Your search keyword '"Chien-Hsiung Lee"' showing total 46 results

1. A serial link transceiver for USB2 high-speed mode.

Author

Shyh-Jye Jou, Shu-Hua Kuo, Jui-Ta Chiu, Chu King, Chien-Hsiung Lee, and Tim Liu

Published

2001

2. Joint AGC-Equalization Algorithm and VLSI Architecture for Wirelined Transceiver Designs.

Author

Jyh-Ting Lai, An-Yeu Wu, and Chien-Hsiung Lee

Published

2007

3. Design and Performance Study of a Solid Oxide Fuel Cell and Gas Turbine Hybrid System Applied in Combined Cooling, Heating, and Power System

Author

Wu-Bin Huang, Chien-Hsiung Lee, Wei-Ping Huang, Hsiao-Wei D. Chiang, Chih-Neng Hsu, and Wen-Tang Hong

Subjects

Engineering, Renewable Energy, Sustainability and the Environment, business.industry, Nuclear engineering, Energy Engineering and Power Technology, Automotive engineering, Power (physics), Electric power system, Nuclear Energy and Engineering, Operating temperature, Hybrid system, Waste heat, Solid oxide fuel cell, Hybrid power, Current (fluid), business, Waste Management and Disposal, Civil and Structural Engineering

Abstract

Because of their high efficiency and very low emissions, fuel cells have been one of the choice areas of research in current energy development. The solid oxide fuel cell (SOFC) is a type of high-temperature fuel cell. It has the characteristic of a very high operating temperature of 1,027°C (1,300 K). The SOFC has the main advantage of very high performance efficiency (more than 50%) but also has very high exhaust temperatures. Current studies point out that the combination of the SOFC and gas turbine (GT) can produce efficiency of more than 60%. The exhaust temperature of this hybrid power system can be as high as 227–327°C (500–600 K). With this waste heat utilized, it is possible to further improve the overall efficiency of the system. A simulation program of the SOFC/GT system and the introduction of the concept of combined cooling, heating, and power (CCHP) system have been used in this study. The waste heat of the SOFC/GT hybrid power generation system was used as the heat source to drive a...

Published

2012

4. MATHEMATICAL MODEL PREDICTING THE CRITICAL HEAT FLUX OF NUCLEAR REACTORS

Author

Kuo-Wei Lin, Chien-Hsiung Lee, and Lih-Wu Hourng

Subjects

Computer Networks and Communications, Computer science, Critical heat flux, Pressurized water reactor, Flux, Heat transfer coefficient, Boiling heat transfer, Mechanics, Thermal conduction, law.invention, Physics::Fluid Dynamics, Flow boiling heat transfer, Heat flux, Artificial Intelligence, law, Heat transfer, Nuclear power plant, Boiling water reactor, High heat, Software, Nucleate boiling

Abstract

Boiling heat transfer system keeps a nuclear power plant safe without getting over-heated. Crisis will occur if the dissipated heat flux exceeds the critical heat flux value. This study assumes the flow boiling system at high heat flux is characterized by the existence of a very thin liquid layer, known as the &#34sublayer&#34, which is trapped between the heated surface and the vapor blankets. In the present study, it is hypothesized that the heat transfer through the liquid sublayer is dominated by the heat conduction and the sublayer is dried out due to occurrence of Helmholtz instability as the relative velocity of the vapor blanket to the local liquid in the sublayer reaches a critical value. By recognizing this hypothesis, a theoretical model for low-quality flow is developed to predict boiling heat transfer and Critical Heat Flux (CHF). To verify the validity of the present model, the predictions are compared with the experimental data of flow boiling heat transfer in the simulation of Pressurized Water Reactor (PWR) and Boiling Water Reactor (BWR) conditions. For the PWR low-quality flow, the comparison demonstrates that the Helmholtz instability is the trigger condition for the onset of CHF.

Published

2012

5. Thermo-electrochemical and thermal stress analysis for an anode-supported SOFC cell

Author

Ryey-Yi Lee, Chien-Hsiung Lee, Hui-Chung Liu, Lieh-Kwang Chiang, and Yao-Hua Shiu

Subjects

Engineering, Field (physics), Renewable Energy, Sustainability and the Environment, business.industry, Mechanical engineering, Computational fluid dynamics, Electrochemistry, Anode, Temperature gradient, Thermal, Solid oxide fuel cell, Composite material, business, Voltage

Abstract

The main objective of this paper is to evaluate the fuel/oxidant gas distributions as well as thermal stresses of an anode-supported solid oxide fuel cell (SOFC) test cell under different operating conditions. In this study, the commercial computational fluid dynamics (CFD) code Star-CD with es-sofc module is employed to simulate the current–voltage (I–V) characteristics and to provide the temperature field of the cell to the commercial code MARC for further thermal stress analysis. Structural and fluid elements are built by preprocessing codes PATRAN and GRIDGEN, respectively. The simulation results indicate that the cells experience higher principal stresses at lower cell voltages due to a higher local current density and a higher temperature gradient.

Published

2008

6. Efficiency analyses of solid oxide fuel cell power plant systems

Author

Wen-Tang Hong, Yau-Pin Chyou, Kin-Fu Lin, Dong-Di Yu, Chien-Hsiung Lee, and Tsang-Dong Chung

Subjects

Engineering, Power station, Waste management, business.industry, Nuclear engineering, Oxide, Energy Engineering and Power Technology, Industrial and Manufacturing Engineering, Methane, chemistry.chemical_compound, Plant efficiency, chemistry, Operating temperature, Hydrogen fuel, Annual fuel utilization efficiency, Solid oxide fuel cell, business

Abstract

In this paper, the effects of fuel utilization, air-to-fuel ratio (A/F) and pre-reforming rate on the plant efficiency, including heat and electric efficiencies, of sequential-type and fully recuperative-type of solid oxide fuel cell (SOFC) power plant are studied with the GCTool software developed by American Argonne National Laboratory (ANL). Methane is chosen as fuel, air as oxidant, and the pressure drop due to stream transported in the duct and components is considered in both types of power plant systems. A full analysis of the state at each node of the system is conducted. The results reveal that the A/F factor is the most important factor on system efficiency, and the pre-reforming rate of fuel is insignificant to the efficiency, but it can be used as an auxiliary tuner for the operating temperature of the solid oxide fuel cells in addition to A/F value. Under the same settings, overall plant efficiency is higher in the sequential type than in the fully recuperative type of SOFC power plants. On the other hand, for electric efficiency, the opposite trend is observed.

Published

2008

7. Hydrogen production in a thermal plasma hydrogen reformer using ethanol steam reforming

Author

Chi-Sheng Wang, Chien‐Hsiung Lee, and Huan-Liang Tsai

Subjects

Steam reforming, Temperature control, Materials science, Catalytic reforming, Atmospheric pressure, Methane reformer, Thermodynamic equilibrium, General Engineering, Analytical chemistry, Small stationary reformer, Thermodynamics, Hydrogen production

Abstract

This paper presents both analytical thermodynamic analysis and experimental results of ethanol steam reforming in a thermal plasma reformer at various working conditions. Since our thermal plasma reformer can work well at atmospheric pressure, a thermodynamic equilibrium prediction is first performed at temperatures in the range from 500 to 1000°C and at mole flow ratios of ethanol to water from 1:1 to 1:6. And then the experiment for ethanol steam reforming of a fabricated thermal plasma reformer is performed and the reformate stream is immediately analyzed using GC/MS, GC/FID/TCD, and pre‐concentrator. Comparing predicted data with experimental data, an optimal working condition is determined at the temperature of 750°C and at mole flow ratio of ethanol to water of 1:3. In the future, an optimal temperature control system will be designed to maintain the thermal plasma reformer at the temperature of 750°C under the inlet mole flow ratio of ethanol to water of 1:3.

Published

2008

8. Experimental simulation on the integration of solid oxide fuel cell and micro-turbine generation system

Author

Wei Hsiang Lai, Chi An Hsiao, Chien Hsiung Lee, Yu-Ching Tsai, and Yau Pin Chyou

Subjects

Engineering, Hydrogen, Renewable Energy, Sustainability and the Environment, business.industry, Nuclear engineering, Energy Engineering and Power Technology, Mechanical engineering, Exhaust gas, chemistry.chemical_element, Combustion, Turbine, chemistry, Combustor, Solid oxide fuel cell, Water injection (engine), Electrical and Electronic Engineering, Physical and Theoretical Chemistry, business, Turbocharger

Abstract

Solid oxide fuel cell (SOFC) is characterized in high performance and high temperature exhaust, and it has potential to reach 70% efficiency if combined with gas turbine engine (GT). Because the SOFC is in developing stage, it is too expensive to obtain. This paper proposes a feasibility study by using a burner (Comb A) to simulate the high temperature exhaust gas of SOFC. The second burner (Comb B) is connected downstream of Comb A, and preheated hydrogen is injected to simulate the condition of sequential burner (SeqB). A turbocharger and a water injection system are also integrated in order to simulate the situation of a real SOFC/GT hybrid system. The water injection system is used to simulate the water mist addition at external reformer. Results show that this configuration can simulate the SOFT/GT hybrid system successfully. Water mist addition will increase the GT rotational speed, but an optimal amount exists during the variation of water injection. In residual fuel addition test, hydrogen shows good combustion efficiency and preheating temperature is the dominant parameter for hydrogen burning in SeqB even without flame holding mechanism in it. When preheating temperature is among 450–600 °C, hydrogen will have almost 100% combustion efficiency at 90% engine loading, and GT will get a higher rotational speed for the same energy input. But when the engine operates at 100% loading, the combustion efficiency will decrease while fuel utilization ( U f ) setting is increasing. When raising the preheated temperature to 650–700 °C, the combustion efficiency will increase rapidly.

Published

2007

9. SOFC Development at INER

Author

Li-Fu Lin, Ruey-Yi Lee, Chien-Hsiung Lee, Chang-Sing Hwang, and Maw-Chwain Lee

Subjects

Marketing, Materials science, Materials Chemistry, Ceramics and Composites, Systems engineering, Condensed Matter Physics

Published

2007

10. Performance simulation for an anode-supported SOFC using Star-CD code

Author

Hui-Chung Liu, Yao-Hua Shiu, Wei-Mon Yan, Chien-Hsiung Lee, and Ryey-Yi Lee

Subjects

Engineering, Work (thermodynamics), Renewable Energy, Sustainability and the Environment, business.industry, Nuclear engineering, Flow (psychology), Energy Engineering and Power Technology, Computational fluid dynamics, Anode, Stack (abstract data type), Thermal, Solid oxide fuel cell, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, business, Simulation, Power density

Abstract

Experimental activities and computational fluid dynamics (CFD) simulation are presented in this paper for investigating the performance of an anode-supported solid oxide fuel cell (SOFC). The goal of this work is to assess a commercial CFD code, Star-CD with es-sofc module, to simulate the current–voltage ( I – V ) characteristics with respect to the experimental data. Compiled with the geometry of cell test housing, a 3D numerical model and test conditions were established to analyze the anode-supported cell (ASC) performance including current density and temperature distributions, fuel concentration, and fuel utilization. After adjusting parameters in the electrochemical model, the simulation results showed good agreements with the experimental data. The results also revealed that the power density increased while the fuel utilization decreased as the fuel flow rate increased. Based on the results, this modeling work will be implemented to analyze the distributions of fuel and oxidant gases for the SOFC stack, to minimize the thermal gradients inside the stack, and to optimize the manifold/flow passage in the future.

Published

2007

11. Joint AGC-Equalization Algorithm and VLSI Architecture for Wirelined Transceiver Designs

Author

Chien-Hsiung Lee, Jyh-Ting Lai, and An-Yeu Wu

Subjects

Very-large-scale integration, Engineering, business.industry, Fast Ethernet, Equalization (audio), Intersymbol interference, Hardware and Architecture, Electronic engineering, Automatic gain control, Electrical and Electronic Engineering, Circuit complexity, Transceiver, business, Software, Blind equalization

Abstract

Traditional approaches of automatic gain control (AGC) involve estimating the average power or the peak amplitude over an extended time period, which results in high hardware complexity and a long processing time. Moreover, the accuracy of traditional approaches is seriously degraded by noise and intersymbol interference. In this paper, we propose a joint AGC and equalization (Joint AGC-EQ) scheme, in which the AGC circuitry comprises only one-tenth of the area of a traditional AGC. In addition, the total convergence time of the proposed Joint AGC-EQ is only half that of traditional blind equalization. The scheme is already silicon proven for the application of a Fast Ethernet transceiver using Faraday/UMC 0.18-mum cell libraries

Published

2007

12. IIST small break LOCA experiments with passive core cooling injection

Author

Wen-Tan Hong, Chien-Hsiung Lee, Chin-Jang Chang, and Lance L. C. Wang

Subjects

Nuclear and High Energy Physics, Engineering, Core cooling, business.industry, Mechanical Engineering, Nuclear engineering, law.invention, Nuclear physics, Core (optical fiber), Nuclear Energy and Engineering, Accident management, law, Nuclear power plant, General Materials Science, Safety, Risk, Reliability and Quality, business, Waste Management and Disposal

Abstract

The purpose of this study is to evaluate the performance of a passive core cooling system (PCCS) with passive injection during the cold-leg small break loss-of-coolant accidents (SBLOCAs) experiments conducted at the Institute of Nuclear Energy Research (INER) Integral System Test (IIST) facility. Four tests were performed simulating break sizes of 0.2–2% (approximately corresponding to 1.25–4″ breaks for a referenced nuclear power plant) at cold-leg for assessing the PCCS capability in accident management. The key thermal–hydraulic phenomena to core heat removal for PCCS are observed and discussed. The experimental results show that the PCCS has successfully provided a continuous removal of core heat and a long term core cooling can be reached for all cases of SBLOCA.

Published

2006

13. Adequacy of Power-to-Mass Scaling in Simulating PWR Incident Transient for Reduced-Height, Reduced-Pressure and Full-Height, Full-Pressure Integral System Test Facilities

Author

Chien-Hsiung Lee and Tay-Jian Liu

Subjects

010308 nuclear & particles physics, Nuclear engineering, Pressurized water reactor, 0211 other engineering and technologies, Fluid mechanics, 02 engineering and technology, Nuclear reactor, 01 natural sciences, law.invention, Power (physics), Nuclear physics, Thermal hydraulics, Nuclear Energy and Engineering, Nuclear reactor core, law, 0103 physical sciences, 021108 energy, Transient (oscillation), Scaling

Abstract

A complete scheme of scaling methods to design the reduced-height, reduced-pressure (RHRP) Institute of Nuclear Energy Research Integral System Test (IIST) facility and to specify test conditions for incident simulation was developed. In order to preserve core decay power history and coolant mass inventory during a transient, a unique power-to-mass scaling method is proposed and utilized for RHRP and full-height, full-pressure (FHFP) systems. To validate the current scaling method, three counterpart tests done at the IIST facility are compared with the FHFP tests in small-break loss-of-coolant, station blackout, and loss-of-feedwater accidents performed at the Large-Scale Test Facility (LSTF) and the BETHSY test facility. Although differences appeared in design, scaling, and operation conditions among the IIST, LSTF, and BETHSY test facilities, the important physical phenomena shown in the facilities are almost the same. The physics involved in incident transient phenomena are well measured and modeled by showing the common thermal-hydraulic behavior of key parameters and the general consistency of chronological events. The results also confirm the adequacy of power-to-mass scaling methodology.

Published

2004

14. Experimental Study on the Performance of the Passive Safety Injection in an IIST

Author

Lance L. C. Wang, Wen-Tang Hong, Chien-Hsiung Lee, and Chin-Jang Chang

Subjects

Nuclear and High Energy Physics, 020209 energy, Nuclear engineering, Pressurized water reactor, 02 engineering and technology, Nuclear reactor, Condensed Matter Physics, law.invention, Thermal hydraulics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Nuclear Energy and Engineering, Nuclear reactor core, Cabin pressurization, law, Heat exchanger, 0202 electrical engineering, electronic engineering, information engineering, Water cooling, Environmental science, Line Break

Abstract

A passive core cooling system (PCCS) has been installed at the Institute of Nuclear Energy Research Integral System Test facility. It includes three core makeup tanks (CMTs), three accumulators (ACCs), a four-stage automatic depressurization system (ADS), a passive residual heat removal (PRHR) heat exchanger submerged into an in-containment refueling water storage tank (IRWST). The purpose of this research is to study the performance of the PCCS with passive injection during either a pressure balance line (PBL) break or a direct vessel injection (DVI) line break. Five experiments were performed simulating break area ratios of 0.5 to 2.0% (1.88 to 3.77 mm) at either a PBL or a DVI line. The general system response and the interactions of CMT, ACC, PRHR, and IRWST to the effect of core heat removal are observed and discussed. The experimental results show long-term core cooling can be reached for the cases of the PBL break and the DVI-line break following the PCCS actuation procedures.

Published

2003

15. Self-regulating characteristics of a cold neutron source with a cylindrical-annulus moderator cell

Author

H. Yoshino, Yuji Kawabata, Masahiro Hino, Tai-Cheng Guung, Takeshi Kawai, Yea-Kuang Chan, and Chien-Hsiung Lee

Subjects

self-regulation, Materials science, Hydrogen, Shell (structure), chemistry.chemical_element, Thermodynamics, closed-thermosiphon, Mechanics, cylindrical-annulus moderator cell, Condensed Matter Physics, cold neutron source, Electronic, Optical and Magnetic Materials, chemistry, Mass transfer, Annulus (firestop), Neutron source, Thermosiphon, Electrical and Electronic Engineering, Condenser (heat transfer), Liquid hydrogen

Abstract

The conditions, under which a cold neutron source of the ORPHEE type with a cylindrical-annulus moderator cell could have a self-regulating characteristics, were obtained through thermodynamic considerations. From an engineering viewpoint, it is not easy to establish these conditions because three parameters are involved even in an idealized system, without the effect of the mass transfer through the moderator transfer tube between the condenser and the moderator cell. The inner shell of the ORPHEE moderator cell is open at the bottom, but it is expected that only hydrogen vapor is contained in the inner shell and liquid hydrogen in the outer shell. Thermodynamic considerations show that such a state is maintained only when the liquefaction capacity of the condenser is large compared to the heat load and three parameters should be adjusted with well balance. We have proposed another type of a moderator cell which has an inner cylindrical cavity with no hole at the bottom but a vapor inlet opening at its uppermost part. In this structure, a self-regulating characteristic is easily established and the liquid level in the outer shell is maintained almost constant against thermal disturbances.

Published

2002

16. Using an IIST 1% Cold-Leg SBLOCA Experiment with Passive Safety Injection to Assess the RELAP5/MOD3.2 Code

Author

Chin-Jang Chang, Chien-Hsiung Lee, and I-Ming Huang

Subjects

Nuclear and High Energy Physics, Hydraulics, 020209 energy, Nuclear engineering, Pressurized water reactor, 02 engineering and technology, Nuclear reactor, Condensed Matter Physics, Coolant, law.invention, Thermal hydraulics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Nuclear Energy and Engineering, Cabin pressurization, law, 0202 electrical engineering, electronic engineering, information engineering, Water cooling, Environmental science, Hydraulic accumulator, Nuclear chemistry

Abstract

The thermal-hydraulic behavior of a postulated 1% cold-leg break loss-of-coolant accident (LOCA) in a pressurized water reactor system was investigated experimentally by the three-loop Institute of Nuclear Energy Research (INER) Integral System Test (IIST) facility with the passive core cooling system (PCCS) and numerically by the RELAP5/MOD3.2 computer code. The PCCS of the IIST facility includes three core makeup tanks (CMTs), three accumulators, and a four-stage automatic depressurization system. The aim of this research is to study the performance of the CMTs with the actuation of the ADS during a small-break LOCA. The experimental results show that the IIST PCCS has the capability to maintain long-term cooling under a postulated 1% cold-leg break LOCA. The comparison of the RELAP5/MOD3.2 simulation against the experimental data shows good agreement in major thermal-hydraulic phenomena in the reactor coolant system, but the prediction of the asymmetric behavior for the three CMTs during a gravity drain period is inadequate.

Published

2001

17. An Evaluation of Emergency Operator Actions by an Experimental SGTR Event at the IIST Facility and a Comparison of Mihama-2 SGTR Event Record

Author

Show-Chyuan Chiang, Chien-Hsiung Lee, Tay-Jian Liu, and Ching-Chuan Yao

Subjects

Nuclear and High Energy Physics, Core cooling, 020209 energy, Nuclear engineering, Pressurized water reactor, Boiler (power generation), Emergency operating procedures, 02 engineering and technology, Nuclear reactor, Condensed Matter Physics, Emergency procedure, law.invention, Thermal hydraulics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Nuclear Energy and Engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Test data

Abstract

The current emergency operating procedures (EOPs) for a three-loop pressurized water reactor on steam generator tube rupture (SGTR) incident are experimentally evaluated at the Institute of Nuclear Energy Research Integral System Test Facility. The focus is on the adequacy of EOPs to limit primary-to-secondary leakage with particular emphasis on the number of ruptured U-tubes on the severity of an incident and the response time available for operator actions. By comparing test data with plant records of a Mihama-2 SGTR event, the key thermal-hydraulic phenomena during SGTR transients can be successfully simulated. The test results indicated that the current EOPs can function well in terminating the break flow and maintaining adequate core cooling. However, the effectiveness in minimizing the radioactive release demands an early and substantial operator involvement. To mitigate the consequences of such an event, the timing to isolate the faulted steam generator (SG) and to terminate safety injection flow will be critical. Furthermore, to avoid overfilling, the water level in the faulted SG needs to be drained prior to the implementation of the cooldown process.

Published

2000

18. Using an IIST SBLOCA Experiment to Assess RELAP5/MOD3.2

Author

Chin-Jang Chang, Yuh-Ming Ferng, Tay-Jian Liu, Chien-Hsiung Lee, and I-Ming Huang

Subjects

Nuclear and High Energy Physics, 020209 energy, Nuclear engineering, Flow (psychology), 02 engineering and technology, Condensed Matter Physics, Discharge coefficient, Coolant, Volumetric flow rate, Thermal hydraulics, 020303 mechanical engineering & transports, Natural circulation, 0203 mechanical engineering, Nuclear Energy and Engineering, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Sensitivity (control systems), Choked flow

Abstract

The RELAP5/MOD3.2 code is used at the Institute of Nuclear Energy Research Integral System Test Facility to analyze a 2% cold-leg-break experiment that includes failure of the high-pressure injection system. The assessment code predictions include primary pressure, inventory distribution in the reactor coolant system (RCS), loop flow rate, break flow rate, and core thermal hydraulics. A comparison between the calculated results and the experimental data shows (a) a good match with the predictions of the RCS pressure and hot- and cold-leg fluid temperatures, (b) underprediction of the core and down-comer levels, (c) overprediction of the loop flow rates in single- and two-phase natural circulation, and (d) inadequate prediction of asymmetric coolant holdup in the three stean generators. Also presented are sensitivity studies of choked flow associated with the defaulted values of discharge coefficients in the simulation of the break flow, and of the core bypass area to evaluate the effect of core level depression.

Published

1999

19. A New Mechanistic Critical Heat Flux Model at Low-Pressure and Low-Flow Conditions

Author

Kuan-Chywan Tu, Shih-Jen Wang, Chien-Hsiung Lee, and Bau-Shei Pei

Subjects

Nuclear and High Energy Physics, Critical heat flux, Chemistry, 020209 energy, Flow (psychology), Thermodynamics, Annular flow, 02 engineering and technology, Condensed Matter Physics, Absolute deviation, Flow instability, 020303 mechanical engineering & transports, Liquid film, Flow conditions, 0203 mechanical engineering, Nuclear Energy and Engineering, 0202 electrical engineering, electronic engineering, information engineering, Flow boiling

Abstract

A new mechanistic critical heat flux (CHF) model has been developed for flow boiling CHF data of low-pressure (i.e., 0.2 to 4.0 MPa), low-mass-flux (i.e., 189 to 789 kg/m 2 .s), and high-quality conditions. In general, CHF at these conditions associates with the flow regime of annular flow. This model assumes that the Helmholtz instability at the liquid-vapor interface of annular flow triggers the onset of CHF. CHF is the energy required to dryout the liquid film isolated by flow instability With five empirical constants to properly correlate the liquid-vapor configurations of annular flow in the steam-water systems, the model successfully achieves a mean deviation error of 0.2% over a CHF data set consisting of 733 CHF data. The prediction of this model is more accurate than those of Biasi and Bowring correlations at the aforementioned low-pressure and low-mass-flux conditions.

Published

1998

20. Power-operated relief valve stuck-open accident and recovery scenarios in the Institute of Nuclear Energy Research integral system test facility

Author

Tay-Jian Liu, Chien-Hsiung Lee, and Chien-Yeh Chang

Subjects

Nuclear and High Energy Physics, Engineering, business.industry, Mechanical Engineering, Nuclear engineering, Pressurized water reactor, Mechanical engineering, law.invention, Coolant, Thermal hydraulics, Nuclear Energy and Engineering, law, Pressurizer, Nuclear power plant, Water cooling, General Materials Science, Relief valve, Safety, Risk, Reliability and Quality, business, Waste Management and Disposal, Safety valve

Abstract

Four scaled small break loss-of-coolant accident (LOCA) tests simulating the pressurizer power-operated relief valves (PORVs) stuck-open accidents and the recovery actions in a pressurized water reactor (PWR) were performed at the Institute of Nuclear Energy Research (INER) integral system test (IIST) facility. The objectives of this study are to verify the effectiveness of emergency operating procedure (EOP) and emergency core cooling system (ECCS) on reactor safety. The break sizes were volumetrically scaled down based on one and all three fully-opened PORVs which is equivalent to 0.23% and 0.69% hot leg flow area of the reference plant. The experimental results indicate that in case of high pressure injection (HPI) system failure, the rapid depressurization of the steam generators is proved to be an effective way in the depressurization of the reactor coolant system and the core cooling. In contrast, if only one HPI charging pump operates normally, which injected half (or minimum) flow rate of normal cooling water, the core cooling can be adequately provided without operating the secondary bleeding during PORV stuck-open transient. This paper also presents the scaling methods for the reduced-height, reduced-pressure (RHRP) IIST facility and the test conditions. The validity of the present scaling methodology is confirmed by the results from previous IIST counterpart tests and comparison of the present results with those of the tests performed at the full-height, full-pressure(FHFP) stuck-open tests.

Published

1998

21. IIST and LSTF counterpart test on PWR station blackout transient

Author

Chien-Hsiung Lee, Tay-Jian Liu, and Yuan-Shun Way

Subjects

Nuclear and High Energy Physics, Engineering, Test facility, business.industry, Mechanical Engineering, Nuclear engineering, Blackout, Pressurized water reactor, Coolant, law.invention, Nuclear Energy and Engineering, Cabin pressurization, law, Physical phenomena, medicine, General Materials Science, medicine.symptom, Safety, Risk, Reliability and Quality, business, Waste Management and Disposal, Simulation

Abstract

A reduced-height, reduced-pressure (RHRP) integral system test facility at the Institute of Nuclear Energy Research (INER) has been established for simulating the thermal-hydraulics of a Westinghouse three-loop pressurized water reactor (PWR). To understand whether or not the physical phenomena observed in this RHRP integral system test facility during a station blackout (SB) transient can be reliably extrapolated to those for an actual plant, a counterpart test based on the same scenarios as those of the full-height, full-pressure (FHFP) large-scale test facility (LSTF) test was performed. To see the result of differences in the design, scaling approach and facility operational conditions in the systems, the present study examines their effects on the SB transient, particularly for the tests performed at full and reduced pressures. We also identify the occurrence of key thermal-hydraulic phenomena, as well as their possible distortions. Results of the INER integral system test (ISST) facility and LSTF tests showed the common thermal-hydraulic phenomena, such as the secondary coolant boil-off and the subsequent primary coolant saturation, pressurization, coolant inventory depletion and redistribution, and core uncovery caused by coolant boil-off. The sequence and timing of the significant events during the SB transient studied in the RHRP IIST facility are also consistent (in most cases) with those for the SB transient studied in the FHFP LSTF.

Published

1997

22. RELAP5/MOD3 Simulation of the Station Blackout Experiment Conducted at the IIST Facility

Author

Chien-Hsiung Lee, Tay-Jian Liu, and Yuh-Ming Ferng

Subjects

Nuclear and High Energy Physics, 020209 energy, Nuclear engineering, Blackout, Boiler (power generation), 02 engineering and technology, Nuclear reactor, Condensed Matter Physics, law.invention, Coolant, Thermal hydraulics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Nuclear Energy and Engineering, Cabin pressurization, law, Pressurizer, 0202 electrical engineering, electronic engineering, information engineering, medicine, Environmental science, medicine.symptom, Safety valve

Abstract

Thermal-hydraulic responses in the station blackout experiment conducted at the IIST facility are simulated through the use of the advanced system code RELAP5/MOD3. Typical behaviors occurring in the IIST station blackout transient are characterized by secondary boiloff, primary saturation and pressurization, and subsequent core uncovery and heatup. As the coolant inventory within the steam generator secondary system boils dry, the primary system pressure increases as a result of degradation of the heat removal ability of the steam generator secondary side. This pressurization phenomenon causes the pressurizer safety valve to open and the primary coolant to deplete through the valve, causing the core to eventually become uncovered. The same response can be exactly simulated by the current model. The current calculated results show fairly good agreement with the experimental data, but the timing of the events occurring in the station blackout transient is calculated earlier than the measured value. The overall comparison of key parameters between the calculated results and IIST test data, however, reveals that the current RELAP5/MOD3 model can provide rear sonable station blackout modeling for simulating longterm system behavior.

Published

1996

23. Assessment of the Simulation Capability of RELAP5/MOD3 Compared with IIST Tests for Loss of the Residual Heat Removal System During Midloop Operation

Author

Yuh-Ming Ferng and Chien-Hsiung Lee

Subjects

Nuclear and High Energy Physics, 020209 energy, Nuclear engineering, Pressurized water reactor, Boiler (power generation), 02 engineering and technology, Heat sink, Condensed Matter Physics, law.invention, Thermal hydraulics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Nuclear Energy and Engineering, law, Pressurizer, Boiling, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Water cooling, Environmental science

Abstract

The simulation capabilities of RELAP5/MOD3 are analyzed and assessed in comparison with the IIST experiments conducted to investigate the system response to the loss of the residual heat removal (RHR) system during midloop operation. Two IIST experiments are simulated; a one-loop test under closed system conditions and a three-loop test with a vent at the top of the pressurizer. Once the RHR cooling system is lost and if alternate heat sinks are not established in time, the primary system will be heated up by the decay power, causing core boiling, system pressurization, and potential core uncovery and fuel heatup. The predicted responses of system parameters by the current model show reasonable agreement with the experimental data. These key parameters consist of the system pressure transient, temperature histories, and variation in the active heat transfer length within the steam generator. The liquid flooding in the pressurizer and the steam generator can also be captured in the current simulation. A periodic fill-and-down cycle developed in the steam generator U-tubes has been observed in the IIST measured data of oscillatory differential pressure across the steam generator. This phenomenon is not simulated in the calculation. However, the calculated differential pressure will follow the experimentalmore » trend and agree qualitatively with the measured data averaged over one fill-and-down cycle. As shown in the comparison of the calculated and experimental data, the overall system responses to the loss-of-RHR system event during midloop operation can be appropriately simulated by the current RELAP5/MOD3 model.« less

Published

1996

24. A Comparison of the RELAP5/MOD3 Code with the IIST Natural Circulation Experiments

Author

Chien-Hsiung Lee and Yuh-Ming Ferng

Subjects

Nuclear and High Energy Physics, Natural convection, Computer program, 020209 energy, Boiler (power generation), Boiler feedwater, 02 engineering and technology, Mechanics, Nuclear reactor, Condensed Matter Physics, law.invention, Coolant, 020303 mechanical engineering & transports, Natural circulation, 0203 mechanical engineering, Nuclear Energy and Engineering, law, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Nuclear chemistry

Abstract

A series of experiments dealing with variable secondary-side cooling conditions have been conducted at the IIST facility, including the natural circulation experiments under the secondary-side conditions of normal feedwater, loss of feedwater, and full of air. Different cooling conditions at the secondary side directly affect the primary-to-secondary heat transfer and then may influence the heat removal capability of natural circulation in the primary system. The corresponding analytical work is performed using the RELAP5/MOD3 code. Good agreement is reached both qualitatively and quantitatively between the experimental data and calculated results, demonstrating the satisfactory assessment of RELAP5/MOD3 code compared with the IIST natural circulation experiments. The cooling conditions at the secondary side have no significant effect on the heat removal capability of natural circulation as long as sufficient coolant exists on the steam generator secondary side, based on current IIST data and analytical results. Continuous increase of the core temperature and system pressure is also demonstrated experimentally and analytically in the test with the secondary side dry for the sake of deficient heat transfer capability at the steam generator secondary system.

Published

1995

25. Numerical simulation of natural circulation experiments conducted at the IIST facility

Author

Chien-Hsiung Lee and Yuh-Ming Ferng

Subjects

Nuclear and High Energy Physics, Engineering, Computer simulation, business.industry, Mechanical Engineering, Nuclear engineering, System pressure, Mechanical engineering, Power level, Current (stream), Natural circulation, Nuclear Energy and Engineering, General Materials Science, Safety, Risk, Reliability and Quality, business, Waste Management and Disposal

Abstract

Natural circulation plays an important role in long-term cooling of pressurized water reactors (PWRs) under small break loss-of-coolant accidents. Recently, natural circulation experiments have been conducted at the Institute of Nuclear Energy Research integral system test (IIST) facility, which is used to simulate the Westinghouse three-loop Maanshan PWR. A numerical simulation is presented to investigate the natural circulation phenomena of the IIST facility with the RELAP5/MOD3 code. The calculated results are in good agreement with the experimental data of the single-phase natural circulation both quantitatively and qualitatively. The influences of power level and system pressure on natural circulation can also be predicted by the current model. Based on the two-phase natural circulation data, the calculated flow rate history is similar to that obtained from the experiment.

Published

1994

26. Design and Performance Analysis of a Solid Oxide Fuel Cell/Gas Turbine (SOFC/GT) Hybrid System Used in Combined Cooling Heating and Power System

Author

Chen-Yin Lin Lin, Hsueh-I Tan, Hsiao-Wei D. Chiang, Wen-Tang Hong, Chih-Neng Hsu, Wu-Bin Huang, Chien-Hsiung Lee, and Wei-Ping Huang

Subjects

Engineering, business.industry, Nuclear engineering, Mechanical engineering, Refrigeration, law.invention, Electric power system, Operating temperature, law, Waste heat, Hybrid system, Absorption refrigerator, Solid oxide fuel cell, Hybrid power, business

Abstract

With high efficiency and very low emissions, fuel cells have been one of the choices of research in current energy development. The Solid Oxide Fuel Cell (SOFC) is a high temperature type fuel cell. It has the characteristic of very high operating temperature 1,027°C (1,300K). The SOFC has the main advantage of very high performance efficiency (over 50%), but also has very high exhaust temperature. Current studies point out that the combination of SOFC and Gas Turbine (GT) can produce efficiency more than 60%. The exhaust temperature of this hybrid power system can be as high as 227–327°C (500–600K). With this waste heat utilized, we can further improve the overall efficiency of the system. A simulation program of SOFC/GT system and the introduction of the concept of Combined Cooling, Heating, and Power System (CCHP) have been used in this study. The waste heat of SOFC/GT hybrid power generation system was used as the heat source to drive an Absorption Refrigeration System (ARS) for cooling. This waste heat enables the SOFC/GT to generate electricity in the system while providing additional cooling and heating capacity. Therefore, we have a combined CCHP system developed using three major modules which are SOFC, GT, and ARS modules. The SOFC module was verified by our test data. The GT and SOFC/GT modules were compared to a commercial code and literature data. Both the single- and double-effect ARS modules were verified with available literature results. Finally, the CCHP analysis simulation system, which combines SOFC, GT, and ARS, has been completed. With this CCHP configuration system, the fuel usability of the system by our definition could be above 100%, especially for the double effect ARS. This analysis system has demonstrated to be a useful tool for future CCHP designs with SOFC/GT systems.Copyright © 2011 by ASME

Published

2011

27. Experimental investigation of flow transient critical heat flux at light water reactor conditions

Author

Kuo-Wei Lin and Chien-Hsiung Lee

Subjects

Materials science, Critical heat flux, General Chemical Engineering, Flow (psychology), Pressurized water reactor, Thermodynamics, Mechanics, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, law.invention, law, Boiling water reactor, Mass velocity, Light-water reactor, Transient (oscillation)

Abstract

An experimental investigation of flow transient critical heat flux (CHF) for water at pressures 6.9 and 15.5 MPa is conducted under the simulation of both Boiling Water Reactor (BWR) and Pressurized Water Reactor (PWR) conditions. The influence of flow decay rates on local mass velocity and quality at CHF is explored to ensure the adequacy of local-condition approach in the CHF predictions. The assesment of transient upstream correction factor to modify the predictions of steady-state CHF correlations during the BWR flow transients are presented. A mechanistic CHF model based on the dryout of a sublayer and CHF correlations are evaluated in the predictions of PWR flow transient CHF.

Published

1993

28. Bundle Critical Power Predictions under Normal and Abnormal Conditions in Pressurized Water Reactors

Author

Bau-Shei Pei, Chien-Hsiung Lee, and Wen-Shan Lin

Subjects

Nuclear and High Energy Physics, Materials science, Critical heat flux, 020209 energy, Flow (psychology), Pressurized water reactor, 02 engineering and technology, Mechanics, Nuclear reactor, Condensed Matter Physics, law.invention, Thermal hydraulics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Nuclear Energy and Engineering, Heat flux, law, Bundle, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering

Abstract

In this paper a new approach to bundle critical power predictions is presented. In addition to a very accurate critical heat flux (CHF) model, correction factors that account for the effects of grid spacers, heat flux non-uniformities, and cold walls, which are needed for critical power predictions for practical fuel bundles, are developed. By using the subchannel analysis code COBRA IIIC/MIT-1, local flow conditions needed as input to CHF correlations are obtained. Critical power is therefore obtained iteratively to ensure that the bundle power value from the subchannel analysis will cause CHF at only one point in the bundle. Good agreement with the experimental data is obtained. The accuracy is higher than that of the W-3 and EPRI-1 correlations for the limited data base used in this study. The effects of three types of fuel abnormalities, namely, local heat flux spikes, local flow blockages, and rod bowing, on bundle critical power are also analyzed. The local heat flux spikes and flow blockages have no significant influence on critical power. However, rod bowing phenomena have some effect, the severity of which depends on system pressure, the gap closure between adjacent rods, and the presence or absence of thimble tubes (cold walls).more » A correlation for the influence of various rod bowing phenomena on bundle critical power is developed. Good agreement with experimental data is shown.« less

Published

1992

29. A transient natural convection in an annular enclosure

Author

Yi-Horng Jou, Chien-Hsiung Lee, and Wu-Shung Fu

Subjects

Physics, Natural convection, General Chemical Engineering, Enclosure, Thermodynamics, Power law scheme, Rayleigh number, Radius, Mechanics, Condensed Matter Physics, Nusselt number, Atomic and Molecular Physics, and Optics, Physics::Fluid Dynamics, Cross section (physics), Adiabatic process

Abstract

A transient natural convection in an annular enclosure is investigated numerically. The upper and lower walls are adiabatic, the outer wall is maintained at a low temperature and the temperature of the inner wall is changed to a high value abruptly. During the computing process, the numerical method of SIMPLE-R with power law scheme is adopted to solve the axially-symmetric governing equations of the continuity, momentum and energy. The Rayleigh number of 104 and 106 are considered, respectively. Since the area of the annular cross section enlarges with the increasing of the radius, the phenomena occurring in the annular enclosure are different from those occurring in the rectangular enclosure. In addition, the results show that in the initial region the variations of the total Nusselt of the inner wall rebounds under Rayleigh number of 106 case and does not fluctuate under Rayleigh number of 104 case, which are similar to those of the rectangular enclosure.

Published

1991

30. A low-cost equalizer-based auto-gain-control scheme for high-speed transceiver applications

Author

Chien-Hsiung Lee, Hsin-Shih Wang, and J.J. Lai

Subjects

Intersymbol interference, Engineering, Noise, Interference (communication), business.industry, Control system, Fast Ethernet, Local area network, Electronic engineering, Automatic gain control, Transceiver, business

Abstract

Traditional approaches of auto-gain control (AGC) need to collect long period of data and estimate the average power. It results in the large hardware complexity. Moreover, the accuracy of traditional approaches will be seriously degraded by noise and inter-symbol interference (ISI). In this paper, we propose an equalizer-based auto-gain control (EQ-AGC), which employs very small hardware and does not use extra memory devices. Furthermore, the AGC can find out the accuracy gain under large ISI environment. Our EQ-AGC is already silicon-proven for the application of fast Ethernet transceiver using Faraday/UMC 0.18/spl mu/m cell libraries.

Published

2005

31. New fully differential HF CMOS op amps with efficient common mode feedback

Author

Chung-Yu Wu, Ming-Kai Tsai, Ping-Hsing Lu, and Chien-Hsiung Lee

Subjects

Engineering, Signal generator, business.industry, Electrical engineering, Differential amplifier, Signal, law.invention, Distortion (music), CMOS, law, Hardware_INTEGRATEDCIRCUITS, Operational amplifier, Electronic engineering, business, Electronic circuit, Voltage

Abstract

Conventional fully differential HF CMOS operational amplifiers (op amps) use an extra circuit to perform common-mode feedback (CMFB), which results in signal distortion and/or asymmetry as the signal swing increases. To solve this problem, two fully differential CMOS op amps that are based on merging two single-ended-output op amps are proposed and analyzed. Through the inherent differential-to-single-ended conversion circuitry, CMFB can be efficiently performed without extra circuits. The output signals are not distorted, and the HF performance is not degraded. Simulation and experimental results have confirmed the performance of the proposed new op amps. >

Published

2003

32. A serial link transceiver for USB2 high-speed mode

Author

Shyh-Jye Jou, Tim Liu, Chien-Hsiung Lee, Shu-Hua Kuo, Jui-Ta Chiu, and Chu King

Subjects

business.industry, Computer science, Serial communication, USB, Synchronization, law.invention, CMOS, law, Personal computer, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Bandwidth (computing), Transceiver, business, Computer hardware, Clock recovery

Abstract

The Universal Serial Bus (USB) technology is now becoming an integral part of the personal computer platform. In this paper, the transceiver architecture and circuits are proposed and implemented for USB2 high-speed mode with 480 Mb/s bandwidth. This physical layer of USB2 consists of transmitter, receiver, two envelope detectors and an all-digital clock recovery/data synchronization blocks. It has been implemented with UMC 0.35 /spl mu/m 1P4M 3.3 V CMOS technology and consumes only 156 mW.

Published

2002

33. Experimental Study on the Performance of IIST Passive Core Cooling System

Author

Wen-Tan Hong, Chin-Jang Chang, Chien-Hsiung Lee, and Lance L. C. Wang

Subjects

Engineering, Core cooling, Cabin pressurization, Accident management, Water storage tank, business.industry, law, Nuclear power plant, Structural engineering, Hydraulic accumulator, business, Coolant, law.invention

Abstract

The purpose of this study is to conduct the experiments at the Institute of Nuclear Energy Research (INER) Integral System Test (IIST) facility for evaluation of the performance of the passive core cooling system (PCCS) during the cold-leg small break loss-of-coolant accidents (SBLOCAs). Five experiments were performed with (1) three different break sizes, 2%, 0.5%, and 0.2% (approximately corresponding to 1 1/4”, 2”, and 4” breaks for Maanshan nuclear power plant), and (2) 0.2% and 0.5% without actuation of the first-stage and third-stage automatic depressurization valve (ADS-1 and ADS-3) to initiate PCCS for assessing its capacity in accident management. The detailed descriptions of general system response and the interactions of core makeup tanks (CMTs), accumulators (ACCs), automatic depressurization system (ADS), passive residual heat Removal (PRHR), and in-containment refueling water storage tank (IRWST) on the core heat removal are included. The results show: (1) core long term cooling can be maintained for all cases following the PCCS procedures, (2) the core can be covered for the cases of the 0.2% and 0.5% breaks without actuation of ADS-1 and ADS-3.Copyright © 2002 by ASME

Published

2002

34. Mathematical Model Predicting the Critical Heat Flux of Nuclear Reactors

Author

Chien-Hsiung Lee, Lih-Wu Hourng, Kuo-Wei Lin, Chien-Hsiung Lee, Lih-Wu Hourng, and Kuo-Wei Lin

Abstract

Boiling heat transfer system keeps a nuclear power plant safe without getting over-heated. Crisis will occur if the dissipated heat flux exceeds the critical heat flux value. This study assumes the flow boiling system at high heat flux is characterized by the existence of a very thin liquid layer, known as the &#34sublayer&#34, which is trapped between the heated surface and the vapor blankets. In the present study, it is hypothesized that the heat transfer through the liquid sublayer is dominated by the heat conduction and the sublayer is dried out due to occurrence of Helmholtz instability as the relative velocity of the vapor blanket to the local liquid in the sublayer reaches a critical value. By recognizing this hypothesis, a theoretical model for low-quality flow is developed to predict boiling heat transfer and Critical Heat Flux (CHF). To verify the validity of the present model, the predictions are compared with the experimental data of flow boiling heat transfer in the simulation of Pressurized Water Reactor (PWR) and Boiling Water Reactor (BWR) conditions. For the PWR low-quality flow, the comparison demonstrates that the Helmholtz instability is the trigger condition for the onset of CHF.

Published

2012

35. DEVELOPMENT OF DYNAMIC SAFETY MODEL FOR THE APPLICATION OF PWR MIDLOOP OPERATION

Author

Chin-Jang Chang, Chun-Chang Chao, Shib-Kuei Chen, Kuo-Shing Liang, and Chien-Hsiung Lee

Published

1997

36. A low-cost equalizer-based auto-gain-control scheme for high-speed transceiver applications.

Author

Lai, J.J., Chien-Hsiung Lee, and Hsin-Shih Wang

Published

2005

37. ICONE11-36446 ASSESSMENT OF THE RELAP5-3D CODE Against An IIST 0.5% COLD LEG SBLOCA EXPERIMENT WITH PASSIVE SAFETY INJECTION

Author

Chien Hsiung Lee, Chin Jang Chang, Hua Jiun Young, and Lance L. C. Wang

Subjects

Engineering, Engineering drawing, business.industry, Code (cryptography), Structural engineering, business

Published

2003

38. Numerical investigation into premixed hydrogen combustion within two-stage porous media burner of 1 kW solid oxide fuel cell system.

Author

Tzu-Hsiang Yen, Wen-Tang Hong, Yu-Ching Tsai, Hung-Yu Wang, Cheng-Nan Huang, Chien-Hsiung Lee, and Bao-Dong Chen

Subjects

FOSSIL fuels, SOLID oxide fuel cells, COMBUSTION, UPPER air temperature distribution, HEATING equipment, INTEGRATED gasification combined cycle power plants, TURBULENCE, HEAT exchangers, COMPUTER simulation

Abstract

Numerical simulations are performed to analyze the combustion of the anode off-gas / cathode off-gas mixture within the two-stage porous media burner of a 1 kW solid oxide fuel cell (SOFC) system. In performing the simulations, the anode gas is assumed to be hydrogen and the combustion of the gas mixture is modeled using a turbulent flow model. The validity of the numerical model is confirmed by comparing the simulation results for the flame barrier temperature and the porous media temperature with the corresponding experimental results. Simulations are then performed to investigate the effects of the hydrogen content and the burner geometry on the temperature distribution within the burner and the corresponding operational range. It is shown that the maximum flame temperature increases with an increasing hydrogen content. In addition, it is found that the burner has an operational range of 1.2~6.5 kW when assigned its default geometry settings (i.e. a length and diameter of 0.17 m and 0.06 m, respectively), but increases to 2~9 kW and 2.6~11.5 kW when the length and diameter are increased by a factor of 1.5, respectively. Finally, the operational range increases to 3.5~16.5 kW when both the diameter and the length of the burner are increased by a factor of 1.5. [ABSTRACT FROM AUTHOR]

Published

2010

39. SOFC Development at INER.

Author

Chien-Hsiung Lee, Maw-Chwain Lee, Chang-Sing Hwang, Ruey-Yi Lee, and Li-Fu Lin

Subjects

NUCLEAR energy, SOLID oxide fuel cells, DIRECT energy conversion, ENERGY development, ECONOMIC development

Abstract

The article explores the development of solid oxide fuel cell (SOFC) at the Institute of Nuclear Energy Research (INER) in Taiwan. The goal of the INER SOFC project is to establish the technologies and equipment for the fabrication of cell, stack and demonstrative system. It is concluded that Taiwan lacks the supply of indigenous energy, but the SOFC system is considered as a potential technology to promote energy security, environmental protection and economic growth

Published

2007

40. Joint AGC-Equalization Algorithm and VLSI Architecture for Wirelined Transceiver Designs.

Author

(Justin) Lai, Jyh-Ting, (Andy) Wu, An-Yeu, and Chien-Hsiung Lee

Subjects

AUTOMATIC gain control, CONTROL theory (Engineering), AUTOMATIC control systems, AMPLITUDE modulation, DATA transmission systems

Abstract

Traditional approaches of automatic gain control (AGC) involve estimating the average power or the peak amplitude over an extended time period, which results in high hardware complexity and a long processing time. Moreover, the accuracy of traditional approaches is seriously degraded by noise and intersymbol interference. In this paper, we propose a joint AGC and equalization (Joint AGC-EQ) scheme, in which the AGC circuitry comprises only one-tenth of the area of a traditional AGC. In addition, the total convergence time of the proposed Joint AGC-EQ is only half that of traditional blind equalization. The scheme is already silicon proven for the application of a Fast Ethernet transceiver using Faraday/UMC 0.18-µm cell libraries. [ABSTRACT FROM AUTHOR]

Published

2007

41. IIST PASSIVE CORE COOLING ON PRESSURIZER TOP BREAK.

Author

Tay-Jian Liu and Chien-Hsiung Lee

Subjects

*COOLING, *PRESSURIZED water reactors, *VALVES, *NUCLEAR energy

Abstract

Two experiments for a small-break loss-of-coolant accident on a pressurizer top were conducted at the Institute of Nuclear Energy Research (INER) Integral System Test (IIST)facility to investigate the thermal-hydraulic behavior of a passive core cooling system (PCCS) in a Westinghouse pressurized water reactor (PWR). The test results are compared with previous IIST tests under the same initial and boundary conditions for a power operated relief valve (PORV) stuck-open incident. The objectives of this study are to understand the key thermal hydraulic phenomena associated with the PCCS and to compare the effectiveness of accident management with or without the PCCS. The break sizes are scaled down based on one and all three fully opened PORVs for a conventional PWR without the PCCS. This paper identifies the key phenomena commonly observed and the phenomena unique to a PWR with a PCCS. [ABSTRACT FROM AUTHOR]

Published

2004

42. A Theoretical Critical Heat Flux Model for Rod Bundles Under Pressurized Water Reactor Conditions

Author

I. A. Mudawwar, Bau-Shei Pei, Wen-Shan Lin, and Chien-Hsiung Lee

Subjects

Nuclear and High Energy Physics, Materials science, Critical heat flux, 020209 energy, Pressurized water reactor, Flow (psychology), Thermodynamics, 02 engineering and technology, Mechanics, Condensed Matter Physics, law.invention, Physics::Fluid Dynamics, Subcooling, Helmholtz instability, 020303 mechanical engineering & transports, 0203 mechanical engineering, Nuclear Energy and Engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Tube (fluid conveyance)

Abstract

A theoretical critical heat flux (CHF) model based on microlayer dryout and Helmholtz instability for subcooled tube flow under pressurized water reactor operation conditions is first extended to t...

Published

1989

43. Authors

Author

Alireza Haghighat, Anthony J. Baratta, D. N. Sah, C. S. Viswanadham, Sunil Kumar, P. R. Roy, Ge-Ping Yu, Bau-Shei Pei, Ying-Pang Ma, Todd K. Campbell, Edgar Robert Gilbert, George D. White, Gregory F. Piepel, Bernard J. Wrona, John F. Geldard, Adolph L. Beyerlein, Masaki Suwa, Atsuyuki Suzuki, Tsutomu Sakurai, Akira Takahashi, Niro Ishikawa, Yoshihide Komaki, Wen-Shan Lin, Chien-Hsiung Lee, I. A. Mudawwar, Thomas M. Parker, Richard J. Kohrt, Sue I. Dederer, Larry E. Hochreiter, Walter R. Schwarz, Chon-Kwo Tsai, Michael Y. Young, Khalid A. Al-Hussan, Tien-Ko Wang, and Mohamed A. Obeid

Subjects

Nuclear and High Energy Physics, Nuclear Energy and Engineering, Condensed Matter Physics

Published

1989

44. An Improved Theoretical Critical Heat Flux Model for Low-Quality Flow

Author

Bau-Shei Pei, Chien-Hsiung Lee, and Wen-Shan Lin

Subjects

Nuclear and High Energy Physics, Critical heat flux, Chemistry, 020209 energy, Flow (psychology), Thermodynamics, 02 engineering and technology, Condensed Matter Physics, Helmholtz instability, 020303 mechanical engineering & transports, Quality (physics), 0203 mechanical engineering, Nuclear Energy and Engineering, Heat flux, Boiling, 0202 electrical engineering, electronic engineering, information engineering

Abstract

Based on the Helmholtz instability at the microlayer/vapor interface as a trigger condition for microlayer dryout, Lee and Mudawwar developed a mechanistic critical heat flux (CHF) model for subcoo...

Published

1989

45. Authors

Author

Gunji Nishio, Kazuichiro Hashimoto, T. J. Liaw, Chin Pan, Gen-Shun Chen, Jung-Kue Hsiue, Rosanna Chambers, Duane J. Hanson, R. Jack Dallman, Fuat Odar, Hoju Moon, Samuel H. Levine, Moussa Mahgerefteh, Tatsutoshi Inagaki, Hiroyuki Kuga, Masao Suzuki, Tsugio Yokoyama, Mitsuaki Yamaoka, Kunikazu Kaneto, Masahisa Ohashi, Kunitoshi Kurihara, Jean Mégy, Robert Harold Allardice, Klaus Ebert, Jean-Marie Morelle, Paolo Venditti, Mrs. Shakila Abdul Majeed, Thandangorai Ganapathi Srinivasan, Kanwal Nain Sabharwal, Wen-Shan Lin, Chien-Hsiung Lee, Bau-Shei Pei, Hassan E. S. Fath, Makarem A. Hussein, Carol A. Jaeger, Eric R. Ellis, Thomas F. Parkinson, and DeeEarl Vaden

Subjects

Nuclear and High Energy Physics, Nuclear Energy and Engineering, Condensed Matter Physics

Published

1989

46. New fully differential HF CMOS op amps with efficient common mode feedback.

Author

Chung-Yu Wu, Ping-Hsing Lu, Chien-Hsiung Lee, and Ming-Kai Tsai

Published

1989