Abstract
The loading-to-flow diagram is a widely used classical method for the preliminary design of radial turbines. This study improves this method to optimize the design of radial turbines in the early design phase under variable operating conditions. The guide vane outlet flow angle is a key factor affecting the off-design performance of the radial turbine. To optimize the off-design performance of radial turbines in the early design phase, we propose a hypothesis that uses the ratio of the mean velocity of the fluid relative to the rotor passage with respect to the circumferential velocity of the rotor as an indicator to indirectly and qualitatively estimate the rotor loss, as it plays a key role in the off-design efficiency. Theoretical analysis of rotor loss characteristics under different types of variable operating conditions shows that a smaller design value of guide vane outlet flow angle results in a better off-design performance in the case of a reduced mass flow. In contrast, radial turbines with a larger design value of guide vane outlet flow angle can obtain a better off-design performance with increased mass flow. The above findings were validated with a mean-line model method. Furthermore, this study discusses the optimization of the design value of guide vane outlet flow angle based on the matching of rotor loss characteristics with specified variable operating conditions. It provides important guidance for the design optimization of multistage radial turbines with variable operating conditions in compressed air energy storage (CAES) systems.
Highlights
IntroductionMultistage radial turbines—usually referring to the multistage radial turbo expanders—are the key component of power generation systems in compressed air energy storage (CAES) and are employed in the recycling of waste heat, residual pressure, and gas in the petrochemical industry
When multistage radial turbines in compressed air energy storage (CAES) systems are integrated with renewable energy generation, generation, the fluctuating power output and inlet pressure make them able to operate under variable working conditions
It can be seen that the larger the design value of guide vane outlet flow angle, the higher the design efficiency of the radial turbine, and the higher the efficiency operating under variable pressure ratio in a certain range (0.5 < βt,i /βt,d < 1.5)
Summary
Multistage radial turbines—usually referring to the multistage radial turbo expanders—are the key component of power generation systems in compressed air energy storage (CAES) and are employed in the recycling of waste heat, residual pressure, and gas in the petrochemical industry. Multistage radial turbines can realize the efficient energy release of a large expansion ratio from the high pressure of compressed compressed air storage to the atmospheric atmospheric pressure, and have the advantages of high efficiency, compact structure, and large power capacity. They they are widely used advantages of high efficiency, compact structure, and large power capacity. When multistage radial turbines in CAES systems are integrated with renewable energy generation, generation, the fluctuating power output and inlet pressure make them able to operate under variable working conditions.
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