DEVICE AND METHOD FOR STARTING A GAS TURBINE, METHOD FOR REGULATING THE ROTATION SPEED OF A GAS TURBINE, AND ASSOCIATED GAS TURBINE AND TURBINE ENGINE

Abstract

The invention relates to a device for starting a gas turbine, comprising an initiation system able, on command, to rotate said gas turbine.

The starting device comprises means for receiving information representing the rotation speed of the gas turbine, means for calculating a set torque value according to said information representing the rotation speed of the gas turbine, and means for transmitting said set torque value to the initiation system, and the means for calculating the set torque value are suitable for making a comparison of the information representing the rotation speed of the gas turbine with a predetermined speed profile and calculating the set torque value from said comparison.

Claims

1. Device for starting a gas turbine, comprising an initiation system able to rotate said gas turbine on command, wherein it comprises: means for receiving information representing the rotation speed of the gas turbine, means for calculating a set torque value according to said information representing the rotation speed of the gas turbine, means for transmitting said set torque value to the initiation system, and in that the means for calculating the set torque value are suitable for making a comparison of the information representing the rotation speed of the gas turbine with a predetermined speed profile and calculating the set torque value from said comparison.

2. Starting device according to claim 1, further comprising: a fuel metering device suitable for injecting fuel into a combustion chamber of said gas turbine, means for calculating a set fuel metering value according to said information representing the speed, and means for transmitting the set fuel metering value to said fuel metering device, and in that the means for calculating the set fuel metering value are suitable for making a comparison of the information representing the rotation speed of the gas turbine with a predetermined speed profile and calculating the set fuel metering value from said comparison.

3. Starting device according to claim 1, wherein the means for receiving information representing the rotation speed of the gas turbine, the means for calculating the set torque value, the means for calculating the set fuel metering value, the means for transmitting the set torque value and the means for transmitting the set fuel metering value are contained in a control unit controlling said gas turbine.

4. Starting device according to claim 1, wherein said initiation system is able to rotate the gas turbine by means of a relay box.

5. Starting device according to claim 1, wherein said initiation system comprises an electrical machine able to rotate said gas turbine, and a system for controlling the electrical machine configured so as to receive said set torque value and to control the power supply to said electrical machine according to the set torque value.

6. Method for regulating the rotation speed of a gas turbine configured so as to be driven by an initiation system, wherein it comprises: a step of receiving information representing the rotation speed of the gas turbine, a step of comparing the information representing the rotation speed of the gas turbine with a predetermined speed profile, a step of calculating a set torque value from a result of said comparison, a step of transmitting said set torque value to the initiation system.

7. Regulation method according to claim 6, further comprising: a step of calculating a set fuel metering value from the result of said comparison, a step of transmitting the set fuel metering value to a fuel metering device suitable for injecting fuel into a combustion chamber of the gas turbine according to said set fuel metering value.

8. Method for starting a gas turbine, wherein the rotation speed of the gas turbine is regulated according to a regulation method according to claim 7, and in that it comprises, successively and in this order: a step (A) of starting the gas turbine by means of the initiation system, during which the set torque value is calculated so that the rotation speed of the gas turbine varies from a zero speed to a so-called ignition speed (Va), a step (B) of igniting the gas turbine, during which the set torque value is calculated so as to maintain the rotation speed of the gas turbine at the ignition speed until the fuel injected by the fuel metering device according to the set fuel metering value combusts, a step (C) of starting up the gas turbine, during which the set torque value and the set fuel metering value are calculated so as to increase the rotation speed of the gas turbine up to a so-called transition speed, a transition step (D), during which the set torque value is fixed and the set fuel metering value is calculated so as to increase the rotation speed of the gas turbine, a normal-regime step (E), during which the set torque value is zero and the set fuel metering value is calculated so as to vary the rotation speed of the gas turbine.

9. Gas turbine, comprising a starting device according to claim 1.

10. Turbine engine, comprising a gas turbine according to claim 9.

Description

5. LIST OF FIGURES

[0059] Other aims, features and advantages of the invention will emerge from a reading of the following description given solely non-limitatively and which refers to the accompanying figures, in which:

[0060] FIG. 1 is a schematic representation of a starting device according to an embodiment of the invention,

[0061] FIG. 2 is a schematic representation of a regulation method according to an embodiment of the invention,

[0062] FIG. 3 is a predetermined speed profile of a gas turbine started according to a starting method according to an embodiment of the invention.

6. DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION

[0063] The following embodiments are examples. Although the description refers to one or more embodiments, this does not necessarily mean that each reference relates to the same embodiment, or that the features apply only to one embodiment. Simple features of various embodiments may also be combined in order to provide other embodiments.

[0064] FIG. 1 shows schematically a device 10 for starting a gas turbine 12 according to an embodiment of the invention. The objective of the starting device 10 is to allow the starting of the turbine 12 when the latter is not rotating. In the absence of rotation, the gas in the turbine 12 cannot be burnt in order to rotate the turbine 12. Thus, to allow the starting of the turbine 12, an initiation system 14 is connected to the turbine in order to be able to trigger the rotation thereof. According to the embodiment depicted in FIG. 1, the initiation system 14 is composed of an electrical machine 18, for example an alternator, and a system 16 for controlling the electrical machine, for example an inverter. The system 16 for controlling the electrical machine provides the electrical power to the electrical machine 18 so that the latter can rotate the gas turbine 12, by means of a relay box 20.

[0065] To control the initiation system 14, the starting device 10 comprises means for applying a predetermined speed profile to the turbine 12. An example of such a predetermined speed profile is described later in the description with reference to FIG. 3. These means are in particular: [0066] means 22 for receiving information representing the rotation speed of the gas turbine 12. This information is for example transmitted by a sensor 24 for the rotation speed of the turbine 12. [0067] means 26 for calculating a set torque value according to said information representing the rotation speed of the gas turbine 12, in particular from a comparison between this information representing the rotation speed and the predetermined speed profile. These calculation means 26 make it possible to determine the set torque value that must be applied to the gas turbine 12 by the initiation system 14. [0068] means 28 for transmitting said set torque value to the initiation system 14, and more particularly to the system 16 for controlling the electrical machine. The system 16 for controlling the electrical machine is then responsible for controlling the electrical machine 18 through its electrical supply, in order to apply to the gas turbine 12 the torque corresponding to the set torque value transmitted.

[0069] In this embodiment, the starting device 10 also comprises a fuel metering device 30, which injects fuel into a combustion chamber 32 of the gas turbine 12. One type of fuel metering device 30 is for example an FMU (fuel metering unit). The fuel metering device 30 injects the fuel into the combustion chamber 32 of the gas turbine 12 so that the fuel is burnt, this combustion permitting the rotation of the gas turbine 12, in particular in normal operating regime, following starting.

[0070] To allow a suitable metering of fuel, the starting device 10 comprises means 34 for calculating a set fuel metering value according to the information representing the rotation speed of the gas turbine 12 and means 36 for transmitting the set fuel metering value to the fuel metering device. The set fuel metering value is calculated according to the rotation speed of the turbine, in particular from a comparison of this rotation speed of the turbine with the predetermined speed profile and the injection of fuel allows the combustion thereof in the turbine in order to provide an additional torque to the gas turbine, which is added to the torque provided by the initiation system 14.

[0071] In this embodiment, the means 22 for receiving the information representing the speed, the means 26 for calculating the set torque value, the means 34 for calculating the set fuel metering value, the means 28 for transmitting the set torque value and the means 36 for transmitting the set fuel metering value are contained in a single item of equipment, referred to as the control unit 38. This control unit 38 makes it possible to simultaneously control the initiation system 14 and the fuel metering device 30 to allow a more robust starting. This control unit 38 may further have more functionalities relating to the gas turbine 12, not described here. The equipment that can serve as a control unit 38 is for example an ECU (engine control unit), in particular a FADEC (Full Authority Digital Engine Control), which is equipment regularly used in the aeronautical field for use of the gas turbine 12 as a turbine of a turbine engine.

[0072] Furthermore, in this embodiment, the means 26 for calculating the set torque value and the means 34 for calculating the set fuel metering value are combined in the same item of computing equipment 40. This allows an adjustment between the two set values in order to obtain the required torque of the gas turbine 12 by combining the effects of the initiation system 14 and the fuel metering device 30.

[0073] FIG. 2 shows schematically a starting method 42 according to an embodiment of the invention. The method 42 is advantageously implemented by the device 10 described in relation to FIG. 1. The method 42 comprises a step 44 of receiving information representing the rotation speed of the gas turbine 12. This information is compared, during a comparison step 48, with a predetermined speed profile 46, as for example described with reference to FIG. 3. This comparison step 48 makes it possible to determine the difference between the actual rotation speed and the required rotation speed defined by the predetermined speed profile 46, and said determined difference then makes it possible, during a step 50 of calculating the set torque value and a step 52 of calculating the set fuel metering value, to determine the set torque value and the set fuel metering value according to the actual rotation speed and the required rotation speed of the turbine 12, and optionally according to a starting phase in which the turbine 12 is situated. In this embodiment, the two calculation steps 50, 52 are combined in a single step 54 in order to provide a more robust regulation using both the initiation system 14 and the injection of fuel by the fuel metering device 30 in order to provide the torque necessary for regulation of the speed.

[0074] The set torque value is transmitted to the system controlling the electrical machine during a step 56 of transmitting the set torque value. The system 16 controlling the electrical machine controls the electrical machine 18 according to this set value, which then applies a torque to the turbine 12 during a step 58 of applying the torque of the initiation system. The resulting torque is shown by the arrow 60.

[0075] Moreover, the set fuel metering value is transmitted to the fuel metering device during a step 62 of transmitting the set fuel metering value, which allows the injection of fuel into the combustion chamber of the gas turbine. The combustion of the gas makes it possible to apply a torque to the turbine 12 during a step 64 of applying the torque of the fuel metering device. The resulting torque is represented by the arrow 66.

[0076] The total torque applied to the turbine, represented by the arrow 68, is therefore the addition of the two torques coming from the initiation system 14 and the fuel metering device 30. This total torque makes it possible to rotate the turbine 12 at a certain speed, represented by the step 69, information representing which is received during the step 44 of receiving information representing the speed: the regulation method thus constitutes a closed regulation loop.

[0077] FIG. 3 shows a predetermined speed profile of a gas turbine started according to a starting method according to an embodiment of the invention. The predetermined speed profile represents the rotation speed V as a function of time t, according to two curves, a set speed value curve 72, representing the rotation speed that the turbine should theoretically follow, and the measured-speed curve 74 representing the rotation speed of the turbine 12 actually measured.

[0078] The predetermined speed profile 70 makes it possible to distinguish the various steps of a method for starting the gas turbine 12:

[0079] At the initiation step A, the initiation system 14 drives only the rotation of the gas turbine 12, the combustion of the gas in the turbine 12 not having begun.

[0080] The ignition step B ignites the gas injected into the combustion chamber 32 of the gas turbine 12 by the fuel metering device 30 in order to cause the combustion of the gas and to cause the rotation of the gas turbine 12. To provide effective ignition, the rotation speed of the gas turbine 12 is maintained at a so-called ignition speed Va.

[0081] At the step C of starting the gas turbine 12, the rotation speed of the turbine 12 increases progressively, mainly because of the action of the initiation system 14 and partly because of the combustion of the fuel injected. The set torque value and the set metering value are calculated so that the action of the initiation system 14 and the combustion of the fuel injected with the air aspirated by the gas turbine apply the required torque to the gas turbine 12.

[0082] Once a so-called transition speed Vt is reached, the starting method passes into the transition step D, during which the set torque value is fixed, and the set fuel metering value is calculated so as to increase the rotation speed of the turbine 12. Thus it is the fuel that regulates the speed of the turbine 12 so as to follow the predetermined speed profile, the initiation system 14 applying only a fixed torque.

[0083] Finally, at the normal-regime step E, the starting is ended and the gas turbine 12 goes back into normal regime. The initiation system 14 is stopped and the turbine 12 is rotated only by the combustion of the fuel injected by the fuel metering device 30.