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1. Experimental study on the retention of aerosol particles through concrete cracks under high Reynolds number flow

Author

Hui Wang, Zhongning Sun, Haifeng Gu, Ji Xing, Xiaohui Sun, Xueyao Shi, and Bin Zhao

Subjects
Severe accident, Aerosol retention, Concrete cracks, High Reynolds number flow, Nuclear engineering. Atomic power, TK9001-9401
Abstract

In the event of severe accidents in pressurized water reactor (PWR) nuclear power plants, the potential leakage of radioactive aerosols through containment cracks poses a considerable radioactive hazard to the public. Understanding aerosol transport and retention in cracks helps reduce the conservatism and uncertainty of radioactive hazard assessment. Concrete cracks are recognized as a pivotal pathway for the leakage of radioactive aerosols, and several researchers have undertaken experimental investigations concerning the aerosol transport and retention in concrete cracks. However, the majority of these studies have rather low gas flow Reynolds numbers. In this work, an experimental setup is built to study aerosol transport and retention in concrete cracks under high Reynolds number flow. The TiO2 aerosol with a mass median diameter of 1 μm and two concrete crack specimens are used in experiments. The results of gas flow experiments indicate that the Reynolds number is capable of reaching 10547. Combining the flow experimental data and Suzuki's formula, the equivalent heights of these two crack specimens are approximated as 303.67 μm and 231.48 μm. The experimental results indicate a notably high retention rate of aerosols, exceeding 0.8. Furthermore, under high Reynolds number flow, the retention rate varies over a relatively narrow range, with the larger the equivalent height of the crack resulting in a lower retention rate. The experimental results match well with the mechanistic analysis based on inertial deposition theory, demonstrating the rationality of the inertial deposition theory.

Published
2024
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2. Experiment investigation on flow characteristics of open natural circulation system

Author

Xiangjie Qi, Zichen Zhao, Peng Ai, Peng Chen, Zhongning Sun, and Zhaoming Meng

Subjects
Open natural circulation, Flashing, Boiling eruption, Flow characteristics, Unstable area distribution, Nuclear engineering. Atomic power, TK9001-9401
Abstract

Experimental research on flow characteristics of open natural circulation system was performed, to figure out the mechanism of the open natural circulation behaviors. The influence factors, such as the heating power, the inlet subcooled and the level of cooling tank on the flow characteristics of the system were examined. It was shown that within the scope of the experimental conditions, there are five flow types: single-phase stable flow, flash and geyser coexisting unstable flow, flash stable flow, flash unstable flow, and flash and boiling coexisting unstable flow. The geyser flow in flash and geyser coexisting unstable flow is different from classic geysers flow. The flow oscillation period and amplitude of the former are more regular, is a newly discovered flow pattern. By drawing the flow instability boundary diagram and sorting out the flow types, it is found that the two-phase unstable flow is mainly characterized by boiling and flash, which determine the behavior of open natural circulation respectively or jointly. Moreover, compared with full liquid level system, non-full liquid level system is more prone to boiling phenomenon, and the range of heat flux density and undercooling degree corresponding to unstable flow is larger.

Published
2022
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3. Scaling analysis of the pressure suppression containment test facility for the small pressurized water reactor

Author

Xinxing Liu, Xiangjie Qi, Nan Zhang, Zhaoming Meng, and Zhongning Sun

Subjects
Scaling analysis, Small PWR, Top-down, Bottom-up, H2TS, Nuclear engineering. Atomic power, TK9001-9401
Abstract

The small PWR has been paid more and more attention due to its diversity of application and flexibility in the site selection. However, the large core power density, the small containment space and the rapid accident progress characteristics make it difficult to control the containment pressure like the traditional PWR during the LOCA. The pressure suppression system has been used by the BWR since the early design, which is a suitable technique that can be applied to the small PWR. Since the configuration and operating conditions are different from the BWR, the pressure suppression system should be redesigned for the small PWR. Conducting the experiments on the scale down test facility is a good choice to reproduce the prototypical phenomena in the test facility, which is both economical and reasonable. A systematic scaling method referring to the H2TS method was proposed to determine the geometrical and thermohydraulic parameters of the pressure suppression containment response test facility for the small PWR conceptual design. The containment and the pressure suppression system related thermohydraulic phenomena were analyzed with top-down and bottom-up scaling methods. A set of the scaling criteria were obtained, through which the main parameters of the test facility can be determined.

Published
2021
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4. Experimental and Numerical Study on the Gravitational Deposition and Coagulation of Aerosols

Author

Huiyu Yu, Haifeng Gu, Zhongning Sun, Yanmin Zhou, Junyan Chen, and Yingzhi Li

Subjects
gravitational deposition, coagulation, COSTTHES, GDE, aerosol, General Works
Abstract

The gravitational deposition and coagulation of aerosols were studied experimentally based on the COSTTHES (Containment Source-Term and Thermal Hydraulics Experiment System) facility and numerically investigated based on a continuous general dynamic equation; the experimental and the numerical results were in good agreement. In the present study, the applicability of the zero-dimensional model for deposition and coagulation of aerosols was verified. A considerable distortion can occur due to the coagulation of the aerosol, which significantly influenced the removal rate of the aerosol with a diameter greater than 0.76 µm, and the dynamic shape factor value of the aerosol used in the present experiment was obtained as 4. In the experimental and numerical studies, it was found that the combined effect of the gravitational deposition and coagulation of the aerosol can increase the number density of the aerosol with specific diameters, and the concentration-increment size would increase as settling continued.

Published
2022
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5. Scaling Design of the Pressure Response Experimental Facility for Pressure Suppression Containment

Author

Xinxing Liu, Zhaoming Meng, Nan Zhang, and Zhongning Sun

Subjects
pressure suppression containment, scaling experiment, pressure response, MELCOR, pipe resistance, Science
Abstract

Pressure suppression containment has been adopted extensively in boiling water reactor design due to its remarkable pressure suppression capacity. To study the pressure response characteristics of the containment in the initial stage of the loss-of-coolant accident, it is necessary to build a scaling facility to simulate the prototype. Analysis of the steam mass and energy that are released from the break as well as of the steam condensation that occurs in the suppression pool is conducted, respectively, for the prototype pressurized water reactor. The suppression pipe system resistance is also scaled with a certain ratio. The length and diameter of the main pipe and the branch pipe as well as the orifice diameter are calculated. At last, the prototype and the experimental facility are modeled by MELCOR to analyze the steam mass and energy release. The results show that the containment pressure evolution trends of the prototype and the scaled experimental facility are consistent. The pressure difference exists at some times, with a maximum relative error of 4%.

Published
2020
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6. Numerical Study of the Influence of Tube Arrangement on the Flow Distribution Inside the Heat Exchanger in the PCCS

Author

Jian Zhou, Yanwei Yue, Zhaoming Meng, and Zhongning Sun

Subjects
flow distribution, tube arrangement, central-type, compact, pressure loss, General Works
Abstract

Passive containment cooling system (PCCS) is widely applied in a new generation of nuclear power plants. The initial heat exchanger is the most improtant heat transfer device in the PCCS. Past studies show that the flow distribution has a great influence on the heat transfer performance of a heat exchanger. And a lot of work has been done on improving the flow distribution uniformity of the heat exchanger such as the geometry modification, proper choice of the geometry parameters. However, little work has been done on the tube arrangement. For a heat exchanger applied in the industry, the number of tubes are huge, and it is unrealistic to arrange all the tubes in a row on the one side of the heat exchanger. Therefore, more work should be paid on the influence of the tube arrangement on the flow distribution in the heat exchanger. The present study numerically investigated the effect of the tube arrangement on the flow distribution in a Central-type parallel heat exchanger. Six different kinds of tube arrangement have been investigated on the flow distribution and the pressure loss characteristics of the heat exchanger. The obtained results show that the tube arrangement has a great influence on the flow distribution and the staggered tube arrangement provides a better flow distribution than the aligned tube arrangement.

Published
2020
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7. Preliminary Experimental Investigation on the Filtration Performance of Submicron Insoluble Aerosol in a Bubble Column

Author

Yingzhi Li, Kaiyi Shi, Zhongning Sun, Haifeng Gu, and Yanmin Zhou

Subjects
insoluble aerosol, operation parameter, filtration efficiency, bubble column, pool scrubbing, General Works
Abstract

Pool scrubbing is a representative process for aerosol retention involved in severe LWR accidents and has proved to be a potential method for the removal of micron-sized aerosols. Bubble scrubbing, as the key component of pool scrubbing, has the advantages of a large gas-liquid contact area and long residence time. However, the filtration mechanism of submicron aerosol by bubble scrubbing is still not clear. Therefore, the goal of this research is to evaluate the filtration performance of submicron insoluble aerosol in a bubble column. Some preliminary experiments were carried out to investigate the influence of operational parameters on aerosol filtration efficiency, such as inlet aerosol concentration, gas flow rate and pool temperature. Mass method was used to analyze the aerosol filtration efficiency. The results show that the aerosol filtration efficiency is independent of inlet aerosol concentration when inlet aerosol concentration is in the range of 0.2–0.5 g/m3. Besides the aerosol filtration, efficiency is influenced by the superficial gas velocity. With the increase of superficial gas velocity, homogeneous bubbling, transition and a heterogeneous bubbling regime will appear in turn. The aerosol filtration efficiency decreases in the transition regime due to the appearance of large bubbles but increases in the heterogeneous bubbling regime account for intense gas-liquid interaction. Moreover, the aerosol filtration efficiency significantly decreases with pool temperature because the evaporation rate at the gas-liquid interface will significantly increase as the boiling point is approached, which gives retroaction to aerosol filtration efficiency.

Published
2019
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8. Study on Calculation Method of Soluble Aerosol Removal Efficiency Under High Humidity Condition

Author

Yingzhi Li, Qianchao Ma, Zhongning Sun, Haifeng Gu, Yanmin Zhou, and Kaiyi Shi

Subjects
soluble aerosol, hygroscopic growth, removal efficiency, pool scrubbing, FCVS, General Works
Abstract

Pool scrubbing is a potential method to remove aerosol particles under accident conditions of nuclear power plants. The relative humidity of aerosol laden gas will increase significantly when passing through the water pool, which will most likely induce hygroscopic growth of soluble aerosol. The hygroscopic growth of soluble aerosol can lead to the deviation of the size distribution of aerosol at the outlet of the water pool, resulting in a large evaluation error of the removal efficiency. In order to solve this problem, the size distributions of sodium chloride at the upstream and downstream of bubble column were measured at a gas flow rate of 4 lpm and a liquid height of 80 cm, respectively. Two methods of calculating aerosol actual size-dependency removal efficiency were proposed and compared. One method is directly calculating the removal efficiency by adding a diffusion drying tube installed at the upstream of Scanning Mobility Particle Sizer (SMPS) to reduce the relative humidity of sample gas below the efflorescence point. Another method is modifying the aerosol size distribution and concentration curve by using the hygroscopic growth theory of soluble aerosols. The experiment results obtained by the two methods are in good agreement.

Published
2019
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9. Reducing the Flow Distribution in Central-Type Compact Parallel Flow Heat Exchangers Having Optimized Tube Structure

Author

Jian Zhou, Ming Ding, Zhaoming Meng, Yinxing Zhang, and Zhongning Sun

Subjects
flow maldistribution, pressure maldistribution, manifolds, central-type heat exchanger, uniformity, General Works
Abstract

Compact parallel manifolds are widely applied in flow heat exchangers. However, the flow maldistribution exists in the parallel manifolds when the flow is distributed in the header, because of the pressure maldistribution. For a heat exchanger, the uniformity of the flow distribution greatly influence the performance of the heat exchanger. It is significantly important to modify the design of the heat exchanger for a uniform flow distribution. In present study, to reduce the maldistribution in the manifolds, the numerical analysis has been made and a method by varying the insert length of tubes inside the header has been pointed out to solve this problem of flow maldistribution. To illustrate the reliability of this method to reduce the maldistribution, three base cases with different header diameters have been applied to be solved with the method. The results indicates that, by using the method, the maldistribution for three base cases can be reduced by 82% for the case1, 72% for the case2 and 68% for the case3. However, the insert length of tubes inside the header increases more pressure loss. The pressure drop for base cases are respectively increased by 2.83, 4.83, and 6.46%. This method is proved to be effective under all flow rates.

Published
2018
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10. Measurement for Surface Tension of Aqueous Inorganic Salt

Author

Jiming Wen, Kaiyi Shi, Qiunan Sun, Zhongning Sun, and Haifeng Gu

Subjects
surface tension, aqueous inorganic, solid aerosol suspension liquid, filtered contain venting system, bubble column, General Works
Abstract

Bubble columns are effective means of filtration in filtered containment venting systems. Here, the surface tension has a significant influence on bubble size distribution and bubble deformation, which have a strong impact on the behavior of the bubble column. The influence of aqueous inorganic compounds on the surface tension depends on the electrolytic activity, Debye length, entropy of ion hydration, and surface deficiencies or excess. In this work, the surface tensions of same specific aqueous solutions have been measured by different methods including platinum plate method, platinum ring method, and maximum bubble pressure method. The measured surface tensions of both sodium hydroxide and sodium thiosulfate are less than that of water. As solution temperature ranges from 20 to 75°C, the surface tension of 0.5 mol/L sodium hydroxide solution decreases from 71 to 55 mN/m while that of 1 mol/L solution decreases from 60 to 45 mN/m. Similarly during the same temperature range, the surface tension of 0.5 mol/L sodium thiosulfate decreases from 70 to 38 mN/m, and that of 1 mol/L sodium thiosulfate is between 68 and 36 mN/m. The analysis for the influence mechanism of aqueous inorganic on surface tension is provided. In addition, experimental results show that the surface tension of solid aerosol suspension liquid has no obvious difference from that of distilled water.

Published
2018
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11. Study on the Behaviors of a Conceptual Passive Containment Cooling System

Author

Jianjun Wang, Xueqing Guo, Shengzhi Yu, Baowei Cai, Zhongning Sun, and Changqi Yan

Subjects
Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The containment is an ultimate and important barrier to mitigate the consequences after the release of mass and energy during such scenarios as loss of coolant accident (LOCA) or main steam line break (MSLB). In this investigation, a passive containment cooling system (PCCS) concept is proposed for a large dry concrete containment. The system is composed of series of heat exchangers, long connecting pipes with relatively large diameter, valves, and a water tank, which is located at the top of the system and serves as the final heat sink. The performance of the system is numerically studied in detail under different conditions. In addition, the influences of condensation heat transfer conditions and containment environment temperature conditions are also studied on the behaviors of the system. The results reveal that four distinct operating stages could be experienced as follows: startup stage, single phase quasisteady stage, flashing speed-up transient stage, and flashing dominated quasisteady operating stage. Furthermore, the mechanisms of system behaviors are thus analyzed. Moreover, the feasibility of the system is also discussed to meet the design purpose for the containment integrity requirement. Considering the passive feature and the compactness of the system, the proposed PCCS is promising for the advanced integral type reactor.

Published
2014
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13. Experiment investigation on flow characteristics of open natural circulation system

Author

Zhongning Sun, Zhaoming Meng, Peng Chen, Ai Peng, Xiangjie Qi, and Zichen Zhao

Subjects
geography, geography.geographical_feature_category, Mechanics, Inlet, Physics::Fluid Dynamics, Subcooling, Flash (photography), Natural circulation, Nuclear Energy and Engineering, Flow (mathematics), Heat flux, Boiling, Environmental science, Supercooling
Abstract

Experimental research on flow characteristics of open natural circulation system was performed, to figure out the mechanism of the open natural circulation behaviors. The influence factors, such as the heating power, the inlet subcooled and the level of cooling tank on the flow characteristics of the system were examined. It was shown that within the scope of the experimental conditions, there are five flow types: single-phase stable flow, flash and geyser coexisting unstable flow, flash stable flow, flash unstable flow, and flash and boiling coexisting unstable flow. The geyser flow in flash and geyser coexisting unstable flow is different from classic geysers flow. The flow oscillation period and amplitude of the former are more regular, is a newly discovered flow pattern. By drawing the flow instability boundary diagram and sorting out the flow types, it is found that the two-phase unstable flow is mainly characterized by boiling and flash, which determine the behavior of open natural circulation respectively or jointly. Moreover, compared with full liquid level system, non-full liquid level system is more prone to boiling phenomenon, and the range of heat flux density and undercooling degree corresponding to unstable flow is larger.

Published
2022

16. Research progress of hydrogen behaviors in nuclear power plant containment under severe accident conditions

Author

Haozhi Bian, Ming Ding, Feng Liu, and Zhongning Sun

Subjects
Hydrogen, Renewable Energy, Sustainability and the Environment, business.industry, Process (engineering), Nuclear engineering, Energy Engineering and Power Technology, chemistry.chemical_element, Condensed Matter Physics, Combustion, Experimental research, law.invention, Fuel Technology, chemistry, Containment, Coupling effect, law, Nuclear power plant, Environmental science, business, Risk management
Abstract

Severe accident in a water-cooled nuclear power plant may lead to the production and release of hydrogen. If hydrogen forms flammable gas with air and steam in the containment, it may trigger more serious hydrogen explosion accident, threaten the integrity of the equipment and the containment. The behavioral characteristics of hydrogen under severe accident conditions become primarily responsible for the assessment of combustion risk. This review paper first identifies and describes various key physical phenomena associated to hydrogen behavior in the containment during a severe accident from four main aspects, including the source of hydrogen, hydrogen transport, combustion, and risk mitigation. The typical release process of hydrogen, the combustion limits of hydrogen and main risk mitigation measures are clarified comprehensively. Moreover, representative experimental facilities, related tests and key conclusions are introduced emphatically, which can provide specific guidance for future and ongoing related experimental research. Additionally, through the analysis of corresponding typical simulation studies based on LP method and CFD method, numerical methods suitable for various key phenomena are summarized and recommended. Currently, associated models realized in codes have limitations for predicting hydrogen behavior under certain conditions, which are mainly derived from the coupling effect of complex factors such as condensation, jets, and flame propagation, etc. The applicability and uncertainty of the models in these situations still need to be further evaluated and developed.

Published
2021

18. Experimental Research on the Retention Characteristics of Hydrophilic and Hydrophobic Aerosols in Jet Regime

Author

Qianchao Ma, Yanmin Zhou, Haifeng Gu, Zhongning Sun, and Jinghao Yang

Abstract

Aerosol is one of the main forms of fission products in nuclear reactor accidents, which are derived from direct leakage of solid fission products and homogeneous and heterogeneous nucleation of gaseous fission products. Pool scrubbing may reduce the leakage of radioactive aerosol, and it is vital for the prediction of radioactivity to accurately grasp the retention efficiency. In this paper, experimental research on aerosol retention characteristics in jet regime was carried out. Titanium dioxide and cesium iodide were used to simulate radioactive aerosols with different hydrophilicity, and the retention efficiency under different inlet pressure and aerosol size was obtained. The results show that the retention efficiency of aerosol increases significantly while the inlet pressure increases from 43 kPa to 110 kPa. While the inlet pressure is higher than 110 kPa, the retention efficiency still increases with the increase of inlet pressure, although the increasing trend is not obvious. The most easily permeable range of cesium iodide aerosol is smaller than that of titania aerosol, and the retention efficiency of cesium iodide aerosol is always higher than that of titania aerosol, which may be caused by hydrophilicity. However, with the increase of stokes number, the difference of retention efficiency between the two aerosols gradually decreases. The difference between different aerosols was analyzed in this paper and it was found that the influence of hydrophilicity was negatively correlated with stokes number. The results of this research can be used to assist the validation of pool scrubbing model.

Published
2022

19. Experimental Study on the Relationship Between Performance and Structural Parameters of Metal Fiber

Author

Lintai Li, Yanmin Zhou, Yuanyuan Li, Zhongning Sun, Yin Wang, Haifeng Gu, and Song Ma

Abstract

As a new filter material, metal fiber has good high-temperature resistance, moisture resistance, and radiation resistance. To explore the influence of the fiber’s primary structural parameters on the fiber’s performance, this paper experimentally studied the relationship between the flow resistance, filtration efficiency, and dust holding capacity of the metal fiber filter material and the thickness and solid volume fraction (SVF). Under the condition of ensuring uniform deposition of NaCl aerosol, we found that the deposition law of NaCl polydisperse aerosol is the same as that of monodisperse aerosol. The results show that for the same fiber diameter, increasing the fiber’s thickness and SVF will increase the flow resistance of the fiber under the same dust holding capacity; that is, reducing the dust holding capacity of the fiber. In the depth filtration, the efficiency increases rapidly due to the aerosol deposition in the fiber, while the efficiency changes gently when the filter cake is covered on the filtration surface. At the same time, for each high filtration efficiency fiber, the variation characteristics of resistance with dust holding capacity in the deep filtration stage are the same. After the filter cake is completely covered on the filter surface, the growth trend of resistance is the same, independent of the fiber’s structural parameters.

Published
2022

20. Study on Numerical Simulation Method of Unsteady Deposition Characteristics of Particles in Surface Filtration

Author

Song Ma, Zhongning Sun, Yanmin Zhou, Haifeng Gu, and Lintai Li

Abstract

As an important part of the ventilation system of nuclear facilities, the performance of filter is of great significance to the environment and personnel safety. With the operation of the filter, the filtration mode will change from depth filtration to surface filtration. In this paper, a numerical simulation method is developed for the unsteady deposition characteristics of particles in the surface filtration. The parcel injection model is applied to accelerate the formation and growth process of dust cake on the surface of fiber filter. A series of subroutines running in FLUENT environment are developed to enhance the capabilities of computational fluid dynamics code in ANSYS. The Brownian force is added to the DPM model to calculate the particle trajectory more accurately. The function that aerosol particles are intercepted and deposited on the surface of fiber filter to form dust cake is added. The porous media model is used to simulate the fiber filter and dust cake. The porosity and resistance coefficient change with the unsteady deposition of particles. Combined with the subroutine with FLUENT software, a numerical simulation method which can be used to predict the unsteady deposition characteristics of particles in the surface filtration is formed. The numerical simulation results are compared with the experimental results, and they are basically consistent. So the developed numerical simulation method can be used to predict the unsteady deposition characteristics of particles in the surface filtration, and can also provide a theoretical basis for the structural design of pleated filter.

Published
2022

21. Numerical Investigation on Transport Characteristics of Hydrogen-Air-Steam Mixture Induced by Condensation in the Single Compartment

Author

Feng Liu, Zhongning Sun, Haozhi Bian, and Ming Ding

Abstract

Under the severe accident of the nuclear power plant, hydrogen-steam mixture gas will be released into the containment compartments. In this process, there is a strong coupling relationship between mixture gas diffusion and steam condensation on the compartment wall surface. Especially for local compartments with poor connectivity, steam condensation is likely to aggravate the risk of hydrogen accumulation and combustion. This coupling phenomenon, which has not been systematically studied in previous numerical simulations or experiments, is especially complex and needs to be further studied. Moreover, the applicability of mechanistic numerical models for predicting condensation-induced transient gas transport processes also should be further confirmed. In this study, the mechanistic numerical model was evaluated through the transient hydrogen mixing experiment of the THAI facility. Based on the validated model, the transient mass transfer process of the mixture gas induced by condensation in a typical single compartment during the steam-hydrogen release process is studied. Furthermore, the influence of release condition of gas source term, wall sub-cooling on the hydrogen accumulation phenomenon in the compartment was discussed. The conclusion is helpful to further understand the transport behavior of hydrogen-air-steam mixture gas in the local single compartment under the severe accident.

Published
2022

22. Research on the Influence of Water Tank Liquid Level on Low Pressure Two-Phase Open Natural Circulation Flow and Heat Exchange

Author

Shengnan Zhang, Zhongning Sun, and Nan Zhang

Abstract

In order to study the influence of the water level of the water tank on the flow instability and heat transfer character istics,which is of the low-pressure two-phase open natural circulation system. The open natural circulation system was numerically simulated and experimentally verified. Numerical simulations are calculated by using a homogeneous flow model in this study, The flow rate and heat removal power of the system under different water level conditions were calculated and recorded, and the trend of changing with the water level was obtained. The results were then compared with the experimental results. It shows that the calculated open natural circulation flow and heat removal power results are consistent with the experimental. As the liquid level decreases, the flow state of the system gradually changes from the periodic flashing state inside the adiabatic section to the stable flashing operating state, and the heat exchange power also increases gradually. times. Therefore, in the low-pressure system, reducing the liquid level of the water tank can achieve a good effect of enhancing the flow stability of the low-pressure two-phase open natural circulation, and also has a good effect on the improvement of the heat removal power of the system.

Published
2022

23. Scaling analysis of the pressure suppression containment test facility for the small pressurized water reactor

Author

Xiangjie Qi, Zhaoming Meng, Zhongning Sun, Xinxing Liu, and Nan Zhang

Subjects
H2TS, Small PWR, 020209 energy, Nuclear engineering, Site selection, Scaling analysis, 02 engineering and technology, 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, 0302 clinical medicine, Conceptual design, law, 0202 electrical engineering, electronic engineering, information engineering, Scaling, Flexibility (engineering), Test facility, Pressurized water reactor, Top-down, lcsh:TK9001-9401, Nuclear Energy and Engineering, Containment, Environmental science, lcsh:Nuclear engineering. Atomic power, Bottom-up, Scale down
Abstract

The small PWR has been paid more and more attention due to its diversity of application and flexibility in the site selection. However, the large core power density, the small containment space and the rapid accident progress characteristics make it difficult to control the containment pressure like the traditional PWR during the LOCA. The pressure suppression system has been used by the BWR since the early design, which is a suitable technique that can be applied to the small PWR. Since the configuration and operating conditions are different from the BWR, the pressure suppression system should be redesigned for the small PWR. Conducting the experiments on the scale down test facility is a good choice to reproduce the prototypical phenomena in the test facility, which is both economical and reasonable. A systematic scaling method referring to the H2TS method was proposed to determine the geometrical and thermohydraulic parameters of the pressure suppression containment response test facility for the small PWR conceptual design. The containment and the pressure suppression system related thermohydraulic phenomena were analyzed with top-down and bottom-up scaling methods. A set of the scaling criteria were obtained, through which the main parameters of the test facility can be determined.

Published
2021

29. Experimental Investigation on the Pressure Oscillations Induced by Subsonic Steam Jets Under Different Vessel Pressures

Author

Xinxing Liu, Mingrui Yu, Wei Li, Pei Yu, Zhaoming Meng, Zhongning Sun, Nan Zhang, and Ming Ding

Subjects
Nuclear and High Energy Physics, History, Nuclear Energy and Engineering, Polymers and Plastics, Mechanical Engineering, General Materials Science, Business and International Management, Safety, Risk, Reliability and Quality, Waste Management and Disposal, Industrial and Manufacturing Engineering
Published
2022

31. Air Horizontal Jets into Quiescent Water

Author

WeiChao Li, Zhaoming Meng, and Zhongning Sun

Subjects
History, Polymers and Plastics, Business and International Management, Industrial and Manufacturing Engineering
Published
2022

38. Deposition characteristic of micro-nano soluble aerosol under bubble scrubbing condition

Author

Zhongning Sun, Haifeng Gu, Yingzhi Li, and Yanmin Zhou

Subjects
Range (particle radiation), Materials science, 020209 energy, Bubble, 02 engineering and technology, Residence time (fluid dynamics), 01 natural sciences, 010305 fluids & plasmas, Aerosol, Volumetric flow rate, Deposition (aerosol physics), Nuclear Energy and Engineering, Chemical engineering, 0103 physical sciences, Micro nano, 0202 electrical engineering, electronic engineering, information engineering, Data scrubbing
Abstract

Bubble scrubbing is recommended as a potential way to remove aerosol under accident conditions not only because of its sufficient specific transfer area and considerable residence time but also the feasibility of the concept. The purpose of this paper is to illuminate the effect of operating parameters such as liquid height, gas flow rate on micro-nano soluble aerosol deposition characteristic under bubble scrubbing condition. The results indicate that a strong hygroscopic growth phenomenon happened under bubble scrubbing condition. A direct effect is change in deposition mechanism and the deviation of MPPS. Liquid height can significantly improve the removal efficiency of micro-nano aerosol and present a more obvious influence on inertial-dominant aerosol than Brownian one. The increase of gas flow rate can weaken the deposition efficiency in range of 0–0.6 m3/h but will reverse to enhancement effect when exceeding 0.6 m3/h.

Published
2019

39. Mean porosity variations in packed bed of monosized spheres with small tube-to-particle diameter ratios

Author

Xiaxin Cao, Zehua Guo, Ming Ding, Nan Zhang, and Zhongning Sun

Subjects
Packed bed, Materials science, General Chemical Engineering, Particle diameter, SPHERES, Tube (fluid conveyance), Composite material, Transport phenomena, Porosity, Reactor design
Abstract

The transport phenomena in packed beds are sensitive to porosity variations. However, empirical correlations in the literature are not in agreement regarding the prediction of the mean porosity for packed beds, resulting in challenges for reactor design. In this study, the mean porosity variations in a densely packed bed with 1.2

Published
2019

40. Bubble growth in a boiling water-cooled packed bed reactor

Author

Zhongning Sun, Guangzhan Xu, and Xiaoning Zhang

Subjects
Mass flux, Packed bed, Nuclear and High Energy Physics, Materials science, Carbon steel, 020209 energy, Mechanical Engineering, Bubble, 02 engineering and technology, Growth curve (biology), Mechanics, engineering.material, 01 natural sciences, 010305 fluids & plasmas, Coolant, Physics::Fluid Dynamics, Nuclear Energy and Engineering, Boiling, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, engineering, General Materials Science, Safety, Risk, Reliability and Quality, Waste Management and Disposal, Glass tube
Abstract

The bubble growth in boiling water-cooled packed bed reactor were determined via experiments. Oxidized carbon steel balls were heated by electromagnetic induction method and packed in the glass tube with water as coolant. A high-speed camera was employed for the visualization study of bubble growth process. The effects of corner region, inlet temperature and mass flux on the bubble growth curve were analyzed, and bubble growth curve were proposed based on certain parameters. The results indicated that value predicted by bubble growth model is good agree with experimental data.

Published
2019

41. Bubble coalescence efficiency near multi-orifice plate

Author

Haifeng Gu, Qiunan Sun, Zhongning Sun, and Jiming Wen

Subjects
Coalescence (physics), Work (thermodynamics), Range (particle radiation), Environmental Engineering, Materials science, General Chemical Engineering, Bubble, Orifice plate, 02 engineering and technology, General Chemistry, Mechanics, 021001 nanoscience & nanotechnology, Biochemistry, Volumetric flow rate, Physics::Fluid Dynamics, 020401 chemical engineering, 0204 chemical engineering, 0210 nano-technology, Body orifice, Sparging
Abstract

Bubble coalescence reduces specific area and weakens the work performance of bubble column. The bubble coalescence near gas sparger which is caused mainly by bubble growing is different from the ones occurring in major liquid. Bubble coalescence efficiency near gas sparger is influenced by many factors including sparger configuration, gas flow rate, bubble deformation, solution composition, etc. This work has conducted a set of visual experiments to study the coalescence characteristics near multi-orifice plate. The experiment parameters cover a wide range of conditions including large scope of gas flow rate, different kinds of solution and orifice configurations. The experimental results suggest that coalescence time is applicable to reflect the influence of the pitch of orifices and gas flow rate on bubble coalescence efficiency. As the number of orifices increases, bubble coalescence efficiency is reduced by the disturbance from the bubbles at adjacent orifices. A hindering coefficient is used to consider the hindering effect of additives on bubble coalescence efficiency. Finally a new calculation expression is established to predict bubble coalescence efficiency near multi-orifice plate whose fundamental form is based on the logistic curve of binary response. The calculated values that refer to this calculation expression are well consistent with the experimental results.

Published
2019

42. Experimental investigation on thermal stratification induced by steam-air mixture vertical injection with shallow submergence depth

Author

Jianjun Wang, Zhongning Sun, Zhaoming Meng, Weichao Li, and Jiazhi Liu

Subjects
Mass flux, 020209 energy, food and beverages, Energy Engineering and Power Technology, 02 engineering and technology, Mechanics, 010501 environmental sciences, Thermal stratification, complex mixtures, 01 natural sciences, humanities, Plume, Nuclear Energy and Engineering, Water temperature, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Negative buoyancy, Safety, Risk, Reliability and Quality, Waste Management and Disposal, Air mass, 0105 earth and related environmental sciences
Abstract

A series of experiments have been performed to investigate thermal stratification induced by steam-air mixture vertical injection, in the range of steam mass flux 3–30 kg/m2s, air mass fraction 0–5% and submergence depth 100–300 mm. Experimental results show that: thermal stratification occurs at the region where none of chugging-induced synthetic jets, steam-driven negative buoyancy jets and plume is strong enough. For pure steam experiments, thermal stratification occurs when the steam mass flux above 15 kg/m2s. The pool is mixed well firstly, then thermally stratified, and then re-mixed in sequence, as the water temperature increases. A little air can make thermal stratification and re-mixing occur ahead of time and more air can completely remove thermal stratification. Gas bypass induced by shallow submergence depth makes thermal stratification occur earlier and more severe. The submergence depth has little effect on thermal stratification in chugging regime.

Published
2019

43. Influence of flow guiding conduit on pressure drop and convective heat transfer in packed beds

Author

Nan Zhang, Zhongning Sun, Zehua Guo, Yanmin Zhou, and Ming Ding

Subjects
Fluid Flow and Transfer Processes, Packed bed, Pressure drop, Materials science, Convective heat transfer, 020209 energy, Mechanical Engineering, 02 engineering and technology, Heat transfer coefficient, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Venturi effect, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Fluid dynamics, 0210 nano-technology, Transport phenomena
Abstract

Packed beds with large tube-to-particle diameter ratios (D/d) suffer from poor lateral heat transport. Consequently, for applications with internal heat generation, fluid with high temperature concentrates in the center of packed beds, which is unfavorable to the design of high efficiency reactors. To address this problem, a novel method is developed: a free channel—flow guiding conduit (FGC)—is constructed in the center of a packed bed using highly fluid-penetrable material. Therefore, in the presented work, CFD simulations are carried out to study the influences of FGC to a conventional packed bed on packing structure, fluid flow distribution as well as heat transfer. It shows that cold fluid with high velocities is guided directly into the original hot zones where fluid temperature is generally higher in a conventional packing. Fluid flow in the lateral direction can be promoted with the Venturi effect. Moreover, with the FGC in proper sizes, pressure drop can be reduced about 16–26%; heat transfer coefficients merely drop 4–6%. However, although favorable effects could be achieved using the FGC, it is also observed that if an oversized flow guiding conduit was imposed into a packed bed, loss of effective cooling for particles would be also resulted since excess fluid could bypass through the conduit. Consequently, unexpected fluid temperature distribution could get some recovery. These findings are helpful for understanding of transport phenomena in packed beds as well as the design of high efficiency reactors.

Published
2019

44. Experimental investigation on thermal stratification induced by steam direct contact condensation with non-condensable gas

Author

Jianjun Wang, Weichao Li, Yanmin Zhou, Zhongning Sun, Zhaoming Meng, and Jiaqing Liu

Subjects
Mass flux, Materials science, 020209 energy, Time evolution, Energy Engineering and Power Technology, Stratification (water), 02 engineering and technology, Mechanics, Thermal stratification, complex mixtures, Industrial and Manufacturing Engineering, Plume, 020401 chemical engineering, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Negative buoyancy, 0204 chemical engineering, Thermocline, Physics::Atmospheric and Oceanic Physics
Abstract

Thermal stratification induced by steam direct contact condensation is a significant technical concern to consider in the energy industry. Thirty experiments have been performed to investigate the effect of steam mass flux, bulk water temperature and air mass fraction on temperature distribution in the water pool. The condensation behavior and time evolution of temperature distribution are recorded and analyzed. Two condensation regimes of chugging and bubbling are observed. Three flow patterns, namely chugging-induced synthetic jets, steam-driven negative buoyancy jets and plume, are discussed. Three thermal patterns of mixing, stratification and re-mixing are identified. A small amount of air (1–2%) could make stratification pattern occur earlier and severer. The maximum vertical temperature difference is about 30 °C in pure steam experiments and 60 °C in mixture gas experiments. Re-mixing pattern occurs when the bulk water temperature is close to 80 °C. In addition, thermal penetration depth, the velocity of thermocline moving down and the thickness of thermocline are estimated through temperature data.

Published
2019

45. CFD analysis of fluid flow and particle-to-fluid heat transfer in packed bed with radial layered configuration

Author

Ming Ding, Zhongning Sun, Nan Zhang, Shuai Shi, and Zehua Guo

Subjects
Packed bed, Pressure drop, Materials science, Convective heat transfer, business.industry, Applied Mathematics, General Chemical Engineering, 02 engineering and technology, General Chemistry, Mechanics, Computational fluid dynamics, 021001 nanoscience & nanotechnology, Industrial and Manufacturing Engineering, Physics::Fluid Dynamics, 020401 chemical engineering, Flow velocity, Heat transfer, Fluid dynamics, Particle, 0204 chemical engineering, 0210 nano-technology, business
Abstract

The channeling effect at the container wall results in difficulties for heat transfer in the central part of packed beds with small tube-to-particle diameter ratios. To overcome this shortcoming, a new kind of packed bed is developed with radial layered configuration: a fluid-penetrable wire mesh is used to divide the container into two parts in the radial direction, which allows particles of different sizes for regional loading. Therefore, following the general rule of fluid flow distribution in packed beds, small particles could be filled in the zone at the container wall to restrain the channeling effect and large particles in the center to promote local heat transfer capacity. In the present work, to facilitate the proper functionality of new equipment using the novel method, a CFD simulation combined with the DEM method for random packing generation is conducted to study the characteristics of the new packed bed on the packing structure, fluid flow, and particles-to-fluid convective heat transfer under a high fluid velocity regime (Re ∼ 104). It finds that the new packing method could exhibit a much regular structure than the conventional packed beds. And outstanding performance is observed in pressure drop reduction and heat transfer efficiency improvement. Moreover, the well-known equations for pressure drop and convective heat transfer predictions are found not applicable to the new bed and distinctive features of fluid velocity and temperature distribution are identified. These findings are helpful for the design of high efficiency reactors.

Published
2019

46. Numerical investigations on steam condensation in the presence of air on external surfaces of 3 × 3 tube bundles

Author

Haozhi Bian, Zhaoming Meng, Nan Zhang, Zhongning Sun, and Ming Ding

Subjects
Work (thermodynamics), Materials science, Physics::Instrumentation and Detectors, 020209 energy, Heat transfer enhancement, Condensation, Energy Engineering and Power Technology, 02 engineering and technology, Mechanics, 010501 environmental sciences, 01 natural sciences, Diffusion layer, Boundary layer, Nuclear Energy and Engineering, Heat flux, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Tube (fluid conveyance), Safety, Risk, Reliability and Quality, Waste Management and Disposal, 0105 earth and related environmental sciences
Abstract

Previous investigations on steam condensation in the presence of air have revealed general heat transfer characteristics in vertical plates and single tubes. However, there remains limited knowledge regarding the thermal-hydraulic phenomena and heat transfer properties of tube bundles. In order to evaluate steam condensation on the external surfaces of tube bundles, STAR-CCM + code with a diffusion boundary layer steam condensation model was employed in this work. In the assessments, 3 × 3 tube bundles with various tube pitches (from 1.5d to 5d) were investigated, and the results were compared to those of a single tube. The data analyses mainly focused on three aspects: (i) global and local condensation phenomena in tube bundles; (ii) heat transfer characteristics in tube bundles; and (iii) influences of tube pitches and global parameters (such as pressure and air mass fraction) on the condensation heat transfer. The phenomena analyses indicate that the axial field profiles are mainly determined by the development of a concentration boundary layer, while the radial field profiles are mostly affected by the tube pitches. Local heat flux analyses indicate that the condensation heat flux exhibits a significant reduction downwards along the vertical tube. In comparison, the condensation heat flux fluctuates in the tube peripheral direction. In the latter case, heat transfer enhancement and inhibition regions are identified and classified. For the tube average heat transfer, only the central tube is significantly affected by the tube pitches, and the degradation may be more than 30% at a tube pitch of 1.5d. The tube pitch effect is almost independent of the bulk air mass fraction and changes slightly with an increase in the wall sub-cooling and bulk pressure.

Published
2019

47. Investigation on steam contact condensation injected vertically at low mass flux: Part I pure steam experiment

Author

Weichao Li, Jianjun Wang, Yanmin Zhou, Zhongning Sun, and Zhaoming Meng

Subjects
Fluid Flow and Transfer Processes, Mass flux, Materials science, Oscillation, Mechanical Engineering, Bubble, Condensation, Nozzle, Flux, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, complex mixtures, 01 natural sciences, 010305 fluids & plasmas, Vortex ring, Physics::Fluid Dynamics, Subcooling, 0103 physical sciences, 0210 nano-technology
Abstract

Steam direct contact condensation in subcooled water is an inevitable process in pressure suppression system of advanced light water reactor. Ten pure steam experiments have been performed in the range of steam mass flux 5–80 kg/m2 s and water temperature 19–96 °C. The steam condensation behave, fluid oscillation and pressure oscillation are recorded and analyzed. Prominent small bubbles are observed on the bubble surface due to the Rayleigh-Taylor instability. Vortex ring appears after aspherical bubble collapses. The upper threshold of chugging is identified by temperature data acquired continuously. The amplitude and frequency of fluid oscillation are obtained and compared with previous correlations. Two typical pressure wave shapes of continuous oscillation and pulse oscillation are identified. The pulse oscillation is induced by steam bubble collapse and observed at low water temperature. The maximum pressure pulse peak is about 1 MPa measured in the nozzle and 0.1 MPa in the pool. The pressure oscillation intensity in the water pool increases first, then decreases rapidly, and then increases slowly. It has a maximum at water temperature about 55–75 °C and the related temperature increases with the increment of the steam mass flux. The pressure oscillation dominant frequency is analyzed and compared with available correlations.

Published
2019

48. Computational study on fluid flow and heat transfer characteristic of hollow structured packed bed

Author

Nan Zhang, Ming Ding, Haozhi Bian, Zhaoming Meng, Zehua Guo, and Zhongning Sun

Subjects
Packed bed, Materials science, 020401 chemical engineering, General Chemical Engineering, Heat transfer, Fluid dynamics, Particle, 02 engineering and technology, Mechanics, 0204 chemical engineering, 021001 nanoscience & nanotechnology, 0210 nano-technology
Abstract

The development of advanced packed beds has remarkable applications in the design of new equipment for related industries. Recently, a hybrid of the structured and random packed beds is proposed—the hollow structured packed bed (HSPB), which can be easily formed with ordered ring structures and a free channel along the centerline by the particle self-assembly feature in a random packed bed at 2

Published
2019

49. The effect of multi-orifice plate configuration on bubble detachment volume

Author

Zhongning Sun, Jiming Wen, Haifeng Gu, and Qiunan Sun

Subjects
Environmental Engineering, Materials science, General Chemical Engineering, Bubble, Orifice plate, 02 engineering and technology, General Chemistry, Mechanics, 021001 nanoscience & nanotechnology, Biochemistry, Volumetric flow rate, Physics::Fluid Dynamics, 020401 chemical engineering, Volume (thermodynamics), Liquid bubble, 0204 chemical engineering, Aeration, 0210 nano-technology, Sparging, Body orifice
Abstract

The multi-orifice plate gas sparger, mainly composed of a multi-orifice plate and a gas chamber, is one of the most common sparger facilities. The aeration performance of multi-orifice plate has a close relation with the multi-orifice plate configuration. In addition, the weeping phenomenon has a considerable influence on the gas chamber condition which affects the bubble detachment volume directly. This paper conducts a set of visual experiments to study the influence of multi-orifice configuration and gas chamber condition on the aeration performance of gas sparger. For multi-orifice plate, an improved theoretical model is proposed which considers the wave effect of the previous bubbles generated from adjacent orifices and the variance of the number of active bubbling orifice. A parameter is proposed to evaluate the aeration performance in order to overcome the difficulty caused by the randomness of bubble formation process. The experimental results suggest that the gas chamber filled with water is in favor of large bubble formation. The influence of the pitch of orifice on aeration performance can only be observed in high-restricted case. According to the theoretical model and experimental results, the influences of gas flow rate and the number of open orifices on the aeration performance are analyzed and a design criterion for the number of open orifice is proposed.

Published
2019

50. Experimental investigations on pressure oscillation induced by steam-air mixture gas sonic jets in subcooled water

Author

Jiaqing Liu, Zhaoming Meng, Zhongning Sun, Weichao Li, and Jianjun Wang

Subjects
Fluid Flow and Transfer Processes, Jet (fluid), Materials science, Oscillation, Mechanical Engineering, Nozzle, Fraction (chemistry), 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Subcooling, 0103 physical sciences, Dynamic pressure, 0210 nano-technology, Intensity (heat transfer), Air mass
Abstract

Present paper aims to experimentally investigate pressure oscillation induced by steam-air mixture gas sonic jets in subcooled water. Dynamic pressure signals and jet images are recorded and analyzed. Experimental results show that: the pressure oscillation dominant frequency decreases with the rise of water temperature, inlet pressure and air mass fraction. Air mass fraction has a complex effect on pressure oscillation intensity. When water temperature is less than 55 °C, as the air mass fraction increases, the pressure oscillation intensity increases first, and then decreases slightly, and then increases quickly. When water temperature is more than 55 °C, as the air mass fraction increases, the pressure oscillation intensity decreases first, and then increases quickly. The interfacial fluctuation height and pressure oscillation intensity dependency to the air mass fraction is the same near the nozzle exit. In addition, the validity of previous analysis model for steam sonic jet pressure oscillation dominant frequency is evaluated. A modified function considering the effect of air mass fraction is developed. The predicted results of steam-air mixture gas sonic jet pressure oscillation dominant frequency agree well with the experimental results. More than 98% of the data points are inside the error band of ±20%.

Published
2019

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