A G-suit, or the more accurately named anti-G suit, is a flight suit worn by aviators and astronauts who are subject to high levels of acceleration force ('g's). It is designed to prevent a black-out and G-LOC (g-induced Loss Of Consciousness) caused by the blood pooling in the lower part of the body when under acceleration, thus depriving the brain of blood.[1] Black-out and G-LOC has caused a number of fatal aircraft accidents.[2]
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If blood is allowed to pool in the lower areas of the body, the brain will be deprived of blood, leading to temporary hypoxia. Hypoxia first causes a greyout (a dimming of the vision), also called brownout, followed by tunnel-vision and ultimately complete loss of vision 'blackout' followed by g-induced Loss Of Consciousness or 'G-LOC'. The danger of G-LOC to aircraft pilots is magnified because on relaxation of g there is a period of disorientation before full sensation is re-gained. A G-suit does not so much increase the g-threshold, but makes it possible to sustain high G longer without excessive physical fatigue. The resting g-tolerance of a typical person is anywhere from 3-5 g's depending on the person. A G-suit will typically add 1 g of tolerance to that limit. Pilots still need to practice the 'g-straining maneuver' that consists of tensing the abdominal muscles in order to tighten blood vessels so as to reduce blood pooling in the lower body. High g is not comfortable, even with a G-suit. In older fighter aircraft, 6 gs was considered a high level, but with modern fighters nine or more gs can be sustained structurally making the pilot the critical factor in maintaining high maneuverability in close aerial combat.
A G-suit is a special garment and generally takes the form of tightly-fitting trousers, which fit either under or over (depending on the design) the flying suit worn by the aviator or astronaut. The trousers are fitted with inflatable bladders which, when pressurized through a g-sensitive valve in the aircraft or spacecraft, press firmly on the abdomen and legs, thus restricting the draining of blood away from the brain during periods of high acceleration. In addition, in some modern very high-g aircraft, the Anti-g suit effect is augmented by a small amount of pressure applied to the lungs (partial pressure breathing), which also enhances resistance to high g. The effects of anti-G suits and partial pressure breathing are straightforward to replicate in a simulator, although the continuous g forces themselves can only be produced artificially in devices such as centrifuges.
Various designs of G-suit have been developed. They first used water-filled bladders around the lower body and legs. Later designs used air under pressure to inflate the bladders. These G-suits were lighter than the fluid-filled versions and are still in extensive use. However, the Swiss company Life Support Systems AG and the German Autoflug GmbH collaborated to design the new Libelle suit for use with the Eurofighter Typhoon aircraft, which reverts to liquid as the medium and improves on performance. The Libelle suit is under consideration for adoption by the United States Air Force.[3]
As early as 1917, there were documented cases of pilots' loss of consciousness due to G-forces (G-LOC) that were referred to as "fainting in the air".[4][5]
In 1931 a professor of physiology, Frank Cotton, from the University of Sydney described a new way of determining the center of gravity of the human body. This made it possible to describe the displacement of mass within the body under acceleration.
With the development of higher speed monoplane fighters in the late 1930s, acceleration forces during combat became more severe.[5][6] As early as 1940 some German aircraft had foot-rests above the rudder pedals so that the pilot's feet and legs could be raised during combat in an attempt to minimize the negative effects of high speed turns. Large rudder deflections were often not necessary during such manoeuvres, but being able to cut inside the opponent's turning radius was.
The first G-suits were developed by a team led by Wilbur R. Franks at the University of Toronto's Banting and Best Medical Institute in 1941. These devices used water filled bladders around the legs and two 'Mk.' versions (or Marks) were developed:
In the United States, physiologists Drs. Earl H. Wood, Edward Baldes, Charles Code and Edward Lambert also contributed to the study and development of G-suits in the 1940s.[7]
The researchers were part of a team assembled at the Mayo Clinic investigating the effects of high performance flight on military pilots, by studying physiological effects of flight and how to mitigate them.[7] They used a large centrifuge to whirl riders and observe their blood pressures at the head and heart levels with special instruments.[7] To prevent drops in blood pressure, the team designed an air bladder suit that inflated at the pilot’s calves, thighs and abdomen.[7]
Their efforts finally culminated with the release of the first US military design in late 1943: the GPS (Gradient Pressure Suit) type fighter pilot's G-1 G-suit.[8] The team subsequently worked on developing further, more advanced models in 1944 and beyond.[8]
Although uncomfortable and distracting to use, later research showed that military fighter pilots who wore G-suits survived and defeated their opponents in greater numbers than those who didn't.[7]
Modern G-Suits meet the United States Air Force Standard CSU-13B/P and United States Navy Standard CSU 15 A/P. Manufactured for over 15 years by Derm-Buro, known commercially as G-Forces Manufacturing, the modern G-Suit can withstand hundreds of missions without failure.
During World War II the German's Henschel Hs 132 jet and US's XP-79 Flying Ram both had prone positions to minimize blood pooling in the legs. After 1945 the British experimented with prone flying positions in a highly modified Gloster Meteor F8 fighter. However, other difficulties associated with prone piloting and the development of practical g-suits for normal seating positions terminated these experiments.
Air-based G-suits were very common in NATO aircraft of all nations from the 1950s onwards and are still in common use today.
Later jets such as the F-15 Eagle, F-16 Fighting Falcon, F/A-18 Super Hornet, Eurofighter Typhoon and the Dassault Rafale can sustain high G loads for longer periods, and are therefore more physically demanding. However, by using a modern G-suit in combination with anti-G strain techniques, a pilot can now be expected to sustain flight forces of up to nine Gs without blacking out.
Astronauts wear G-suits similar to aviators but face different challenges due to the effects of microgravity. Aviator G-suits apply uniform pressure to the lower legs to minimize the effects of high acceleration but research from the Canadian Space Agency[9] implies there might be a benefit in having a suit for astronauts that uses a "milking action" to increase blood flow to the upper body.
Pilots in Red Bull Air Race World Championship wear G-suits called G-Race Suit since the 2009 season. The G-race suit is a liquid (water) filled, autonomous and aircraft independent working full-body G-protection system. It is tailor made for each pilot and can be fine adjusted via lacings. This G-race suit was adapted and tested by Red Bull Air Race GmbH in co-operation with Autoflug GmbH based on the multi patented Libelle G-Multiplus which is already in service in military fighter jets.
The G-race suit contains four so-called "fluid muscles" that are liquid filled and sealed tubes. Each fluid muscle extends from the shoulder to the ankle. Two fluid muscles – each filled with app. 1 litre of fluid (total of app. 4 litres/ app. 1 US Gallon per G-race suit) - are routed vertically on the front side of the G-race suit and two are routed vertically on the rear side of the G-race suit. It weighs on average app. 6.5 kg/ 14 lbs in total and its fabric is made out of a special mix of Twaron and Nomex. The counter pressure effect occurs instantaneously without any time delay versus standard pneumatic, inflatable G-suits have an up to 2 second time delay before reaching full system protection. The race pilot utilizes the G-race suit interactively by muscle straining and breathing techniques to achieve an improved cardiac output and thus improved G-protection.[10]