**Part 4**

**Combustion** 

236 Advances in Gas Turbine Technology

Ribaud, Y., 2004, Overall Thermodynamics Model of an Ultra Micro turbine, *Journal of* 

Sacadura, J. F., 1993, Initiation aux transferts thermiques, *Lavoisier Tec & Doc,* Vol. 4ème tirage

Verstraete, T. & al., 2007, Numerical Study of the Heat Transfer in Micro Gas Turbines,

*Journal of Turbomachinery.* ASME, Octobre 2007, Vol.129, DOI: 10.1115/1.2720874,

*Thermal Science.* 2004, Vol. 13, 4, pp. 297-301.

1993, pp. 1-439, ISBN. 2-85206-618-1.

pp 835-841.

**11** 

*Japan* 

**Developments of Gas Turbine** 

**Combustors for Air-Blown and** 

*Central Research Institute of Electric Power Industry* 

From the viewpoints of securing a stable supply of energy and protecting our global environment in the future, the integrated gasification combined cycle (IGCC) power generation of various gasifying methods has been introduced in the world. Gasified fuels are chiefly characterized by the gasifying agents and the synthetic gas cleanup methods and can be divided into four types. The calorific value of the gasified fuel varies according to the gasifying agents and feedstocks of various resources, and ammonia originating from nitrogenous compounds in the feedstocks depends on the synthetic gas clean-up methods. In particular, air-blown gasified fuels provide low calorific fuel of 4 MJ/m3 and it is necessary to stabilize combustion. In contrast, the flame temperature of oxygen-blown gasified fuel of medium calorie between approximately 9–13 MJ/m3 is much higher, so control of thermal-NOx emissions is necessary. Moreover, to improve the thermal efficiency of IGCC, hot/dry type synthetic gas clean-up is needed. However, ammonia in the fuel is not removed and is supplied into the gas turbine where fuel-NOx is formed in the combustor. For these reasons, suitable combustion technology for each gasified fuel is important. In this paper, I will review our developments of the gas turbine combustors for the three type gasified fuels produced from the following gasification methods through experiments using a small diffusion burner and the designed combustors' tests of the

 Air-blown gasifier + Hot/Dry type synthetic gas clean-up method. Oxygen-blown gasifier + Wet type synthetic gas clean-up method. Oxygen-blown gasifier + Hot/Dry type synthetic gas clean-up method.

power than an LNG gas turbine power generation.

Figure 1 provides an outline of a typical oxygen-blown IGCC system. In this system, raw materials such as coal and crude are fed into the gasifier by slurry feed or dry feed with nitrogen. The synthetic gas is cleaned through a dust removing and desulfurizing process. The cleaned synthetic gas is then fed into the high-efficiency gas turbine topping cycle, and the steam cycle is equipped to recover heat from the gas turbine exhaust. This IGCC system is similar to LNG fired gas turbine combined cycle generation, except for the gasification and the synthetic gas cleanup process, primarily. IGCC requires slightly more station service

**1. Introduction**

simulated gasified fuels.

**Oxygen-Blown IGCC** 

Takeharu Hasegawa
