风光互补发电实训系统教学实验平台设计
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摘要
为增加学术前沿理论教育,解决电气主干理论课与实验教学"脱节"的现象,开发了风光互补发电实训系统教学实验平台。基于光伏阵列与风力发电机工作原理,重点阐述了实验平台的原理与构成,深入分析了最大功率跟踪策略的选择与实现。然后根据实验平台分析了可开展实验内容与风光互补发电实验平台建设的重要意义。该实验平台可完善电气工程专业实验教学知识体系,完成光伏、风力发电的相关教学内容,提高毕业生解决复杂工程问题的能力。
To increase the academic frontier theory education, solving the phenomenon of "disconnect" for main electrical theory and experiment teaching, a comprehensive teaching experimental platform for wind and solar hybrid power generation system was developed. Based on the principle of photovoltaic array and wind driven generator, this paper mainly focused on the principle and the composing of the experimental platform, in-depth analysis of the choice of maximum power tracking strategy and implementation. And then can carry out the experiment contents are analyzed based on the experimental platform and the significance of wind-light complementary experimental platform construction. This experiment platform can perfect the system of the electrical engineering experiment teaching knowledge, carry out the teaching content related photovoltaic, wind power, improve the ability of graduates to solve complex engineering problems.
To increase the academic frontier theory education, solving the phenomenon of "disconnect" for main electrical theory and experiment teaching, a comprehensive teaching experimental platform for wind and solar hybrid power generation system was developed. Based on the principle of photovoltaic array and wind driven generator, this paper mainly focused on the principle and the composing of the experimental platform, in-depth analysis of the choice of maximum power tracking strategy and implementation. And then can carry out the experiment contents are analyzed based on the experimental platform and the significance of wind-light complementary experimental platform construction. This experiment platform can perfect the system of the electrical engineering experiment teaching knowledge, carry out the teaching content related photovoltaic, wind power, improve the ability of graduates to solve complex engineering problems.
引文
[1] 李源启.风光互补发电系统中最大功率跟踪控制策略研究[D].兰州:兰州理工大学,2017.
[2] 刘艳.可再生能源与新能源国际科技合作计划启动[C]//节能减排论坛——福建省科协学术年会卫星会议论文专刊,福建省能源研究会,2008:1-1.
[3] 陈惠俊.风光互补发电应用技术[M].北京:化学工业出版社,2016.
[4] 万军,胡长生.基于AVR单片机的光伏系统变步长MPPT控制[J].机械与电子,2008(4):20-22.
[5] 卢琳,殳国华,张仕文.基于MPPT的智能太阳能充电系统研究[J].电力电子技术,2007,41(2):96-98.
[6] 何龙,程树英.基于遗传算法和扰动观察法的MPPT算法[J].现代电子技术,2009,32(24):199-202.
[7] 刘细平,林鹤云.风力发电机及风力发电控制技术综述[J].大电机技术,2007(3):17-20.
[8] 郭栋,徐欣,杨根科,等.基于MPPT算法的风光互补发电实验系统的研究与实现[J].实验室研究与探索,2013,32(6):71-76.
[9] 杨新法,苏剑,吕志鹏,等.微电网技术综述[J].中国电机工程学报,2014(1):57-70.
[10] 张荣甫,高树发,邵振付.风能太阳能综合电源系统设计[J].电源技术,2003,27(1):36-38.
[11] 景新幸,张国庆,周胜源,等.以实验教学创新全面推进国家级实验教学示范中心建设[J].实验技术与管理,2011,28(12):5-8.
[2] 刘艳.可再生能源与新能源国际科技合作计划启动[C]//节能减排论坛——福建省科协学术年会卫星会议论文专刊,福建省能源研究会,2008:1-1.
[3] 陈惠俊.风光互补发电应用技术[M].北京:化学工业出版社,2016.
[4] 万军,胡长生.基于AVR单片机的光伏系统变步长MPPT控制[J].机械与电子,2008(4):20-22.
[5] 卢琳,殳国华,张仕文.基于MPPT的智能太阳能充电系统研究[J].电力电子技术,2007,41(2):96-98.
[6] 何龙,程树英.基于遗传算法和扰动观察法的MPPT算法[J].现代电子技术,2009,32(24):199-202.
[7] 刘细平,林鹤云.风力发电机及风力发电控制技术综述[J].大电机技术,2007(3):17-20.
[8] 郭栋,徐欣,杨根科,等.基于MPPT算法的风光互补发电实验系统的研究与实现[J].实验室研究与探索,2013,32(6):71-76.
[9] 杨新法,苏剑,吕志鹏,等.微电网技术综述[J].中国电机工程学报,2014(1):57-70.
[10] 张荣甫,高树发,邵振付.风能太阳能综合电源系统设计[J].电源技术,2003,27(1):36-38.
[11] 景新幸,张国庆,周胜源,等.以实验教学创新全面推进国家级实验教学示范中心建设[J].实验技术与管理,2011,28(12):5-8.