The market deregulation as well as interest in local power and heat production has increased the use of gas turbines. A method to increase the performance and decrease the environmental impact of gas turbines, is to introduce a high amount of water or steam into the gas turbine cycle. This paper will discuss some industrial applications for the Evaporative Gas Turbine - EvGT. The EvGT cycle is preferably compared with the combined cycle in respect of efficiency, emissions, part load characteristics and economy. The main difference between an EvGT-cycle and a combined cycle is in the way the energy in the flue gas is recovered. The combined cycle has a gas turbine as a topping cycle followed by a steam turbine bottoming cycle. In the EvGT-cycle there is no bottoming cycle. Instead the energy in the flue gas is recovered directly into the gas turbine as a water/steam-air mixture. This makes it possible for the EvGT to offer high flexibility in the split between electricity, process steam and process heat during operation. The steam cycle has a relatively high specific investment cost and therefore requires reasonable or even high grade steam to be generated from the flue gases. Due to this, combined cycles are often built around bigger gas turbines with high exhaust temperatures. Examples of the appearance of the EvGT in different applications are presented. The results are based on the market study (carried out at Vattenfall). The energy and fuel prices used in the presented cases are just examples and not a forecast by Vattenfall. The specific investment cost is indicative. The physical size of the EvGT plant depends on many factors. First of all the number and types of components used. The two main parameters that determine the dimensions of the humidifier are the humidification ratio (height) and the fraction of airflow (width). The height grows in increments depending on the number of stages needed in the humidifier, whereas the width or cross section is proportional to the airflow through the humidifier. Although initially the main advantage of the EvGT was shown in power generation, it is also interesting to use in cogeneration. Since the different products from the gas turbine e.g. electricity and process steam is competing for the same thermal energy it is important to have the right balance with respect to the configuration. The EvGT challenges the competition in performance. A combustion chamber designed for humidified air is likely to perform equal or even better than the best DLE designs from an emission point of view. The high specific power will generate significantly lower investment costs compared to combined cycles. Due to good performance, high flexibility and low investment cost the EvGT will have a position in future energy production.