2021年度新能源电力系统国家重点实验室开放研究课题申请指南(Open Fund Application Guidelines )
信息发布于:2020-11-25
新能源电力系统国家重点实验室依托华北电力大学,主要围绕新能源电力系统的重大科技问题,开展创新性基础研究和应用基础研究,为我国能源可持续发展以及新能源战略性新兴产业发展提供科技支撑。
The State Key Laboratory of Alternate Electrical Power System with Renewable Energy Source, established in the North China Electric Power University (NCEPU), is committed to carry out both fundamental and application researches on the key scien-tech issues concerning the alternate electrical power system so as to provide technological support for the energy sustainable development as well as the emerging new energy industry in China.
为充分发挥国家重点实验室科研平台的作用,促进科研合作和学术交流,实验室根据“开放、联合、流动、竞争”的运行机制设立开放课题。课题申请人须选定本室研究人员为联系人进行联合研究,以促进相关学科的相互交叉和集成。热忱欢迎和邀请相关领域的国内外科研人员来实验室进行合作研究,共同推动我国新能源电力系统领域科学与技术的发展。现发布《2021年度新能源电力系统国家重点实验室开放研究课题申请指南》如下:
The laboratory as a platform promoting scientific cooperation and academic exchange based on the mechanism of “open, cooperation, mobility, competition", has been setting up open fund annually. For domestic and overseas research specialists to carry out of associated studies with researchers of the Laboratory and to advance the integration of related disciplines and facilitate the scientific and technological development, we publish the “2021 Open Fund Application Guidelines” as follows:
一、资助方向Main Research Orientations and Recent Focuses
本年度立项课题将主要支持下列方向的研究。对于不直接属于这些范围,但具有重要科学意义的、有创意的项目,也将考虑择优支持。
The Lab mainly supports projects within the following research orientations and research focuses. Creative proposals that do not strictly pertain to the listed areas yet have important scientific values, preferential support might also be considered.
方向一:新能源高效转换与发电特性Research on High-efficiency Energy Conversion and Power Generation Characteristics
针对新能源发电的安全、高效与可靠运行,研究新型太阳能光电转换材料、器件和系统的理论及关键技术,发展大型海上风电系统的理论与关键技术,研究太阳能热发电系统耦合特性及集成调控技术,研究生物质高效热转换机理及发电技术,揭示太阳能、风能、生物质能发电过程机理及特性,构建智能新能源发电系统。
In view of the safe, efficient and reliable operation of new energy power generation, research on theories and key technologies of new photovoltaic conversion materials, devices and systems, developing theories and key technologies theory and key technologies of large scale wind turbine generator systems. Furthermore, research on the coupling characteristics and integrated control technology of solar thermal power generation systems and explore the efficient heat conversion mechanism of biomass and power generation technology, so as to reveal the mechanism and characteristics of solar, wind, and biomass power generation processes, and build a smart new energy power generation system.
近期研究重点Recent Research Focuses:
1.高效太阳能光电转换及光伏发电Efficient photovoltaic conversion of the solar energy and photovoltaic power generation
(1)研究新型太阳电池材料的设计、制备和应用,研究电池材料生长的热力学和动力学特性,研究材料结构、薄膜形貌构筑和界面调控及其对器件光伏性能的影响规律,实现对器件光电性能的有效调控;
Research on the design, preparation and application of new solar cells materials, study the thermodynamic and kinetic characteristics of solar cell material growth, research on the material structure, film morphology and interface regulation and its influence on the photovoltaic performance of the device, realizing the effective regulation on the device of photoelectric performance.
(2)研究大面积新型太阳电池的高效、高稳定制备及集成技术,研究大面积太阳电池中导致光电能量损失的关键问题,研究大面积薄膜的结构和光电特性调控方法;
Research on the high-efficiency, high-stability preparation and integration technology of large-area new solar cells, study the key issues that lead to photoelectric energy loss in large-area solar cells, and research on the structure of large-area thin films and the regulation method of photoelectric characteristics.
(3)研究多物理场耦合及典型故障条件下光伏电站核心部件及系统出力行为特性,系统提出光伏电站异常状况预警、诊断及预测性维护理论和方法,提升光伏发电智能化运行水平。
Research on the output characteristics of core components and systems for photovoltaic power plant under multi-physics coupling conditions and typical faults conditions, proposing new methods for the abnormal condition warning, fault diagnosis and predictive maintenance, and finally improve the intelligence level of photovoltaic power generation.
2.大型风力发电机组特性与运行控制Characteristics and operation control for large scale wind turbine generator systems
(1)发展大型海上风电机组设计理论,揭示气-液-机-电-弹-控大型海上风电机组耦合作用机理;研究基于可靠性增长的海上风电机组整机动力学建模与仿真技术、叶片与传动链关键部件的优化设计方法,并进行实验验证;突破陆上/海上新型风电机组智能控制技术;
To develop the design theory for large scale wind turbine generator systems, and explore the coupling mechanism of aerodynamics-hydraulics-mechanics-electrical-elasticity-control for large scale offshore wind turbine generator systems; to study the reliability growth based dynamic modeling and simulation technologies of offshore wind turbine generator systems, the optimal design methods of blades and drive train, and experimental validations; to break through the intelligent control technologies of new type wind turbine generator systems.
(2)掌握超大型叶片大变形流固耦合特性,发展非线性气动弹性分析方法;揭示深海浮式风电机组支撑结构的气-液-固耦合动力学特性,创新浮式支撑结构设计方法与稳定控制技术;
To explore the fluid structure coupling characteristics of super large blades under large deformation, and develop nonlinear aeroelastic analysis methods; to reveal the air-liquid-solid coupling dynamic characteristics of deep-sea floating wind turbine support structures, and innovate the design method and stability control technologies of the floating support structures.
(3)研究陆上(海上)大气边界层时空多尺度特性,创新风电机组、风电场/群流场多精度数值模拟方法,开发风电场流场模拟软件;揭示风电机组尾流干涉机理和风电场流动的时空演化特性,创新风电场功率预测方法和智能运行控制技术。
To study the multi-scale characteristics of atmospheric boundary layer on land and ocean, innovate the multi-precision numerical simulation methods for the flow fields of wind turbine/ wind farm / wind farm cluster, and develop flow field simulation software for wind farms; to reveal the interference mechanism of wind turbine wakes and spatial-temporal evolution characteristics of wind farm flow, and innovate power prediction methods and intelligent operation control technologies for wind farms.
3.太阳能热发电特性与系统集成Solar thermal power generation characteristics and system integration
(1)以实现连续太阳能热发电为目标,研发低成本、高能量密度高温储热技术及建模方法,研究储热材料多尺度传热传质机理,揭示储热系统储释热动态特性及与热发电系统的集成运行方法;
With the goal of continuous solar thermal power generation, develop low cost, high energy density, high temperature heat storage technology and modeling methods, research on the multi-scale heat and mass transfer mechanism of heat storage materials, and reveal the dynamic characteristics of heat storage and release of the heat storage systems and integrated operation method with thermal power generation system.
(2)以提高太阳能发电效率为目标,基于能的梯级利用原理,发展新的热力学循环,建立发电规模-循环工质-热功转换效率之间的关系,发展复杂天气条件下热发电系统调控运行策略,形成提高太阳能热发电效率的系统理论、原理及方法;
To improve the efficiency of solar power generation, based on the principle of energy cascade utilization, develop new thermodynamic cycles, establish the relationship between power generation scale, cycle working medium and thermal power conversion efficiency, and develop the regulation and operation strategy of thermal power generation system under complex weather conditions, and form the system theory, principle and method for improving the efficiency of solar thermal power generation.
(3)针对太阳能热与化石能源互补发电,进行复杂耦合系统热力学研究,探索先进的集成模式及方法。
For the complementary power generation of solar thermal and fossil energy, conduct thermodynamic research on complex coupling systems, and explore advanced integration modes and methods.
4.生物质转化机理与清洁高效发电Biomass conversion mechanism and clean and efficient power generation
(1)研究生物质大分子热转化反应的一般机理以及各种产物的生成路径、能量信息、动力学参数和关键控制步骤,探究生物质热转化过程中组分内和组分间的交互作用机理,构建生物质热解过程的全局反应机理与路径;
Research on the general mechanism of biomass thermal conversion and the formation path, energy information, kinetic parameters and key control steps of various products, explore the interaction mechanism of within and between components in biomass thermal conversion process, and construct the global reaction mechanism and path of biomass pyrolysis.
(2)研究生物质在不同条件下的特定热转化机理与调控机制,明确生物质原料、反应条件与产物之间的内在关联耦合机制,建立生物质选择性热转化多联产的技术理论体系;
Research on the specific thermal conversion mechanism of biomass and the relevant control mechanism under different conditions, clarify the internal coupling mechanism among biomass raw materials, reaction conditions and products, and establish the technical theoretical system for selective thermal conversion polygeneration of biomass.
(3)研究生物质直燃发电、混燃发电、气化发电、衍生燃料发电等发电过程中的输运与反应特性,确定污染元素的迁移转化规律,开发高效的发电技术与污染物防治技术,形成具有自主知识产权的系列成套技术,并大规模推广应用。
Research on the transport and reaction characteristics of biomass power generation process including direct combustion power generation, mixed combustion power generation, gasification power generation, derivative fuel power generation, etc., determine the migration and transformation of pollution elements, develop efficient power generation technology and pollutant prevention technology, form a series of complete sets of technologies with independent intellectual property rights, and apply them on a large scale.
方向二:先进输变电技术与电磁理论Advanced Power Transmission and Transformation Technology and ElectromagneticTheory
针对规模化新能源灵活传输与电网柔性互联等需求,研究高电压电磁理论以及电工材料、电力电子器件与新型输变电装备的多物理场分析与设计方法,揭示新型输变电装备特性及失效机理,提出新型传感技术与状态评估方法,发展先进输变电的换流理论,为先进输变电技术奠定理论基础。
In view of the technical requirements of large-scale new energy flexible transmission and flexible interconnection of power grids, research on high-voltage electromagnetic theory, as well as research on multi-physics analysis and design methods for electrical materials, power electronic devices and novel power transmission and transformation equipment. Furthermore, it reveals the characteristics and failure mechanisms of novel power transmission and transformation equipment, and proposes new sensing technologies and state assessment methods. So as to develop advanced power transmission and transformation commutation theory, and finally lay a theoretical foundation for the advanced power transmission and transformation technology.
近期研究重点Recent Research Focuses:
1.高电压电磁理论及应用High-voltage electromagnetic theory and application
(1)研究大功率电力电子器件电热力特性以及封装机构的电磁理论及多物理场调控方法,掌握器件失效机理,发展可靠性理论和提升方法;
Research on the electro-thermal characteristics of high-power power electronic devices, the electromagnetic theory and multi-physical field control methods of the packaging mechanism, and the failure mechanism of the power electronic devices, developing the reliability theory and improvement methods
(2)研究高压大容量电力电子装备(柔直换流阀、直流断路器、直流变压器等)的电磁特性,提出电磁瞬态计算、电磁性能提升、多物理量传感、可靠性评估等方法;
Research on the electromagnetic characteristics of high-voltage and large-capacity power electronic equipment such as VSC converter valves, DC circuit breakers, and DC transformers, proposing methods for electromagnetic transient calculation, electromagnetic property improvement, multi-physical quantity sensing, and reliability evaluation of equipment.
(3)研究柔性直流换流站和高海拔等特殊环境下直流线路的电磁环境特性和影响机理,发展电磁环境建模计算与防护方法;
Research on the characteristics and the mechanism of the electromagnetic environment generated from converter stations and HVDC transmission lines, and electromagnetic environment modeling calculations and protection methods
(4)研究高载流高温超导导体、低损耗高载流高温超导电缆、交直流超导限流电缆、超导限流变压器等的结构和原理,探索超导电力技术在新能源电力系统应用的新原理与新装备、闭环运行的高温超导磁体磁通泵励磁原理及关键技术。
Research on the configurations and principles of HTS conductor (cable) with high carrying current, HTS cable with high carrying current and low loss, AC/DC fault current limiting HTS cable and HTS transformer with limiting current function. Study novel principles and devices of superconducting technology in applications of electrical power system with renewable energy source, HTS magnet with persistent current mode energized by flux pump and its key technology
2.新型输变电装备特性及失效机理Characteristics and Failure Mechanism of New Transmission and Transformation Equipment
(1)研究新型电工材料的参数调控与制备方法,探索纳米复合电介质多因子劣化的微观规律与破坏机理;
Study on parameter control and preparation methods of novel electrical materials, and to explore the microscopic law and failure mechanism of multi-factor deterioration of nano-composite dielectrics.
(2)研究新型输变电装备(换流变压器、柔直变压器、直流GIL等)的多物理场分析方法,揭示多物理场综合作用特性,提出设计方法;
Investigation on the multi-physical field analysis methodology for new transmission and transformation equipment including converter transformer, flexible DC transformer, DC GIL, etc., as to reveal the comprehensive functioning characteristics of multi-physical fields, as well as development of novel design scheme.
(3)研究压敏、光敏、磁敏、气敏等先进传感方法,发展微电子和光电子的智能传感器;
Research on advanced sensing methodologies such as pressure-, light-, magnetic- and gas-sensitive transducers, and develop microelectronics and optoelectronics-based intelligent sensors.
(4)研究新型数据库的构建方法,提出融合大数据和云计算的智能诊断方法,建立新型输变电装备状态评估和故障预警的理论体系。
Study on construction method of new type database, and develop intelligent diagnosis method with combined big data and cloud computing, as to establish a theoretical system for condition assessment and fault prognosis of the new transmission and transformation equipment.
3.先进输变电的换流理论及系统特性The Advanced Converting Theory and System Characteristic of the Transmission and Transformation system
(1)研究全控/半控器件融合的混合直流输电理论,揭示复杂工况下不同类型电源、多换流器及控制系统之间的电磁交互作用机制,构建协同运行控制理论;
Research on the hybrid HVDC transmission theory integrating the fully-controlled and half-controlled devices, revealing the electromagnetic interaction mechanisms between different types of power sources, multiple converters and control systems under complex working conditions, and constructing the coordinated operation and control theory.
(2)研究直流电网拓扑形态、运行特性和故障传播等理论,基于新型换流器拓扑,提出直流电网及多端直流系统故障的主动管理理论和方法;
Research on the mechanisms of the topological structure, operational characteristics, and fault propagation of the HVDC grid. Based on the new converter topology, proposing the theory and practical measures of the active fault management of HVDC grid and multi-terminal HVDC systems.
(3)研究新型换流器拓扑和远海风电等新能源发电并网系统的电磁暂态等效建模方法,发展直流电网的电磁暂态实时仿真关键技术;
Research on the electromagnetic transient (EMT) equivalent modeling methods of the new converter topologies and renewable energy integration systems such as far-sea wind power generation, and developing the key technologies of real-time EMT simulation of HVDC grid.
(4)研究新型逆阻型器件和碳化硅等新一代电力电子器件的换流理论,提出更高功率密度的新型换流器拓扑结构。
Research on the converting theory of the newer generation power electronic devices such as reverse-blocking and silicon carbide devices, and proposing the new converter topologies with higher power density compared to the existing ones.
方向三:新能源电力系统控制与优化Control and Optimization of Renewable Energy Power System
针对新能源作为补充能源、替代能源、主流能源和主导能源的不同场景,探究新能源电力系统控制与优化的基础理论与方法,研究提高发电单元灵活性的理论方法,探索需求侧资源特性与多元互补调度控制理论与技术,研究高比例电力电子装置渗透后电网保护与稳定控制理论方法,实现新能源电力系统的安全高效运行。
In view of the different scenarios of renewable energy playing roles as supplementary energy source, alternative energy source, mainstream energy source and leading energy source respectively, we try to explore the basic control theories and optimization methods for the renewable energy power system, study theoretical methods to improve the flexibility of power generation units, and explore the demand-side resource characteristics and investigate the multiple energy complementary scheduling control theory and technology, develop the theory and methods of grid protection and stabilization control with higher-proportion penetration of power electronic devices, and realize the safe and efficient operation of renewable energy power systems.
近期研究重点Recent Research Focuses:
1.智能发电控制理论与技术Intelligent power generation control theory and technology
(1)研究综合能源转换效率、疲劳载荷与输出功率波动水平的新能源发电单元多目标优化控制策略,提出新能源发电单元、场群及基地的有功/无功控制方法;
Study the multi-objective control and optimization strategy of renewable energy power generation units with performance indexes of energy conversion efficiency, fatigue loads and output power fluctuations, and propose active and reactive power control methods for renewable energy power generation units, clusters and bases.
(2)研究发电过程运行状态精细化表征方法,提出多相流动环境下速度场、温度场、浓度场、成分场等的新型检测理论与技术,发展状态参数软测量技术;
Study the operation states refined characterization methods of the power generation process, propose novel detection theories and technologies for velocity field, temperature field, concentration field, composition field, and etc. within the multi-phase flow environment, and develop soft measurement technology for state parameters.
(3)研究基于机理分析与大数据分析的发电过程建模理论及先进控制方法,建立火电机组灵活智能运行控制理论技术体系,提出电源可调度性定量评价方法;
Research on mechanism analysis and big data analysis-based power generation process modeling theory with advanced control methods, establish a theoretical and technical system for the flexible and intelligent operation control of thermal power units, and propose a quantitative evaluation method for the power dispatchability.
(4)探索新能源发电过程多智能体分布协同控制理论,建立拓扑结构变化、信息传输延迟、随机噪声干扰情况下的特征辨识与协同调控方法。
Explore the multi-agent distributed collaborative control theory of the renewable energy power generation process, and establish the characteristic identification and coordinated control method under the conditions of changing topology, information transmission delay, and stochastic noise interference.
2.需求侧资源特性与调度控制Demand side resource characteristics and scheduling control
(1)研究不同时间尺度下需求侧资源特性与响应机理,揭示其可调控性与影响因素之间的关联机制,建立分时可调功率及区间可调电量的数学模型;
Study the characteristics and response mechanisms of demand-side resources corresponding to different time scales, reveal the correlation mechanism between the controllability and key influencing factors, and establish mathematical models for time-depending adjustable power and regional adjustable power.
(2)研究数据驱动的需求侧资源特性高速、高精度计算方法,提出基于机器学习的负荷特性智能建模与预测技术;
Study the data-driven high-speed high-precision calculation methods for demand-side resource characteristics, and propose machine learning based intelligent modeling and forecasting techniques for load characteristics.
(3)研究多区域需求响应资源动态聚合的技术经济准则,提出基于多种博弈框架的虚拟电厂集成与调控策略;
Research on the technical and economic criteria for the dynamic aggregation of multi-region demand response resources, and propose a virtual power plant integration and control strategy based on multigame theory frameworks
(4)研究新能源电源、常规电源和需求侧资源的互补特性,提出源网荷多元互补的新能源电力系统动态优化调度方法。
Research on the complementary characteristics of renewable energy power, conventional power and demand-side resources, and propose the dynamic dispatch optimization method to achieve the multiple complementary objective among the power generation, the power grid and loads.
3.电力系统保护新原理与安全稳定控制Power system protection, system stability and security control
(1)研究新能源电力系统扰动传播机理,分析单点、区域、整网扰动传播与耦合规律,建立新能源电力系统故障分析模型,提出高比例电力电子装置渗透下系统故障分析方法;
Research on disturbance propagation and coupling mechanism within renewable power system from the point of view single-port, multi-port and whole system. Build the fault analysis models of renewable power generation sources. Propose the system faut analysis methods for system with high portion penetration of power electronic converters.
(2)研究源网荷多场景下宽频带信号测量及测试方法,研究海量测量数据质量评估及轨迹精度提升方法,发展源网荷全景同步测量系统;
Study on the wide bandwidth measurement method under multiply scenarios; study data quality access and trajectory accuracy improvement method; develop the full-view synchronous measurement system for renewables, grids and loads
(3)研究高比例电力电子装置渗透后电网故障特征提取方法与保护新原理,提出融合电力电子控制、保护及故障隔离一体化故障处理方法;
Research on new protection for system with high portion penetration of power electronic converters. Propose the combined control and protection method to deal with the system faults.
(4)发展融合故障关联信息的后备保护构成原理,提出抑制连锁故障发生的保护与控制协同策略;
Develop backup protection theory based on the fusion of fault associated information and the coordination strategy of control and protection to reduce the possibility of the cascading failure.
(5)研究大规模新能源和电网间的动态交互作用机制,发展采用人工智能技术的电力系统特征提取方法,提出融合数据响应特征的人工智能建模和稳定性分析体系,建立新能源电力系统就地趋稳设计、全网在线协同的理论和方法。
Analyze the dynamic interaction mechanism between large-scale new energy and the power grid; develop power system feature extraction methods using artificial intelligence technology; propose an artificial intelligence modeling and stability analysis system that integrates data response characteristics; establish on-site trend theories and methods for stable design and online collaboration for the renewable energy power system.
方向四:多元信息融合与综合能源系统优化Multi-information Fusion and Integrated Energy System Optimization
针对分布式能源高比例接入的场景,研究多元信息融合理论、综合能源系统特性、电能质量测控理论等关键问题,突破多元信息采集、通信与信息处理关键技术,建立综合能源系统的仿真模型并提出优化控制方法,发展电能质量控制的关键技术与装备,实现可再生能源的分布式消纳与高效利用。
For the scenario of large-scale distributed energy resources integration, the key issues including multi-information fusion theory, integrated energy system characteristics, and power quality measurement and control theory are studied, the key technologies of multi-information collection and communication and information processing is broken, the simulation model of integrated energy system is established and the optimization control methods are proposed, the key technologies and equipment for power quality control is developed. Finally, the distributed consumption and efficient utilization of renewable energy are realized.
近期研究重点Recent Research Focuses:
1.多元信息融合理论与技术Theory and technology of multi-information fusion
(1)研究光纤分布式状态感知及微型自取能自组网无线状态感知方法,构建综合能源系统全信息透明监控体系;
Research on distributed optical fiber state sensing and micro self-powered ad-hoc network wireless state sensing methods, and construction of a comprehensive information and transparent monitoring system for the integrated energy system.
(2)研究适用于综合能源系统的5G和后5G物理层传输和跨层关键技术协同理论和方法, 建立信道、噪声和干扰时变模型,提出通信网与电网兼容共存的理论和方法,提出海量终端低功耗大连接、网络切片和本-边-云协同优化策略;
Research on the theories and methods of 5G and post-5G physical layer transmission and cross-layer key technology collaboration for integrated energy systems, and formulation of the channel, noise and interference time-varying models, research on the theories and method for compatible coexistence of communication network and power network, and strategies introduction of the massive terminals connections with low power consumption, network slicing, and local-edge-cloud collaborative optimization.
(3)研究多源异构电力大数据融合技术、数据清洗及数据治理理论与方法,建立多源异构数据知识库模型与评估方法,提出数据驱动的云雾协同智能决策理论与关键技术以及基于区块链、量子加密等方法的信息可信互联技术。
Research on the theories and methods of heterogeneous multi-source power big data technologies in terms of data fusion, data cleaning, and data governance, formulation of the heterogeneous multi-source database model and evaluation method, research on data-driven cloud-fog collaborative decision-making theory and the trusted information interconnection technology based on block chain and quantum encryption.
2.综合能源系统建模仿真与优化控制Simulation modeling and optimization control of integrated energy system
(1)研究综合能源系统物理调控特性,提出多能互补的优化配置方法与解耦运行策略,揭示随机不确定性对系统调度运行决策的影响规律,提出数据驱动的全工况优化运行控制方法;
Research on the physical control characteristics of the integrated energy system, proposal of the multi-energy complementary optimal configuration method and decoupling operation strategy, influence mechanism revelation of uncertainties on the system scheduling and operation, data-driven optimization control method introduction for all operation conditions
(2)研究电动汽车、可控负荷、分布式能源、多元储能与综合能源系统的交互运行机制,提出计及需求响应的协同优化控制技术,揭示综合能源系统的故障与扰动传播机理,提出保障安全可靠运行的韧性自愈控制方法;
Research on the interactive operation mechanism of EVs, controllable loads, distributed energy resources, multi-energy storages, and integrated energy systems, research on the collaborative optimization control technology with the consideration of demand response, propagation mechanism revelation of fault and disturbance in integrated energy system, and proposal of the resilient self-healing control method to ensure safe and reliable operation
(3)研究能源供给和需求的市场主体构成及其行为特征,提出分布式能源系统集群的多主体优化方法及其市场均衡分析机制。
Research on the market entities composition and their behavior characteristics of energy supply and demand, and proposal of the multi-agent optimization method and market equilibrium analysis mechanism for distributed energy system cluster.
3.电能质量测控理论与技术Theory and technology of power quality measurement and control
(1)研究高渗透率分布式能源并网下系统的电能质量理论,以直流配电网电能质量和超高次谐波等为新关注点,揭示扰动发射和负荷敏感机理及其耦合规律,提出电能质量扰动影响评估方法;
Research on the power quality theory of the system with high distributed energy resources integration, new focus considerations about the DC distribution network power quality and ultra-high harmonics, revelation of the disturbance emission and load sensitivity mechanism and coupling mechanism, and method introduction of the power quality disturbance influence evaluation
(2)研究多源接入配电网电能质量扰动传播规律及其关键因素,提出欠量测情况下监测盲区最大可观测的电能质量监测终端优化配置方法;
Research on the propagation regulation and key factors of power quality disturbances in multi-source access distribution network, research on the optimal configuration method of power quality monitoring terminal for monitoring blind zone with maximum observability in the case of lacking measurement
(3)研究高功率密度、高转化效率能源路由器拓扑与协调控制策略,提出弱机械惯性分布式新能源系统的设计与调控方法,发展分布式新能源系统的电能质量控制技术与装备。
Research on the topology and coordinated control strategy of energy hubs with high power density and high conversion efficiency, system design and control methods proposal of distributed alternative energy resources system with weak mechanical inertia, and development of the power quality control technology and distributed alternative energy system equipment.
二、申请人条件与申请提交要求 Requirements of the Application Submission
申请人应有固定的工作单位,原则上具有博士学位或高级职称,年龄不超过55岁;与本室科研人员就相关研究有合作的申请优先资助。
Applicants should have fixed work unit, possessing a doctoral degree or a senior professional post at an age of no more than 55; Applicants having cooperative ties with the Laboratory researchers enjoy approval priority.
申请者按规定的格式要求填写《新能源电力系统国家重点实验室开放课题申请书》,经所在单位签署意见并加盖单位公章后,在规定的时间之内将纸质版申请书(胶装一式两份)寄给指定联系人;将word版申请书(含扫描版签字盖章页)通过Email发给联系人。不邮寄的可直接交到实验室综合办公室(主楼A座309室)。纸质版申请书要求胶装。实验室将对申请书进行形式审查;本着公平竞争、择优支持的原则对通过形式审查的申请项目进行评审。
Applicants fill in the “Application Form for Open Fund”,have it signed and stamped. Applicants should hand in 2 hard copies of the Form and 1 copy in word format (a scanned copy with the signed and stamped page included) by email. Hard copies can be posted to the designated contact or send to the Laboratory Office (room 309, Main-Building Block A) via the liaison man. The hard copy of the Application Form should be in paper cover binding. The Lab administrators will first go through the format of the Application Forms and those qualified Forms will be further evaluated under the principles of fair competition and selective support.
三、支持强度、申请截止日期、考核重点Implementation Period, Fund Limit and Appraisal Priority
开放课题的研究年限为2年,每个课题的资助强度最高限额10万元。开放课题考核注重申请人与本室研究人员学术交流和科研合作,如联合发表高水平论文、联合申请相关项目、到实验室作学术报告等。
The implementation period of each open fund is 2 years. Top limit for each open fund is RMB 100,000yuan. The appraisal of these research projects lays emphasis on the academic exchanges and cooperation between the applicants and the Laboratory researchers, such as making academic report in the Laboratory, joint publication of high-level academic papers, joint application for related research projects, and the like.
四、联系人Contact
张 洪(Mr. Zhang) Tel: 010-61771852 E-mail: zh10358@163.com
五、邮寄材料指定联系人Designated Contact for Post
收件人:许 静 手机186-0020-5433
邮寄地址:北京市昌平区北农路2号华北电力大学
为方便收件,建议统一选择顺丰快递邮寄。快递寄送截止收件日期: 2020年12月15日。
Consignee: Ms. Xu Jing Mobile phone: 186-0020-5433
Mailing address: North China Electric Power University, No. 2 Beinong Road, Changping District, Beijing, P.R.China.
We recommend applicants to mail the Application Forms by SF Express. The mail receipt date is until 15 December. 2020.
六、新能源电力系统国家重点实验室开放课题申请书(见附件)。
其中,英文版申请书“Application Form for Open Fund”仅供母语为非汉语的申请人填写。
“Application Form for Open Fund of the State Key Laboratory of Alternate Electrical Power System with Renewable Energy Source” (as attached, only for applicants whose native language is not Chinese.)
相关附件: