DE3327740A1 - PUSH AMPLIFIER FUEL CONTROL SYSTEM - Google Patents

Description

Booster fuel regulation system

The invention relates to thrust boosters for gas turbine engines and, more particularly, relates to fuel control systems for such boosters.

Gas turbine engine thrust boosters typically contain a plurality of fuel spray tubes in the form of themselves radially extending rods or of concentric rings, which in the exhaust duct a short distance upstream are arranged by one or more flame holders. The spray tubes have each regardless of their shape several openings with either a fixed or a variable cross-section through which the fuel enters the gas flow is sprayed. Variable area fuel outlet openings in spray tubes are generally shown in FIG expensive to manufacture and therefore undesirable.

In known thrust amplifier systems, individual

Spray pipes or groups of spray pipes separate shut-off valves, which can be opened in a special order for ignition and other modes of operation of the booster to facilitate. There are several of these spray tubes or groups of spray tubes supplied with fuel from a common distribution line. A single main valve controls the whole Fuel supply to the distribution line. The fuel flow rate or output in the openings in the individual spray tubes connected to the distribution line is a function of the pressure drop across the openings, which is a function of the back pressure of the system is. During stationary operation the back pressure is essentially constant, and the flow rates in the spray tubes are steady and predictable. During initiation during boost booster and during boost booster transitions, the shut-off valves are in turn after opened, and the main fuel supply valve will opened to add more fuel overall to the distribution line according to a suitable schedule. Since the Brenn Material flow rate with which the fuel flows out of each spray tube, depends on the back pressure there is a sudden change every time another shut-off valve is opened back pressure resulting in a sudden decrease, a sudden increase or a sudden fluctuation the fuel feed speed in the spray tubes, in which fuel is already flowing, leads. The total fuel supply to the distribution line is thus Although controlled by the main valve, the distribution of the fuel supply to the spray tubes during transients is uncertain.

The object of the invention is to provide an improved fuel control system for a gas turbine engine boost booster to accomplish.

It should also be possible to switch individual thrust booster spray devices on and off, without affecting the flow rate in other boost booster sprayers is adversely affected in the system.

Furthermore, the fuel control system should be able to the fuel flow rate in detail To change spray tubes without fuel outlet openings of variable cross-section in the spray tubes required are.

According to the invention, the boost booster includes a fuel control system a plurality of fuel spray devices upstream of a flame holder, the fuel outlet openings have fixed cross-section and with fuel from a common chamber via individual variable Metering cross-sections are supplied, a metering cross-section corresponding to each spray device and has its own pressure regulator which has a substantially constant pressure drop across the metering cross-section and each sprayer also has its own shut-off valve and control system Has means for opening and closing the shut-off valves.

Every thrust booster spraying device sees itself in this control system, which is associated with the common fuel chamber, a back pressure from the Back pressures that other spray devices, through which fuel flows through, are exposed to, facing. The shut-off valves of the individual spray devices can now be opened and closed as required, for example by opening the same in a predetermined sequence during the initiation of the thrust reinforcement or during subsequent thrust

Booster transitions without affecting the fuel flow rate is significantly affected in the spray devices that are already in operation. The fuel flow rate in each sprayer is a direct function of their corresponding one the metering cross-section.

An embodiment of the invention is described in more detail below with reference to the drawing.

The only figure in the drawing shows a boost booster fuel control system according to the invention.

As shown in the drawing, surrounds a gas turbine engine casing 6 a turbine exhaust duct 8 and an engine tail cone 10. The turbine exhaust duct 8 and the tail cone 10 delimit an annular turbine exhaust gas flow path 12 around the engine centerline 14. A thrust booster is designated as a whole by the reference number 16. The boost booster 16 has one Flame holders 18 and annular fuel spray tubes 20 (six of which are shown in this embodiment are) arranged upstream thereof in the gas flow path 12. Each ring 20 has several circumferentially spaced apart, nozzle-like openings 22 of fixed cross-section, which spray the fuel during the boosting of thrust. In In the drawing, the spray tubes are shown as rings, but they could also be simple to radial rods or the like. or a combination of bars and rings.

The flame holder 18 has a known structure. In the embodiment shown in the drawing has the flame holder three concentric, ring-shaped, im

Cross-section of V-shaped grooves 24 and a plurality of circumferentially spaced apart, V-shaped cross-section Grooves 26 extending radially inward and radially outward therefrom.

According to the invention, each spray ring 20 receives fuel via a separate fuel supply line 38. The supply lines 38 are supplied with fuel from a common chamber 40 of a fuel metering valve, which is designated as a whole by the reference number 42. In this embodiment the fuel metering valve has 42 an outer wall 44 having an inner cylindrical surface 46 and an inner hollow cylinder 48 having an outer cylindrical surface 50 concentric with the inner cylindrical surface 46 and is in sliding contact with it. The cylinder 48 has closed ends 49, 51 and delimits the aforementioned common chamber 40. Fuel from a fuel supply 52 passes into the common chamber 40 openings 54, 56 in the wall 44 and the cylinder 48, respectively. Each fuel supply line 38 is connected to the common Fuel chamber 40 via a corresponding pair of openings 58, 60 of fixed cross-section in the outer Wall 44 or the cylinder 48 in connection, these openings by moving the cylinder 48 relative to the surface 46 can be brought more or less into congruence. Thus, the metering cross-sections are variable 62 formed at the interfaces between corresponding openings 58,60.

Any suitable device can be used to determine the relative position of the openings 58, 60 and thus to control the size of the metering cross-sections 62. In the embodiment shown in the drawing, the Cylinder 48 with respect to the cylindrical surface 46 through a control valve 64 axially to the left and after

moved to the right, which receives control commands from a computer, which is not shown. A valve position sensor 65 provides a position feedback signal to the computer. In operation, a chamber 66 is on the right end of cylinder 48 filled with servo fluid, which is maintained at a constant servo supply pressure represented by a box 67. This creates a constant pressure on the right end 49 of the cylinder 48 maintained. To the left of the cylinder 48 is a piston 68 directly to the left end 51 of the cylinder 48 connected by an axle 70. A chamber 72 is located between the piston 68 and the Cylinder 48. The chamber is filled with servo fluid, which is held at a constant servo exhaust pressure, which is represented by a box 74 and is considerably lower than the servo supply pressure 67 is. A chamber 76 is located to the left of the piston 68 and is filled with servo fluid, the pressure of which is between the supply pressure 67 and the discharge pressure 74 can be changed with the aid of the control valve 64. Thus, by controlling the pressure of the fluid in chamber 76, cylinder 48 can move left or right be moved to the metering cross sections 62 as required to change.

The metering cross-sections 62 can also be changed, by rotating the inner cylinder relative to the outer wall. In addition, other types of Metering valves are used in the control system according to the invention, the several variable metering cross-sections which flow into a common chamber.

Furthermore, according to the invention, each fuel supply line is 38 is assigned a separate shut-off valve 100. To initiate the thrust reinforcement will be these valves are opened in a predetermined order by a control device 102 which has any

known structure (electrical, hydromechanical, etc.). The controller 102 is also used to open and close the valves 100 so further boost booster modes of operation can be achieved.

Each fuel supply line 38 is a pressure regulating valve 104 assigned, that between the feed line metering cross-section 62 and the corresponding shut-off valve 100 is arranged. Each valve 104 nearly holds you constant pressure drop across the metering cross-section 62 with which it is associated. Pressure regulating valves of this type are known. Each pressure regulating valve 104 is supplied with a working fluid that is the same The same pressure as the fuel in the common chamber 40. In the control system shown, this is working fluid Fuel coming from the common chamber 40 to the fuel control valves 104 via a system of conduits 106 is fed. In the invention it is not necessary that the pressure drop across each metering cross section 62 is the same.

In the boost booster fuel control system according to the invention thus becomes the fuel pressure drop across each Metering cross-section 62 regulated independently of the pressure drop across the other metering cross-sections 62. To be there- or switching off a spray ring 20 with the aid of its shut-off valve 100, for example during the sequence control the spray rings 20, has no effect on the fuel flow rate to others Rings 20. The rate of fuel supply to each spray ring 20 depends solely on the size of the Metering cross-section 62 depending on which this spray ring is assigned, and on the value of the pressure drop, which at the metering cross section 62 is maintained. The speed the fuel supply to the common

40 ·

Chamber 40 is the sum of the individual fuel supplies or -flows, which at the individual metering cross-sections 62 are maintained. Each time an additional spray ring is opened during the sequence control additional fuel is supplied from the fuel supply 52 to the common chamber 40 in order to a constant flow through the already open valves 100 as well as through the valve 100, which is newly opened will ensure.

According to the drawing, the fuel supply line delivers Although 38 fuel to a single spray ring 20, each fuel supply line 38 could equally well Fuel to a group of spray rings or spray sticks, or a combination of rings and Provide rods, depending on the particular structure of the thrust amplifier with which the control system according to the invention connected is. The boost booster fuel control system of the invention is for such an arrangement equally well suited.

Claims (3)

Patent claims: MJ Booster Fuel Control System for a Gas Turbine Engine, which has an exhaust gas duct (8) with a flame holder (18) arranged therein, characterized by a plurality of spray tubes (20) placed in the exhaust duct (8) upstream of the flame holder (18) are arranged and each have a plurality of openings (22) through which the fuel enters the exhaust gas duct (8) is sprayed, by a fuel metering valve (42) with a device (48), which contains a common fuel chamber (40) and several separate, variable fuel metering cross-sections (62), each of which corresponds to one of the spray tubes (20), and a flow connection between the common fuel chamber (40) and the Produces spray tubes (20), by a fuel supply device (52), which with the common fuel chamber (40) is in communication, by pressure regulating devices (104) which are assigned to the spray tubes (20) and the fuel metering valve (42), a substantially constant pressure drop across each Maintain metering cross-section (62) through several shut-off valves (100), each of which one corresponds to one of the spray tubes (20) to cut off the fuel supply from the fuel metering valve (42) interrupt or allow the spray lance corresponding to the shut-off valve, and by a control device (102) assigned to the shut-off valves (100) for opening and closing the same is. 2. Control system according to claim 1, characterized in that the spray tube openings (22) openings of fixed cross section are. 3. Control system according to claim 1 or 2, characterized in that the fuel metering valve (42) has a first Wall (48) defining the common fuel chamber (40) and an "outer cylindrical surface (50) and a second wall (44) having an inner cylindrical surface (46) which extends from the second Wall is surrounded, the inner and the outer cylindrical wall surface concentric and on top of one another are displaceable, wherein the second wall (44) has a first number of through openings (58) and the first Wall (48) a second number of through openings (62) and wherein the walls are movable with respect to one another so as to provide the first and second openings can be brought into congruence with one another in order to form the metering cross-sections (62), and that the regulating device (64), which is assigned to the metering valve (42), devices (65, 67, 74) for controlling the relative movement of the first and the second wall for changing the metering cross-sections (62).