US 12,168,955 B2
Constant-volume combustion system with synchronized injection
Quentin Bouyssou, Moissy-Cramayel (FR); Guillaume Alain Taliercio, Moissy-Cramayel (FR); Christophe Nicolas Henri Viguier, Moissy-Cramayel (FR); and Daniel Mejia, Moissy-Cramayel (FR)
Assigned to SAFRAN, Paris (FR); and SAFRAN.HELICOPTER ENGINES, Bordes (FR)
Appl. No. 17/596,864
Filed by SAFRAN, Paris (FR); and SAFRAN HELICOPTER ENGINES, Bordes (FR)
PCT Filed Jun. 11, 2020, PCT No. PCT/FR2020/050994
§ 371(c)(1), (2) Date Dec. 20, 2021,
PCT Pub. No. WO2020/254743, PCT Pub. Date Dec. 24, 2020.
Claims priority of application No. 1906729 (FR), filed on Jun. 21, 2019.
Prior Publication US 2022/0316393 A1, Oct. 6, 2022
Int. Cl. F02C 5/12 (2006.01)
CPC F02C 5/12 (2013.01) [F05D 2220/323 (2013.01); F05D 2240/35 (2013.01)] 6 Claims
OG exemplary drawing
 
1. A constant volume combustion system for a turbomachine comprising a plurality of combustion chambers distributed annularly about an axis, each combustion chamber comprising an enclosure, wherein the enclosure is parallelepiped shape, and wherein the enclosure includes a first surface with an inlet orifice and an outlet orifice and the enclosure includes a second surface opposite the first surface and the second surface includes a cavity at the center of the second surface, a selective shut-off element movable in rotation about the axis relative to the combustion chambers, the selective shut-off element comprising a shroud facing the inlet and outlet orifices of the combustion chambers, the shroud including on a first annular portion at least one intake aperture intended to cooperate with the inlet orifice of each combustion chamber during the rotation of the selective shut-off element and on a second annular portion at least one exhaust aperture intended to cooperate with the outlet orifice of each combustion chamber during the rotation of the selective shut-off element, wherein each combustion chamber comprises a fuel injection device connected to a fuel supply circuit, wherein the fuel injection device includes a protrusion extending radially outward from the center of the second surface of the enclosure and wherein the fuel supply circuit is connected to a surface of the protrusion, each fuel injection device being operated between a closed position in which the fuel injection device prevents fuel injection in a combustion chamber from the fuel supply circuit and an opened position in which the fuel injection device allows fuel injection in a combustion chamber from the fuel supply circuit, the shut-off element controlling the operation of each fuel injection device between the opened position and the closed position, wherein each fuel injection device includes an injection valve, a return spring, and a rocker arm, wherein the injection valve is housed in the protrusion extending from the second surface of the parallelepiped shaped enclosure and is parallelepiped shape, and wherein a portion of the injection valve extends outside of the protrusion, and wherein the injection valve includes a casing including a hole on a surface of the casing of the injection valve, and wherein when the fuel injection device is in the open position, the fuel supply circuit is in communication with the hole on the surface of the casing of the injection valve and fuel is injected through the injection valve and through the opening of the second surface of the enclosure, and wherein an axial length of the opening of the second surface of the enclosure is less than an axial length of the injection valve, wherein the return spring is housed in the protrusion extending from the second surface of the enclosure and is positioned between the injection valve and the opening of the second surface of the enclosure, and wherein the rocker arm includes a finger and a rocker arm rod, wherein the finger includes a free end connected to a radially outermost surface of the injection valve and, wherein the finger is pivotally mounted about an axis and connected to the rocker arm rod, and wherein the constant volume combustion system comprises an aerodynamic injection device configured to supply fuel to each combustion chamber when aligned with at least one intake aperture of the shut-off element, wherein the aerodynamic injection device is in a same radial position when the at least one intake aperture of the shut-off element is aligned with the inlet orifice of at least one combustion chamber and when the at least one intake aperture of the shut-off element is not aligned with the inlet orifice of at least one combustion chamber.