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            Suzhou Electric Appliance Research Institute
        
    
        
    
            
            
    期刊號:
            
            CN32-1800/TM|
            
            ISSN1007-3175
            
            
            
    
        
    
    
    

    

      
    
        
    
            
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    氫電混輸直流超導(dǎo)電纜研究進展及安全設(shè)計研究
    
            
    來源:電工電氣發(fā)布時間:2024-04-07 14:07 瀏覽次數(shù):392
    
            
    
              
    
	氫電混輸直流超導(dǎo)電纜研究進展及安全設(shè)計研究
    

    
	朱紅亮
    

    
	(富通集團(天津)超導(dǎo)技術(shù)應(yīng)用有限公司 天津市超導(dǎo)電纜應(yīng)用重點實驗室,天津 300384)
    

    
	 
    

    
	
    
		    摘 要:超導(dǎo)氫電混合旨在實現(xiàn)液氫清潔能源和超導(dǎo)電力能源共同輸運,不僅可以節(jié)約冷卻成本,同時可以提升超導(dǎo)電纜通流能力,是實現(xiàn)超導(dǎo)電力大規(guī)模應(yīng)用的有效技術(shù)手段。闡述了氫電混輸直流超導(dǎo)電纜研究進展,對超導(dǎo)電纜在液氫環(huán)境下的混輸結(jié)構(gòu)設(shè)計方法進行了研究,并給出了安全設(shè)計原則與應(yīng)急預(yù)案,為氫電混輸直流超導(dǎo)電纜優(yōu)化設(shè)計提供了參考。
    
	
    
		    關(guān)鍵詞: 直流超導(dǎo)電纜;氫電混輸;熱絕緣;冷絕緣
    
	
    
		    中圖分類號:TM757     文獻標(biāo)識碼:A     文章編號:1007-3175(2024)03-0001-05
    
	
    
		 
    
	
    
		
    
			Research Progress and Safety Design of Hydrogen-Electric
    
		
    
			Hybrid Transmission DC Superconducting Cables
    
		
    
			 
    
		
    
			
    
				ZHU Hong-liang
    
			
    
				(Futong Group (Tianjin) Superconductor Technologies and Applications Co., Ltd. Tianjin Key
    
			
    
				Laboratory of Superconducting Cable Applications, Tianjin 300384, China)
    
			
    
				 
    
			
    
				
    
					    Abstract: Superconducting hydrogen-electric hybrid aims to realize the joint transportation of liquid hydrogen clean energy and superconducting power energy, which can not only save cooling costs, but also improve the flow capacity of superconducting cables, and it is an effective technical means to realize the large-scale application of superconducting electricity. In this paper, the research progress of hydrogen-electric hybrid DC superconducting cable is expounded, the design method of superconducting cable mixed transportation structure in liquid hydrogen environment is studied, and the safety design principles and emergency plan are given, which provides a reference for the optimal design of hydrogen-electric hybrid DC superconducting cable.
    
				
    
					    Key words: DC superconducting cable; hydrogen-electric hybrid transmission; thermal insulation; cold insulation
    
				
    
					 
    
				
    
					
    
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