Control system design for a pressure-tube-type supercritical water-cooled nuclear reactor via a higher order sliding mode method

Nuclear power plants exhibit non-linear and time-variable dynamics.Therefore,designing a control system that sets the reactor power and forces it to follow the desired load is complicated.A supercritical water reactor(SCWR)is a fourth-generation conceptual reactor.In an SCWR,the non-linear dynamics of the reactor require a controller capable of control-ling the nonlinearities.In this study,a pressure-tube-type SCWR was controlled during reactor power maneuvering with a higher order sliding mode,and the reactor outgoing steam temperature and pressure were controlled simultaneously.In an SCWR,the temperature,pressure,and power must be maintained at a setpoint(desired value)during power maneuvering.Reactor point kinetics equations with three groups of delayed neutrons were used in the simulation.Higher-order and classic sliding mode controllers were separately manufactured to control the plant and were compared with the PI controllers speci-fied in previous studies.The controlled parameters were reactor power,steam temperature,and pressure.Notably,for these parameters,the PI controller had certain instabilities in the presence of disturbances.The classic sliding mode controller had a higher accuracy and stability;however its main drawback was the chattering phenomenon.HOSMC was highly accurate and stable and had a small computational cost.In reality,it followed the desired values without oscillations and chattering.

Sliding Mode Predictive Control of Main Steam Pressure in Coal-fired Power Plant Boiler

Since the combustion system of coal-fired boiler in thermal power plant is characterized as time varying, strongly coupled, and nonlinear, it is hard to achieve a satisfactory performance by the conventional proportional integral derivative (PID) control scheme. For the characteristics of the main steam pressure in coal-fired power plant boiler, the sliding mode control system with Smith predictive structure is proposed to look for performance and robustness improvement. First, internal model control (IMC) and Smith predictor (SP) is used to deal with the time delay, and sliding mode controller (SMCr) is designed to overcome the model mismatch. Simulation results show the effectiveness of the proposed controller compared with conventional ones.

Analysis and Calculation of the Flow Pressure in the Multipoint Steam Injection String of a Horizontal Well

The multipoint steam injection string of the horizontal well is a commonly used downhole component for high efficiency steam injection of the thermal recovery horizontal well. A reasonable layout of the valves to ensure an even steam output of each point is still not well designed. At present, a general design method which is urgently necessary isn＇ t applied by each factory. According to the balance relationship of the momentum, the energy and the mass of the fluid flowing in the string, the pressure distribution equation of the fluid flowing in the multipoint steam injection string is built. On the basis of this equation, the design calculation method of the multipoint steam injection string is come up with. A specific example is given in the paper. Study shows that, with the equation built in this paper, the string can be designed with each axial valve having the same output, so that the technical demand of an even steam injection of the horizontal well section can be met.

Response characteristics of PWR primary circuit under SBLOCAs considering steam bypass discharging

Small-break superposed station blackout(SBO)accidents are the basic design accidents of nuclear power plants.Under the condition of a small break in the cold leg,SBO further increases the severity of the accident,and the steam bypass discharg-ing system(GCT)in the second circuit can play an important role in guaranteeing core safety.To explore the influence of the GCT on the thermal-hydraulic characteristics of the primary circuit,RELAP5 software was used to establish a numerical model based on a typical pressurized water reactor nuclear power plant.Five different small breaks in the cold-leg super-posed SBO were selected,and the impact of the GCT operation on the transient response characteristics of the primary and secondary circuit systems was analyzed.The results show that the GCT plays an indispensable role in core heat removal during an accident;otherwise,core safety cannot be guaranteed.The GCT was used in conjunction with the primary safety injection system during the placement process.When the break diameter was greater than a certain critical value,the core cooling rate could not be guaranteed to be less than 100 K/h;however,the core remained in a safe state.

Calculation of the Choked Back Pressure for Steam Turbines with Air Cooled Condensers

The choked back pressure characteristic of the steam turbine unit with air cooled condenser is very different with the unit with wet cooling technology, and the understanding of the choked back pressure performance change with operation load is important to guide the economic operation of the unit. One simplified Variable Operation Condition Analysis Method was put forward for calculation of the unit output-turbine back pressure characteristics. Based on this method, the choked back pressure for each operation load can be determined. An example was given for a super-critical, regenerative single-shaft, 2-casing with 2-exhaust steam turbine generation unit with air cooled condenser. The calculation result was provided and compared with the result of the unit with wet cooling technology.

Experimental study on steam-water two-phase flow frictional pressure drops in helical coils

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Verification of Integrity of Steam Generator Tubes by Pressure Testing

This paper assessed the benefit of the in-situ pressure test to support steam generator tube integrity assessment and reviewed a conservatism of currently applied structural integrity assessment methodology against defected tubes. According to the steam generator program requirement, condition monitoring assessment was performed to the all detected flaws. For condition monitoring assessments, the limiting structural integrity requirement should be demonstrated for all detected degraded tubes at a probability of at least 0.95 at 50% confidence. Some flaws were slightly exceeded the structural integrity threshold values of the condition monitoring performance limits using analytical method. As a direct evaluation of tube integrity with degraded tubes, in-situ pressure testing performed on some selected flaws and passed all proof and leakage test criteria with no leakage. From this pressure testing, the authors have verified that degraded tubes met a specified value containing a defined safety margins. Also, the authors have confirmed that existing structural assessment methodology has enough margins to retain integrity of steam generator tubes.

Prediction of Boiler Drum Pressure and Steam Flow Rate Using Artificial Neural Network

Numerical simulation of complex systems and components by computers is a fundamental phase of any modern engineering activity. The traditional methods of simulation typically entail long, iterative processes which lead to large simulation times, often exceeding transient real time. Artificial neural networks （ANNs） may be advantageous in this context, the main advantage being the speed of computation, the capability of generalizing from the few examples, robustness to noisy and partially incomplete data and the capability of performing empirical input-output mapping without complete knowledge of underlying physics. In this paper, the simulation of steam generator is considered as an example to show the potentialities of this tool. The data required for training and testing the ANN is taken from the steam generator at Abott Power Plant, Champaign （USA）. The total number of samples is 9600 which are taken at a sampling time of three seconds. The performance of boiler （drum pressure, steam flow rate） has been verified and tested using ANN, under the changes in fuel flow rate, air flow rate and load disturbance. Using ANN, input-output mapping is done and it is observed that ANN allows a good reproduction of non-linear behaviors of inputs and outputs.

Research on the steam–gas pressurizer model with Relap5 code

Steam–gas pressurizers are self-pressurizing, and since steam and noncondensable gas are used to sustain their pressure, they experience very complicated thermal–hydraulic phenomena owing to the presence of the latter. A steam–gas pressurizer model was developed using Relap5 code to investigate such a pressurizer's thermal–hydraulic characteristics.The important thermal–hydraulic processes occurring in the pressurizer model include bulk flashing, rainout, wall condensation with noncondensable gas, and interfacial heat and mass transfer. The pressurizer model was verified using results from insurge experiments performed at the Massachusetts Institute of Technology. It was found that noncondensable gas was one of the important factors governing the pressure response, and the accuracy of the developed model would change with different mass fractions and types of noncondensable gas.

Solution of Coal Char-steam Pressurized Kinetic Parameters Based on Atmospheric Thermo Gravimetric Analyzer

根据文献中气化速率对总压不敏感、对反应气体分压敏感的实验结论，探索利用常压热重实验得到加压动力学参数的便捷方法。采用NETZSCH STA449F3同步热分析仪进行4种煤焦与水蒸气反应的常压热重实验（水蒸气分压pH2O为0.016~0.053 MPa），通过实验数据处理，获得反应速率与温度、水蒸气分压的关系式，分别以 n 级速率方程和Langmuir-Hinshelwood （LH）速率方程表示，并对上述关系式在水蒸气分压为0.057~0.063 MPa 的工况下进行了实验验证。随着水蒸气分压增大，计算结果与实验数据的相对误差逐渐减小。LH速率方程比n级速率方程更适合描述水蒸气分压的作用。水蒸气分压对反应速率的影响程度随水蒸气分压升高而减小。温度对煤焦-水蒸气反应速率的影响程度大于水蒸气分压对反应速率的影响。温度范围较窄时，煤种本身引起的煤焦反应活性变化幅度会超过温度对煤焦反应活性的影响。在不同的温度和水蒸气分压下，煤种的化学反应活性强弱次序会发生变化，某一特定工况下的次序不能未加实验而随意扩展到其他工况。

Development and Installation of High Pressure Boilers for Co-Generation Plant in Sugar Industries

The sugar cane containing minimum 30% fiber was referred as bagasse and used the generation of power required for the operation of sugar mill. The bagasse is fired in the boiler for producing steam at high pressure, which is extracted through various single high capacity turbines and used in the process. The installation of high pressure boilers and high pressure turbo-generators has provision for the operation of co-generation plant during the off-season also that enhances the power generation from 9MW to 23MW. The annual monetary benefits achieved are Rs. 204.13 million and this was based on cost of power sold to the grid @ Rs 2.548 per unit, sugar season of 219 days and off season of 52 days. This required an investment of Rs 820.6 million. The investment had an attractive simple payback period of 48 months.

基于MPGW分布的压力蒸汽灭菌器可靠性分析

浴缸形状的失效率函数因其能够捕捉某些实际情境中的故障率特征,在机械结构可靠性分析中至关重要。引入一种修正广义幂威布尔(Modified Power Generalized Weibull,MPGW)分布,能够建模表征浴缸形状的失效率变化规律。为评估该模型的有效性,本研究使用了压力蒸汽灭菌器故障数据集进行实证研究,并将其性能与5种经典分布模型进行了比较,发现该模型在灵活性上具有较大优势。

乏汽供热用大型蒸汽射汽器性能试验与研究

对乏汽供热用大型射汽器的性能进行了全面分析和研究。结合射汽器的固有特性,在300 MW等级机组的乏汽供热系统中对射汽器变工况性能进行了试验研究,得到了不同机组背压、动力蒸汽压力和出口压力下射汽器的性能曲线。建立了一种射汽器全工况特性的性能参数求解方法。结果表明:性能参数求解结果与试验数据吻合度高。

3种灭菌方式对磁外科器件磁通量的影响及灭菌成本分析

目的 分析压力蒸汽、低温等离子及环氧乙烷3种灭菌方式对磁外科器件磁通量的影响及其灭菌成本。方法234件不同规格型号磁外科器件-磁环,配对编号标记后随机分为A组、B组和C组,每组78件(39对),其中A组使用压力蒸汽灭菌,B组使用低温等离子灭菌,C组使用环氧乙烷灭菌,每对器件按灭菌规范进行包装;测量3组磁环灭菌前后磁通量,对单包灭菌成本和灭菌时间比较分析。结果 3种灭菌方式对磁外科器件磁通量的影响差异无统计学意义(P>0.05),每种灭菌方式灭菌前后的磁通量有统计学差异(P<0.001);灭菌成本:A组为(1.96±0.16)元,B组(23.17±0.32)元、C组(8.16±0.18)元,差异有统计学意义(P<0.01);灭菌时间:A组为(65.21±3.36)min, B组(45.46±1.39)min, C组(1 020.38±12.21)min,差异具有统计学意义(P<0.01)。结论 3种灭菌方式对磁外科器件的磁通量没有影响。压力蒸汽灭菌法单包成本最低,低温等离子单包灭菌成本最高,环氧乙烷灭菌时间最长。压力蒸汽应为磁外科手术器件的首选灭菌方法。

溶剂低压过热蒸汽热裂解塑料制油过程特性

低碳清洁处理塑料垃圾对环境保护和循环经济发展具有重要意义。本文提出了一种在低压过热溶剂蒸汽体系中高效热裂解液化塑料的方法,以聚丙烯(PP)和高密度聚乙烯(HDPE)为原料,研究了塑料在溶剂低压过热蒸汽环境中(≤5MPa)热裂解液化过程特性,并提出了两种塑料热液化过程中的降解机制。结果表明:低压有机溶剂蒸汽体系能在相对温和的条件下实现塑料的高效液化,330℃是本研究中实现塑料快速热裂解液化的起始温度。在此温度下,PP在甲醇、乙醇、丙酮中的热裂解液化率均为100%,HDPE在三种溶剂中的热裂解液化率分别为100%、72.9%和71.03%。在本研究条件下,塑料液化中小分子更容易发生缩聚反应,放出大量热并使反应体系温度出现不同幅度的飞升,从而为塑料进一步解聚为小分子提供能量,提高塑料的热裂解液化率。PP热裂解液化油中含氧化合物的质量分数大于40%,而HDPE的热裂解液化油中氧化物含量低,且烃类的质量分数大于80%,作为燃料使用的潜力大。

蒸汽射流直接接触凝结的界面及声压特性

蒸汽射流在液体中的直接接触凝结引发的剧烈界面振荡及声压振荡,可能导致工业管道系统振动甚至失效,采用高速摄像机与高频水听器,捕捉了射流的界面演化行为及其诱导的声压。研究了3种典型凝结流型下射流界面的径向、轴向振荡与声压振荡特性,并阐明声压振荡产生机理。研究发现:声压波动的概率密度函数在间歇流型下呈左偏单峰分布,在界面振荡流型下呈双峰分布,而在稳定流型下呈对称单峰分布;随蒸汽质量流速升高,无量纲径向、轴向界面振荡强度及声压振荡强度整体呈下降趋势,表现出极强的相关性。建立了基于声压参数的射流喷射长度预测模型,预测值与实验值的误差在±1%内。概率密度及相关性分析结果表明,蒸汽射流凝结的声压振荡是由其界面振荡引起的。

基于不同统计模型对压力蒸汽灭菌器故障数据集的可靠性分析

目的:基于医院压力蒸汽灭菌器的故障数据,分析评估医疗机构中压力蒸汽灭菌器的可靠性。方法:利用威布尔分布(Weibull分布)、指数分布(Exponential分布)、对数-正态分布(Log-Normal分布)和q-威布尔分布(q-Weibull分布)4种统计模型对压力蒸汽灭菌器的故障数据进行分析,并使用图表工具展示不同分布统计模型在拟合数据时的性能。结果:4种统计模型对比显示,Log-Normal分布统计模型的修正赤池信息准则为564.4512,贝叶斯准则(568.7691)值最低,柯尔莫哥洛夫-斯米尔诺夫(KS)统计量(0.0739)最小,P值最大(P>0.05),表明分布拟合效果最好,最适合用于分析压力蒸汽灭菌器故障数据集的模型。结论:通过使用不同统计模型对压力蒸汽灭菌器故障数据的可靠性分析,可以为临床工程师优化压力蒸汽灭菌器维护策略提供依据。

16m双柱立车在核电汽轮机低压内缸研制中的必要性分析

本文根据自主型核电汽轮机低压内缸结构、尺寸、重量、精度,加工现状,以及核电汽轮机发展趋势和市场前景,提出了添制16 m双柱立车在核电汽轮机低压内缸研制中的必要性,同时拟定了机床的主要技术参数。

自主核电汽轮机低压内缸研制技术探究

为了提高在制自主核电汽轮机低压内缸研制水平,文章对缸的设计结构、制造工艺、加工机床等环节进行了深入剖析,拟定出缸的结构优化、工艺完善、立车改造方案,有效提高了缸的研制质量,大幅降低了缸的研制费用。先进的技术方案、优良的经济效果,为机组进一步抢占国内外市场和公司目前推进的智能制造创出了一条新思路。

油田注汽锅炉产汽单耗的计算方法与影响因素分析

为有效降低油田注汽锅炉产汽单耗,通过系统分析油田注汽锅炉生产工艺、生产设备、能耗水平及产汽单耗的计算方法,确定影响产汽单耗水平的关键因素包括温度、压力、干度、过热度、运行管理水平、锅炉热效率等,对各项因素的影响效果进行了分析验证。采用实际测试结果与理论计算数据对比的方法,得出了常见工况下油田注汽锅炉产汽单耗的变化规律,在此基础上明确了注汽锅炉节能提效的重点方向和技术措施,分析各项措施提效降耗的基本效果,对油田注汽锅炉的节能提效、降低产汽单耗和企业生产成本提供了良好借鉴。