Reducing fuel consumption through operational measures

Basic cabin equipment is made lighter, e.g. lighter aircraft seats or lighter freight containers. Fuel calculation is refined to ensure that the aircraft does not carry a single excess tonne of fuel, other than its reserve fuel. On long-haul flights, every avoidable tonne reduces fuel consumption disproportionately.

Freight weights are optimally distributed. Larger aircraft pump fuel back and forth between the tanks on the main wings and the tail fin during flight in order to keep the aircraft in a flight attitude that minimises drag when cruising, without having to adjust the control surfaces. This is also done when passengers or crew move back and forth in the aircraft.

Even if an aircraft can reach high speeds at high altitudes with relatively little propulsion power thanks to low air density, the laws of physics still apply. Specifically, this means that a small increase in the normal cruising speed requires a lot of additional power. Whether it is a plane in the air, a car on the motorway or a train on a high-speed rail line, 10% more speed requires 30% more propulsion power. So increasing speed to make up time is inefficient in terms of fuel and energy consumption. Conversely, even a small reduction in cruising speed can save an airline a significant amount of fuel. The cruising speed is therefore reduced slightly and an acceptable balance is sought between passenger requirements (journey time, arrival time) and fuel consumption.

European airspace is highly fragmented. In addition, political factors such as the war in Ukraine are lengthening flight routes. The Single European Sky project aims to optimise the use of Europe’s airspace.
Climbs and descents harbour further potential. For example, passenger jets can cover the last 200km of their route with the engines idling, without the need to repeatedly generate thrust. In an optimum approach, a jet descends to its destination like a glider.

Previously, aircraft on long-haul flights landing at Zurich sometimes had to fly holding pat-terns if they arrived at too close intervals or before the airport opened at 6am. That is no longer the case thanks to iStream, an initiative by the airline SWISS, the air navigation ser-vice provider Skyguide and the airport operator Flughafen Zürich AG. Now, a time slot is re-served for each flight in the wave of early-morning arrivals at Zurich Airport. From then on, a minute-by-minute calculation is performed, factoring in the economical cruising speed, the weather and the route. The departure time for these flights is then adjusted accordingly. If there is a strong tailwind on flights from North America to Switzerland, take-off is delayed so that the flight does not arrive in Zurich before 6am and can keep to its landing slot. This op-timised procedure has cut the number of holding patterns at Zurich by 96% and shortened the approach routes by around 30%, thereby reducing kerosene consumption and CO2 emis-sions. iStream is now being rolled out to other airlines and European airports.

Weather forecasts have become very accurate, especially those for high-altitude winds. Modern flight management systems allow these winds to be better exploited.