@article{oai:nifs-repository.repo.nii.ac.jp:00010737,
 author = {TAMURA,  Hitoshi and TANAKA,  Teruya and GOTO,  Takuya and MIYAZAWA,  Junichi and MIYAZAWA, Jun-ichi and MASUZAKI,  Suguru and WATANABE,  Tsuguhiro and YANAGI,  Nagato and SAGARA,  Akio and ITO,  Satoshi and HASHIZUME1,  Hidetoshi},
 journal = {Fusion Engineering and Design},
 month = {Feb},
 note = {0000-0003-4210-9859, The heat flux at the divertor in a fusion reactor is considered to have a peak of >10 MW/m2. In a design study of the helical reactor FFHR-d1, the feasibility of employing a copper alloy for divertor cooling pipes was investigated; however, radiation in the divertor area would quickly damage the copper alloy. The neutron load on the divertor can be reduced by a blanket arrangement; nevertheless, in the present divertor structure, irradiation damage of materials on the inboard side of the torus remains relatively high. If the divertor could be moved to an area receiving much less radiation, then the lifetimes of divertor materials should increase. In this paper, a novel divertor structure is introduced in which the coil-support structure is modified to create a region receiving relatively low amounts of radiation without changing the geometry of the helical or vertical field coils. Using this proposed design would increase the lifetime of the copper alloy in divertor components to more than an estimated six years. In addition, the divertor could be accessed from either the upper or lower sides of the device, simplifying maintenance.},
 pages = {1629--1633},
 title = {Novel divertor design to mitigate neutron irradiation in the helical reactor FFHR-d1},
 volume = {98-99},
 year = {2015}
}