Self-adapting gas turbine firebox with variable geometry

The invention claimed is: 1. A self-adapting gas turbine firebox with variable geometry, comprising: a combustion chamber ( 101 ); an air supply system for supplying air exiting a compressor ( 200 ), arranged to supply the combustion chamber ( 101 ) with the air having a variable temperature; and at least one system with a variable opening, comprising: an intake passage, arranged to allow the air coming from the air supply system to enter the combustion chamber ( 101 ), a movable closure member, which changes an open cross-sectional area of the intake passage when moved, and a thermosensitive member, having a shape which varies depending on a temperature of said thermosensitive member, the thermosensitive member being arranged in a stream of combustion air between the air supply system and the intake passage, and being connected to the closure member so that a deformation of the thermosensitive member causes said closure member to move, wherein the intake passage is arranged with respect to the combustion chamber ( 101 ) so that the combustion air entering said combustion chamber through said intake passage is air which participates in combustion of a fuel in the combustion chamber such that the turbine firebox is self-adapting for automatically adjusting a combustion configuration inside the combustion chamber according to an operational power setting of the turbine firebox, wherein the at least one system is arranged to vary an intake flow rate of the combustion air coming from the air supply system and entering the combustion chamber ( 101 ) through an air supply swirler ( 103 ), located axially upstream of said combustion chamber relative to a combustion chamber axis, and wherein the closure member comprises a ring ( 2 ) with openings ( 2 a ) which laterally surrounds the air supply swirler, so that the openings are aligned or offset relative to channels ( 103 a ) of said air supply swirler ( 3 ), in order to vary a cross-sectional area of an access to said channels according to an angular position of the ring around the air supply swirler, forming the open cross-sectional area of the intake passage. 2. The turbine firebox according to claim 1 , wherein the thermosensitive member comprises a portion made of a shape-memory alloy, or comprises a bimetal strip assembly, said bimetal strip assembly being composed of at least two portions ( 2 c 1 , 2 c 2 ; 7 1 ; 7 1 ) made of materials which have different respective values for a coefficient of thermal expansion, and which are connected to each other so that a relative dimensional variation of said two portions of materials, caused by a change in temperature undergone by the thermosensitive member, produces the deformation of said thermosensitive member. 3. The turbine firebox according to claim 2 , wherein the thermosensitive member is adapted to provide sufficient energy to cause the closure member to move from an initial position when said thermosensitive member undergoes a first change in temperature from an initial temperature value, and is also adapted to then provide additional energy which is sufficient to cause a reverse movement of the closure member when said thermosensitive member undergoes a second change in temperature following the first change in temperature and in the opposite direction to said first change in temperature so that the closure member is once again in the initial position when the temperature of the thermosensitive member is again equal to the initial value. 4. The turbine firebox according to claim 2 , wherein the thermosensitive member is adapted to provide sufficient energy to cause the closure member to move from an initial position when said thermosensitive member undergoes a first change in temperature from an initial temperature value, and the at least one system further comprises at least one return member adapted to produce additional energy which is sufficient to cause a reverse movement of the closure member when said thermosensitive member undergoes a second change in temperature following the first change in temperature and in the opposite direction to said first change in temperature so that the closure member is once again in the initial position when the temperature of the thermosensitive member is again equal to the initial value. 5. The turbine firebox according to claim 2 , wherein the at least one system is a first system, and the turbine firebox further comprises a second system with a second variable opening which is arranged to vary an intake flow rate of a stream of dilution air coming from the air supply system and entering the combustion chamber ( 101 ) through a side wall of said combustion chamber, said second system comprising: a second intake passage, arranged to allow the stream of dilution air coming from the air supply system to enter the combustion chamber ( 101 ), a second movable closure member, which changes an open cross-sectional area of the second intake passage when moved, and a second thermosensitive member, having a shape which varies depending on a temperature of said second thermosensitive member, the second thermosensitive member being arranged in the stream of dilution air between the air supply system and the second intake passage, and being connected to the second closure member so that a deformation of the second thermosensitive member causes the second closure member to move, wherein the second intake passage is arranged with respect to the combustion chamber ( 101 ) so that the stream of dilution air entering said combustion chamber through said second intake passage is air that participates in a dilution of the gases effective inside the combustion chamber, and wherein the first and second systems are adapted to simultaneously vary the open cross-sectional areas of the respective first and second intake passages in opposite variation directions when the temperature varies of the streams of air in which are arranged the first and second thermosensitive members. 6. The turbine firebox according to claim 1 , wherein the thermosensitive member is adapted to provide sufficient energy to cause the closure member to move from an initial position when said thermosensitive member undergoes a first change in temperature from an initial temperature value, and is also adapted to then provide additional energy which is sufficient to cause a reverse movement of the closure member when said thermosensitive member undergoes a second change in temperature following the first change in temperature and in the opposite direction to said first change in temperature so that the closure member is once again in the initial position when the temperature of the thermosensitive member is again equal to the initial value. 7. The turbine firebox according to claim 6 , wherein the thermosensitive member constitutes at least a portion of a blade ( 2 c ) which is carried by the ring ( 2 ), located in the stream of combustion air coming from the air supply system, and adapted to impart tilts or directions of curvature to the blade which are the inverse of one another, between at least two temperature values of the air coming from the air supply system, so as to rotate the ring by aerodynamic force in a first direction or in a second direction opposite to said first direction around the air supply swirler ( 103 ). 8. The turbine firebox according to claim 7 , wherein the at least one system is arranged to reduce the open cross-sectional area of the intake passage when the temperature of the air coming from the air supply system decreases, and to increase said open cross-sectional area of the intake passage when said air temperature increases. 9. The turbine firebox according to claim 6 , wherein the at least one syste