine to the mixing duct can be effected by a conduit system; An aircraft according to the invention may accordingly comprise such a pipeline system.

The precipitation of the condensed water may comprise centrifugal separation and / or centrifugation of at least a portion of the condensed water droplets, wherein in each case the exhaust gas and / or the gas mixture can be set in rotation; an aircraft according to the invention can according to at least one device for

Centrifugal separation and / or centrifugation of at least part of the

condensed water include.

According to an advantageous embodiment of a method according to the invention, the separation of the condensed water comprises an electrostatic charging of water molecules in the exhaust gas and a steering of at least part of the charged condensed out

Water droplets to a (charging) complementary pole out (which then preferably acts as a collecting electrode). The charging can, for example, by means of a

Spray electrode for Stoßionisation or to carry out a corona charging done. In this way, the electrostatic forces can guide the resulting water droplets and thus facilitate a removal of the water, for example by means of a gutter from which the water - as mentioned above - can be sucked off. In

Embodiments in which, as described above, the mixing takes place at least partially on an outer surface of the aircraft, at least a portion of this surface may be formed as a precipitation electrode (that is to say correspondingly electrically charged); so a movement of the water droplets can be effected towards the surface.

Accordingly, an aircraft according to the invention may preferably comprise a device having a first pole for electrostatically charging water molecules in the exhaust gas and a second (for the first) complementary pole (eg, a precipitation electrode) for attracting at least a portion of the charged condensed water droplets. The first Pol can be formed, for example, as a spray electrode for impact ionization or for carrying out a corona charging. According to an advantageous embodiment, the first pole is arranged inside the at least one nozzle. But the first pole can also be

be arranged downstream of the nozzle.

In embodiments in which the at least one nozzle is directed towards an outer surface overflowed by at least part of the ambient air during operation of the aircraft, at least a portion of this surface can, analogously to the above, cover the second pole (the

Precipitation electrode).

In the following preferred embodiments of the invention will be explained in more detail with reference to drawings. It is understood that individual elements and components can be combined differently than shown. Reference numerals for corresponding elements are used across figures and may not be rewritten for each figure.

They show schematically:

FIG. 1 shows a first exemplary embodiment of an aircraft according to the invention; and FIG. 2 shows a second exemplary embodiment of an aircraft according to the invention.

FIG. 1 schematically shows the first exemplary embodiment of an aircraft 100 according to the invention. The aircraft, which is particularly suitable for carrying out a method according to the invention, comprises a heat engine 10 for driving the aircraft 100 as well as a conduit system 31, which is illustrated schematically in the figure, for this purpose

is arranged to direct exhaust gas A from the heat engine to a nozzle 30.

In the illustrated operation of the aircraft (in the region of an interface), the nozzle 30 is at least partially surrounded by ambient air U and adapted to discharge the exhaust gas A passed through it in the direction of flow of the ambient air U at a surface 20 which is overflowed by the ambient air the along so the

Ambient air flows). The exhaust gas A and the respective part of the ambient air U

thus mixing on the surface 20. The resulting gas mixture then flows along the surface 20 on. The inventive mixing of the exhaust gas A with the ambient air U allows an efficient cooling in the exhaust gas contained moisture below the dew point, without the aircraft has to be equipped with heavy and bulky special devices such as (in the present application effective) heat exchangers. The saturation vapor pressure in the gas mixture drops more than the cooling due to the cooling

Partial pressure of the water, it comes to supersaturation and there are so-called condensation nuclei (for example on dust and / or soot particles and / or on electrically charged molecules) fine water droplets W.

The aircraft 100 further comprises a separation device 40, which in the present case comprises a spray electrode 41 for charging the water molecules according to the corona charging process (impact ionization) and a collecting electrode 42 which extends along the surface 20 as a result of an applied pole complementary to the discharge electrode , The electrostatic forces cause movement of the water droplets W toward the surface where they touch the surface 20 farther downstream and then e.g. be directed into a gutter 50.

Alternatively or additionally, the separation device of an inventive

Aircraft comprise a device for centrifugal separation and / or centrifugation of at least a portion of the condensed water (not shown).

The illustrated example of an aircraft 100 according to the invention also has a

Condensate pump 51, which is adapted to suck the water thus separated from the gutter 50. The water can then be left overboard directly by means of a drain 52 and / or at least part of the water can be one

Water treatment 53 and then - by a (schematically illustrated in the figure) channel system 54 through - the heat engine 10 to be supplied. There, the water can for example be injected directly into the combustion chamber of the heat engine, or it can be fed to a steam generator (not shown), which uses the exhaust heat of the heat engine to generate steam.

FIG. 2 schematically shows an aircraft l00 'according to an alternative embodiment of the present invention. In contrast to the aircraft 100 illustrated in FIG. 1, the nozzle 30 of the aircraft 100 'is arranged inside a mixing channel 60. The aircraft Partially (namely upstream of the nozzle upstream) overflowing ambient air (preferably from an interface) flows through the channel 60 and is mixed with exhaust gas A.

An inlet opening 61 of the mixing channel is variable by means of a flap 62 (and preferably an associated actuation and control unit, not shown), so that an inflow of ambient air U into the mixing channel 60 can be set, for example, depending on a respective current output of the heat engine and / or a temperature of the ambient air U.

As in the example shown in FIG. 1, the nozzle 30 of the aircraft l00 'also has one

Spray electrode 41 'for the electrostatic charging of water molecules in the exhaust gas. An associated collecting electrode 42 'of the aircraft 100' is in the present

Embodiment formed as part of a channel wall of the mixing channel 60, to which the water droplets W are deflected due to the electrostatic forces. The water thus separated is collected and removed analogously to the case shown in FIG.

Disclosed is a method for reducing contrails in the operation of an aircraft 100, 100 'with heat engine 10. The method comprises inducing a

Condensation of moisture contained in the exhaust gas A of the heat engine by mixing at least a portion of the exhaust gas with ambient air U of the aircraft and a separation of the condensed water on the aircraft.

Also disclosed is an aircraft 100, 100 'with a heat engine 10. The aircraft comprises at least one nozzle 30, which is adapted to exhaust A from the

Heat engine of the aircraft at least partially in ambient air U of the aircraft to conduct and so to produce a gas mixture, and at least one separation device 40 for separating condensed water from the gas mixture. reference numeral

10 heat engine 20 surface of the aircraft

30 nozzle

31 line system 40 deposition device

41, 4 G spray electrode

42, 42'filling electrode

50 gutter

51 condensate pump

52 derivative

53 Water treatment

54 duct system 60 mixing duct

61 variable inlet opening

62 adjustable flap

100, 100 'aircraft

A exhaust

U ambient air

W condensed water droplets

Claims

claims

A method for reducing contrails when operating an aircraft (100, 100 ') with heat engine (10), comprising:

- causing condensation of moisture contained in the exhaust gas (A) of the heat engine by mixing at least part of the exhaust gas with ambient air (U) of the aircraft and

- Separating the condensed water on the aircraft.

2. The method of claim 1, wherein the mixing occurs at least partially on an outer surface (20) of the aircraft, along which flows at least a portion of the ambient air.

3. The method according to any one of claims 1 or 2, wherein the mixing takes place at least partially in a of at least a portion of the ambient air (U) flow through the mixing channel (60) in the aircraft.

4. The method of claim 3, comprising adjusting an inflow of ambient air (U) in the mixing channel (60) by influencing a variable inlet opening (61) of the mixing channel.

5. A method according to any one of the preceding claims, wherein the depositing comprises:

- Electrostatic charging of water molecules in the exhaust gas and directing charged condensed water droplets (W) to a complementary pole (42, 42 ') back and / or

- Centrifugal separation and / or centrifugation of at least one at least part of the condensed water.

6. The method according to any one of the preceding claims, which is a suction of the

separated water with a condensate pump (51).

7. aircraft (100, 100 ') with a heat engine (10), which further comprises: at least one nozzle (30), which is adapted to exhaust gas (A) from the heat engine of the aircraft at least partially in ambient air (U) to guide the aircraft and thus to produce a gas mixture, and

at least one separation device (40) for separating out condensed water from the gas mixture.

An aircraft according to claim 7, wherein the at least one nozzle (30) is adapted to exhaust gas (A) passed therethrough.

- At one in operation of the flight operation of at least part of the ambient air (U) overflowed outer surface (20) of the aircraft and / or

- In a in the operation of the aircraft by at least a portion of the ambient air (U) flowed through the mixing channel (60) into it

leave.

Aircraft according to one of claims 7 or 8, wherein the at least one

Separating device comprises:

a first pole (41) for electrostatically charging water molecules in the exhaust gas and a second, complementary pole (42, 42 ') for attracting charged condensed water droplets (W) and / or

a device for centrifugal separation and / or centrifugation of at least a portion of the condensed water.

10. An aircraft according to any one of claims 7 to 9, further comprising at least one collecting channel (50) for separated water and / or a condensate pump (51) for sucking off separated water.

11. An aircraft according to any one of claims 7 to 10, which is adapted to carry out a method according to any one of claims 1 to 6.