1. Thermal Energy System Laboratory, Korea Institute of Energy Research, 152 Gajeong-ro, Yusung-gu, Daejeon 34129, Republic of Korea 2. Engine Component Research Team, Korea Aerospace Research Institute (KARI), 169-84 Gwahak-ro, Yusung-gu, Daejeon 34133, Republic of Korea 3. InGineers, 21 Saman-ro, 16 Beon-gil, Gimhae-si, Gyeongsangnam-do 621-220, Republic of Korea
Research on applying a supercritical carbon dioxide power cycle (S-CO2) to concentrating solar power (CSP) instead of a steam Rankine cycle or an air Brayton cycle has been recently conducted. An S-CO2 system is suitable for CSP owing to its compactness, higher efficiency, and dry-cooling capability. At the Korea Institute of Energy Research (KIER), to implement an S-CO2 system, a 10 kWe class test loop with a turbine-alternator-compressor (TAC) using gas foil bearings was developed. A basic sub-kWe class test loop with a high-speed radial type turbo-generator and a test loop with a capability of tens of kWe with an axial type turbo-generator were then developed. To solve the technical bottleneck of S-CO2 turbomachinery, a partial admission nozzle and oil-lubrication bearings were used in the turbo-generators. To experience the closed-power cycle and develop an operational strategy of S-CO2 operated at high pressure, an organic Rankine cycle (ORC) operating test using a refrigerant as the working fluid was conducted owing to its operational capability at relatively low-pressure conditions of approximately 30 to 40 bar. By operating the sub-kWe class test loop using R134a as the working fluid instead of CO2, an average turbine power of 400 W was obtained.
. [J]. Frontiers in Energy, 2017, 11(4): 452-460.
Junhyun CHO, Hyungki SHIN, Jongjae CHO, Young-Seok KANG, Ho-Sang RA, Chulwoo ROH, Beomjoon LEE, Gilbong LEE, Byunghui KIM, Young-Jin BAIK. Preliminary experimental study of a supercritical CO2 power cycle test loop with a high-speed turbo-generator using R134a under similarity conditions. Front. Energy, 2017, 11(4): 452-460.
0.4 (turbine) /2.95/110/90/2016 (operated with R134a as a workingfluid)
0.0/0/0/0/2016 (preliminary testing)
15/10.5/477 /50/2012
40/14.1/282 /55/2014
Tab.1
Fig.1
Fig.2
Fig.3
Fig.4
Parameters
Design target
CFD result
Rotational speed/(RPM)
200000
–
Wheel diameter/mm
22.6
–
Blade height/mm
1.7
Mass flow rate/(kg·s−1)
0.621
0.626
Expansion ratio
2.27
2.27
Efficiency/%
–
79.7
Tab.2
Fig.5
Operation modes
Operation strategy
Cycle operation
1. Closed cycle operation characteristics andcontrol parameters 2. Closed Rankine cycle operation characteristicswith phase change and control parameters 3. Identification of cycle operation characteristicsand analysis of control parameters through expansion needle valves 4. Identification of cycle operation characteristicsaccording to working fluid filling amount and analysis of controlparameters 5. Identification of cycle starting characteristicsand development of the control strategy 6. Analysis and development of the control strategyof the CO2 pumps 7. Development of the cycle restart procedureand control strategy through expansion needle valve after turbineshutdown 8. Development of the cycle characteristic/turbineoperating characteristic analysis method based on raw data measurement
Turbine operation
1. Development of turbine start-up procedureand control strategy 2. Identification and analysis of turbine start-upoperation characteristics 3. Confirm turbine power production 4. Analysis of turbine operation characteristicsby controlling turbine load 5. Analysis of cycle pressurizing/heating/coolingsection operation characteristics during turbine operation 6. Identification of turbine leakage amountand characteristics 7. Development and complementation of turbineleakage make-up strategy 8. Development of cycle control strategy foroperation of the turbine design point 9. Verification of vibration stability characteristicswhen driving a turbine 10. Identification of bearing/generator temperaturechange characteristics during turbine operation 11. Check and supplement emergency stop operationin case of turbine problems 12. Development of turbine drive stop procedureand control strategy
Tab.3
Fig.6
Fig.7
CSP
Concentrating solar power
PCHE
Printed circuit heat exchanger
RPM
Rotation per minute
S-CO2
Supercritical carbon dioxide power cycle
TAC
Turbo-alternator-compressor
1
Dostal V, Driscoll M, Hejzlar P . A supercritical carbon dioxide cycle for next generation nuclear reactors. Massachusetts Institute of Technology, MA 2004, MIT-ANP-TR-100
2
Wright S A, Radel R F, Vernon M E, Rochau G E, Pickard P S. Operation and analysis of a supercritical CO2 Brayton cycle. SANDIA REPORT, 2010: SAND2010–0171
3
Pasch J J, Conboy T M, Fleming D D, Rochau G E. Supercritical CO2 recompression Brayton cycle: completed assembly description. SANDIA REPORT, 2012: SAND 2012–9546
4
Conboy T, Wright S A, Pasch J, Fleming D , Rochau G , Fuller R . Performance characteristics of an operating supercritical CO2 Brayton cycle. ASME Turbo Expo: Turbine Technical Conference & Exposition, 2012, 134(11): GT2012–68415
5
Conboy T, Pasch J, Fleming D . Control of a supercritical CO2 recompression Brayton cycle demonstration loop. Asme Turbo Expo: Turbine Technical Conference & Exposition, 2013, 135(11): GTP–13–1198
6
Clementoni E M , Cox T L . Steady-state power operation of a supercritical carbon dioxide Brayton cycle. ASME Turbo Expo: Turbine Technical Conference & Exposition, 2014: GT2014–25336
7
Clementoni E M , Cox T L . Practical aspects of supercritical carbon dioxide Brayton system testing. Proceedings of the 4th International Symposium-Supercritical CO2 Power Cycles, Pittsburgh, Pennsylvania, 2014
8
Kalra C J. Development of high efficiency hot gas turbo-expander for optimized CSP supercritical CO2 power block operation. Proceedings of the 4th International Symposium-Supercritical CO2 Power Cycles, Pittsburgh, Pennsylvania, 2014
9
Moore J, Brun K, Evans N , Bueno P , Kalra C J . Development of a 1 MWe supercritical CO2 Brayton cycle test loop. Proceedings of the 4th International Symposium-Supercritical CO2 Power Cycles, Pittsburgh, Pennsylvania, 2014
10
Held T J. Initial test results of a megawatt-class supercritical CO2 heat engine. Proceedings of the 4th International Symposium-Supercritical CO2 Power Cycles, Pittsburgh, Pennsylvania, 2014
11
Zhang Z, Ma Y, Li M , Zhao L. Recent advances of energy recovery expanders in the Transcritical CO2 refrigeration cycle. HVAC & R Research, 2013, 19(4): 376–384
12
Cho J, Choi M, Baik Y J , Lee G, Ra H S, Kim B, Kim M . Development of the turbomachinery for the supercritical CO2 power cycle. International Journal of Energy Research, 2016, 40(5): 587–599 https://doi.org/10.1002/er.3453
13
Cho J, Shin H, Cho J , Ra H S , Roh C, Lee B, Lee G , Baik Y J . Development of the supercritical carbon dioxide power cycle experimental loop with a turbo-generator. Asme Turbo Expo: Turbomachinery Technical Conference & Exposition, 2016: GT2017–64287
