Turbine Passage Design Methodology to Minimize Entropy Production—A Two-Step Optimization Strategy

Abstract: Rapid aerodynamic design and optimization is essential for the development of future turbomachinery. The objective of this work is to demonstrate a methodology from 1D mean-line-design to a full 3D aerodynamic optimization of the turbine stage using a parameterization strategy that requires few parameters. The methodology is tested by designing a highly loaded and efficient turbine for the Purdue Experimental Turbine Aerothermal Laboratory. This manuscript describes the entire design process including the 2D/3… Show more

“…In the application of the network methodology the value of the mean stagnation density in each node can be obtained with the sequence provided in Equation (11) as follows: (i) determine the entropy at the stagnation conditions using the known values of stagnation enthalpy and stagnation pressure with the aid of a suitable real gas fluid property library (such as CoolProp); (ii) determine the static enthalpy from the stagnation enthalpy and the velocity; (iii) obtain the static pressure using the known values of static enthalpy and entropy (which is the same value as at the stagnation conditions) with the aid of a suitable real gas fluid property library; (iv) determine the value of the mean stagnation density from Equation (11).…”

“…For a one-dimensional fluid control volume with a well-defined single inlet (i) and single outlet (e) Equation ( 13) can be integrated to get ( ) ( ) The simultaneous solution of ( 5) and ( 6) for each node and ( 14) for each element in the network, together with appropriate boundary conditions will yield the nodal stagnation pressures and enthalpies as well as the elemental mass flow rates. Following this the static properties can be obtained from equation (11), which can then be used to determine all the other fluid properties with the aid of a suitable real gas fluid property library. Once all the fluid property values are known for the nodes, the appropriate mean values can also be determined for the elements, which in turn can be used in the calculation of the component characteristics (…”

“…The utilization of static maps does not provide a direct simulation of the internal flows and dynamic behavior through the machines. Therefore, the approach using static maps cannot be applied when performing integrated cycle design optimization [11][12][13] which includes machine dimensions such as impeller diameters and vane angles as independent design parameters, or when the fast transient response [14] of the turbomachinery systems is to be investigated. Furthermore, the conventional scaling rules based on corrected mass flow and corrected speed on which static maps are based do not necessarily ensure similarity in the case of sCO2 [15].…”

Modelling of Real Gas Compression Using the Finite Volume Thermofluid Network Methodology and Mean-Line Approach for Centrifugal Compressors

“…In the application of the network methodology the value of the mean stagnation density in each node can be obtained with the sequence provided in Equation (11) as follows: (i) determine the entropy at the stagnation conditions using the known values of stagnation enthalpy and stagnation pressure with the aid of a suitable real gas fluid property library (such as CoolProp); (ii) determine the static enthalpy from the stagnation enthalpy and the velocity; (iii) obtain the static pressure using the known values of static enthalpy and entropy (which is the same value as at the stagnation conditions) with the aid of a suitable real gas fluid property library; (iv) determine the value of the mean stagnation density from Equation (11).…”

“…For a one-dimensional fluid control volume with a well-defined single inlet (i) and single outlet (e) Equation ( 13) can be integrated to get ( ) ( ) The simultaneous solution of ( 5) and ( 6) for each node and ( 14) for each element in the network, together with appropriate boundary conditions will yield the nodal stagnation pressures and enthalpies as well as the elemental mass flow rates. Following this the static properties can be obtained from equation (11), which can then be used to determine all the other fluid properties with the aid of a suitable real gas fluid property library. Once all the fluid property values are known for the nodes, the appropriate mean values can also be determined for the elements, which in turn can be used in the calculation of the component characteristics (…”

“…The utilization of static maps does not provide a direct simulation of the internal flows and dynamic behavior through the machines. Therefore, the approach using static maps cannot be applied when performing integrated cycle design optimization [11][12][13] which includes machine dimensions such as impeller diameters and vane angles as independent design parameters, or when the fast transient response [14] of the turbomachinery systems is to be investigated. Furthermore, the conventional scaling rules based on corrected mass flow and corrected speed on which static maps are based do not necessarily ensure similarity in the case of sCO2 [15].…”

Modelling of Real Gas Compression Using the Finite Volume Thermofluid Network Methodology and Mean-Line Approach for Centrifugal Compressors

“…The ultimate goal is either to minimize the effort required or to maximize the desired benefit. For instance, Balafkandeh et al [5] and Juangphanich et al [6] focus their efforts on optimizing operations to minimize outputs, while, Oleksy-Sobczak and Klewicka [7] and Delavar and Naderifar [8] pursue optimization of inputs to maximize results. However, companies are not only concerned with creating more products with less resources; they also have the intention of performing right operations the first time.…”

A Study of Stopping Rules in the Steepest Ascent Methodology for the Optimization of a Simulated Process

A multi-factor comprehensive optimization of a supercritical carbon dioxide radial inflow turbine with low specific speed