The transition in the energy market and the growing share of renewable energy sources have been
boosting the research in new power cycles. For example, the concept of batch evaporation in the Misselhorn
Cycle promises to increase the overall efficiency in low-temperature applications and therefore
saves resources. In this paper, a dynamic evaporator model was extended in order to prove the feasibility
of the Misselhorn Cycle despite its transient character. In this context, the thermal capacity of the wall
material as well as the residence time of the heat source medium were added. The previous, underlying
model predicted an improved system efficiency for the Misselhorn Cycle of about 50% compared to an
Organic Rankine Cycle (ORC) at 100+C. Initially, the results of the extended model showed a negative
influence of the inertial effects on the possible net power output (advantage over ORC only 10%).
However, an unheated discharge phase and reduced dimensions of the heat exchanger could compensate
these drawbacks and achieved results (about 40% better than ORC) in the same range as the previous,
simple model predicted. These findings prove the general practical feasibility of the Misselhorn Cycle.The transition in the energy market and the growing share of renewable energy sources have been
boosting the research in new power cycles. For example, the concept of batch evaporation in the Misselhorn
Cycle promises to increase the overall efficiency in low-temperature applications and therefore
saves resources. In this paper, a dynamic evaporator model was extended in order to prove the feasibility
of the Misselhorn Cycle despite its transient character. In this context, the thermal capacity of the wall
material as well as the residence time of the heat source medium were added. The previous, underlying
model predicted an improved system efficiency for the Misselhorn Cycle of about 50% compared to an
Organic Rankine Cycle (ORC) at 100+C. Initially, the results of the extended model showed a negative
influence of the inertial effects on the possible net power output (advantage over ORC only 10%).
However, an unheated discharge phase and reduced dimensions of the heat exchanger could compensate
these drawbacks and achieved results (about 40% better than ORC) in the same range as the previous,
simple model predicted. These findings prove the general practical feasibility of the Misselhorn Cycle.
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The transition in the energy market and the growing share of renewable energy sources have been
boosting the research in new power cycles. For example, the concept of batch evaporation in the Misselhorn
Cycle promises to increase the overall efficiency in low-temperature applications and therefore
saves resources. In this paper, a dynamic evaporator model was extended in order to prove the feasibility
of the Misselhorn Cycle despite its transient character. In this context, the thermal capac...
»
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