特高压直流分压器内部温度场结构优化设计  被引量:6

Optimized Design for HVDC Voltage Divider Internal Temperature Field

在线阅读下载全文

作  者:邵明鑫[1] 王晓琪[1] 汪本进[1] 向璨[2] 

机构地区:[1]中国电力科学研究院,武汉430074 [2]华中科技大学能源与动力学院,武汉430074

出  处:《高压电器》2016年第9期8-13,共6页High Voltage Apparatus

基  金:国家电网公司科技项目~~

摘  要:直流分压器是直流输电系统中不可缺少的主设备。目前直流阻容式分压器因结构和工作原理的原因,导致内部出现较大的温度梯度,影响了分压器的误差性能,同时增加了空心绝缘子发生污秽闪络的概率。针对±1 100 kV直流分压器的散热问题,文中进行了内部温度场的结构优化设计,同时在顶部增加散热结构,降低其温度梯度。最后利用Ansys Fluent软件对该结构设计进行温度场和热流场的仿真分析,结果表明:在27℃的环境温度下,与传统结构的直流分压器相比,在额定一次电流为2 m A,热流量为2.2 k W的情况下,其内部温度有明显的降低,最大温差可达到20 K。同时增加的散热翅片显著提高了分压器内部气体的循环流动,提高了散热的效率,优化后的结构满足散热的需求。DC voltage divider is indispensable for DC power transmission system. Owing to its structure and principle, DC voltage divider has a great temperature gradient inside, which affect its error performance and increase the flashover probability of the hollow insulator. For the heat problem, this paper improves the structure of the ±1 100 kV DC voltage transformer's internal temperature field, while improving the cooling structure of the top, this design can lower its temperature gradient. Finally, Ansys Fluent is used to simulation the new design for the analysis of the temperature distribution and heat flux field, the results show that, in the case of the primary current is 2 m A and the heat flow is 2.2 k W, the new DC voltage divider internal temperature decreases significantly compared to the conventional structure at an ambient temperature of 27 ℃, the temperature difference can reach 20 K. The cooling structure of the top increases the gas flow inside the divider and improves the efficiency of the heat dissipation, this optimized design can meet the cooling requirement.

关 键 词:特高压 直流分压器 温度场 同轴双气室 散热系统 

分 类 号:TM721.1[电气工程—电力系统及自动化]

 

参考文献:

正在载入数据...

 

二级参考文献:

正在载入数据...

 

耦合文献:

正在载入数据...

 

引证文献:

正在载入数据...

 

二级引证文献:

正在载入数据...

 

同被引文献:

正在载入数据...

 

相关期刊文献:

正在载入数据...

相关的主题
相关的作者对象
相关的机构对象