|
|
漏板配电分流在玻纤降本增效中的应用
|
Abstract:
对风电市场进行了分析后,发现玻璃纤维中的风电产品因提产增效而存在的配电问题。本研究以F10生产线为分析样例,对漏板三级配电情况进行了详细梳理,并指出因提产导致的漏板配电超载问题。漏板配电超载将导致用电安全隐患,对提产增效形成制约。在综合考虑生产需求与安全运行的基础上,提出增设漏板配电柜以进行配电分流的有效解决措施,满足大漏板增设的配电需求,从而实现降本增效。
After analyzing the wind power market, it was found that wind power products in fiberglass have distribution problems due to increased production and efficiency. This study takes the F10 production line as an example to analyze the three-level distribution of leakage boards in detail, and points out the problem of overload of leakage board distribution caused by increased production. Overloading of leaky distribution boards will lead to safety hazards in electricity consumption, which will constrain production and efficiency improvement. On the basis of comprehensive consideration of production demand and safe operation, an effective solution is proposed to add a leakage board distribution cabinet for distribution diversion, to meet the distribution needs of adding large leakage boards and achieve cost reduction and efficiency improvement.
| [1] | 梁广华. 我国推进碳中和意义及路径研究[J]. 未来与发展, 2022, 46(12): 1-6. |
| [2] | Udeagha, M. and Muchapondwa, E. (2023) Achieving Regional Sustainability and Carbon Neutrality Target in Brazil, Russia, India, China, and South Africa Economies: Understanding the Importance of Fiscal Decentralization, Export Diversification and Environmental Innovation. Sustainable Development, 31, 2620-2635. https://doi.org/10.1002/sd.2535 |
| [3] | 刘海斌. 世界风电技术发展趋势和我国未来风电发展探讨[J]. 自然科学, 2021(9): 93-93. |
| [4] | Liu, D., Liu, M., Xu, X., et al. (2020) Future Prospects Research on Offshore Wind Power Scale in China Based on Signal Decomposition and Extreme Learning Machine Optimized by Principal Component Analysis. Energy Science and Engineering, 8, 3514-3530. https://doi.org/10.1002/ese3.761 |
| [5] | 谭虢, 魏榛, 谢宇丹, 等. 我国风电行业发展及区域分布分析[C]//中国农业机械工业协会风力机械分会. 中国农机工业协会风能设备分会《风能产业》. 2015. |
| [6] | 杜培刚, 王玉琪. 玻璃纤维生产工艺技术优化与效益分析[J]. 当代化工研究, 2023(19): 179-181. |
| [7] | 马晓虎, 耿怀亮, 金英杰, 等. 铂合金玻纤漏板制造技术现状及发展趋势[J]. 贵金属, 2022, 43(3): 89-96. |
| [8] | 孙文华. ABB与施耐德低压断路器选配要领[J]. 电工技术, 2002(12): 38-39. |
| [9] | 谷国瑞. 浅谈断路器误跳闸的常见原因[J]. 农村电工, 2021, 29(12): 42. |
| [10] | 肖镇铭. 化工装置中电线电缆的选择和校验研究[J]. 建筑工程技术与设计, 2017(11): 3899. |
| [11] | 员三妮. 仪表信号电缆截面积的选择与最大敷设长度的计算[J]. 石油石化物资采购, 2023(11): 205-207. |
| [12] | 潘国斌. 温度对电线电缆绝缘材料机械性能的影响[J]. 电工技术, 2022(5): 183-184. |
| [13] | 袁钦成. 配电系统故障处理自动化技术[M]. 北京: 中国电力出版社, 2007: 87-91. |
