TY - GEN
T1 - EXPERIMENTAL ANALYSIS OF AN ELASTOHYDRODYNAMIC SEAL FOR SUPERCRITICAL CARBON DIOXIDE TURBOMACHINERY
AU - Henry, Jonah
AU - Xu, Hanping
AU - Hassan, Mohammad Fuad
AU - Cesmeci, Sevki
AU - Islam, Mohammad Towhidul
AU - Liu, Shuangbiao
AU - Tang, Jing
N1 - Publisher Copyright:
Copyright © 2023 by ASME.
PY - 2023
Y1 - 2023
N2 - To unlock the potential of sCO2 power cycles, technology readiness must be demonstrated on the scale of 10 – 600 MWe and at the sCO2 temperatures and pressures of 350 – 700 °C and 20 –35 MPa for nuclear industries. The lack of suitable shaft seals in sCO2 operating conditions is one of the main challenges at the component level. So far, conventional seals all suffer from the incapability of handling sCO2 pressure and temperature in one way or another. To this end, we propose an elastohydrodynamic (EHD) high-pressure, high-temperature, and scalable shaft seal for sCO2 cycles. The unique mechanism of such an EHD seal provides a self-regulated constriction effect to restrict the flow without substantial material contact, thereby minimizing leakage and wear. In this study, we conducted an experimental study to prove the EHD seal concept on a 2” static shaft. The shaft was made from stainless steel, whereas the test seal was made from PEEK. The experiments were performed for 12.7 μm initial clearance, and the operating pressure was increased up to 5 MPa. It was observed that the EHD seal throttled the leakage rate successfully. The leakage rate increased to a maximum of 2 g/s at around 4MPa before it started to decay to 1.75 g/s at the maximum operating pressure of 5 MPa. This unique behavior of the EHD seal could become advantageous for sCO2 turbomachinery, where lower leakage rates are required at high pressure and temperature values.
AB - To unlock the potential of sCO2 power cycles, technology readiness must be demonstrated on the scale of 10 – 600 MWe and at the sCO2 temperatures and pressures of 350 – 700 °C and 20 –35 MPa for nuclear industries. The lack of suitable shaft seals in sCO2 operating conditions is one of the main challenges at the component level. So far, conventional seals all suffer from the incapability of handling sCO2 pressure and temperature in one way or another. To this end, we propose an elastohydrodynamic (EHD) high-pressure, high-temperature, and scalable shaft seal for sCO2 cycles. The unique mechanism of such an EHD seal provides a self-regulated constriction effect to restrict the flow without substantial material contact, thereby minimizing leakage and wear. In this study, we conducted an experimental study to prove the EHD seal concept on a 2” static shaft. The shaft was made from stainless steel, whereas the test seal was made from PEEK. The experiments were performed for 12.7 μm initial clearance, and the operating pressure was increased up to 5 MPa. It was observed that the EHD seal throttled the leakage rate successfully. The leakage rate increased to a maximum of 2 g/s at around 4MPa before it started to decay to 1.75 g/s at the maximum operating pressure of 5 MPa. This unique behavior of the EHD seal could become advantageous for sCO2 turbomachinery, where lower leakage rates are required at high pressure and temperature values.
KW - EHD Seal
KW - Seal
KW - power generation
KW - sCO2
KW - supercritical carbon dioxide
KW - sustainable power generation
UR - http://www.scopus.com/inward/record.url?scp=85174619731&partnerID=8YFLogxK
U2 - 10.1115/POWER2023-108781
DO - 10.1115/POWER2023-108781
M3 - Conference article
AN - SCOPUS:85174619731
T3 - American Society of Mechanical Engineers, Power Division (Publication) POWER
BT - Proceedings of ASME Power Applied R and D 2023, POWER 2023
PB - American Society of Mechanical Engineers (ASME)
T2 - ASME Power Applied R and D 2023, POWER 2023
Y2 - 6 August 2023 through 8 August 2023
ER -