Plant factory, a sophisticated environmentally controlled facility, could facilitate the production of virus-free strawberry daughter plants and pesticide-free fruits. At present, the problem caused by recirculating hydroponic system in daughter plants and fruits production has not yet been solved. Therefore, this study focused on the establishment of recirculating hydroponic system in strawberry daughter plants and fruit production. The growth of daughter plants was also evaluated in the greenhouse. N129%S90%, Enshi solution with 29% nitrogen enhancement and 10% MgSO4 decrease, was evaluated for daughter plants production. No difference between N129%S90% and Enshi solution in mother plants’ growth. N129%S90% enabled 1 mother plant to produced 1.83 daughter plants per week in average. The growth of the mother plants was not promoted after the second solution renewing; therefore, the mother plants were suggested to be renewed after the final harvest, and each mother plants produced 37 daughter plants in average. The Enshi solution modification, N129%S90%, increased 7.8% of daughter plant production. N129%S90% nutrient solution effectively decreased the SO42- accumulation in addition to supply more NO3-, but the variation of EC and pH value were larger. Nearly all the daughter plants grew well after transferring to the greenhouse. The flower induction in recirculating hydroponic system was first evaluated both 'Taoyuan No.1' and 'Changbin' strawberry by direct fitting the reproduction model previously built in non-recirculation system which Enshi solution was used. The final inflorescence ratio of both cultivars was only 12%. Due to the solution renewing was at the end of floral induction, the dramatic increase of nitrogen forced most of plants turn back to vegetative growth. Therefore, a nitrogen-reduced nutrient solution experiment was programed. We reduced nitrogen content of Enshi solution in both the initial and supplemental nutrient solution. N75%+N50% and N75%+N75% recovered the final inflorescence to 100% and 93.33%, respectively, but the appearance of inflorescence was slower in nitrogen-reduced nutrient program, particularly N75%+N75%. The concentration of Ca2+ and Mg2+ maintained stable and SO42- was accumulating throughout the experimental period. The K+ and NO3- were less supplement in nitrogen-reduced nutrient solution and plants suffer depletion at the early fruit development stage which might resulted in delaying harvest by 6 to 7 days compared to non-recirculating control, and the delay could not prevent even if we renewed the solution. The average fruit weight was 16 g, which was significantly smaller than the average weight 20 g of non-recirculating system. In recirculating system, the nitrogen-reduced nutrient program could solve the problem of flower induction but the nutrient was not sufficient to offer good fruit production; therefore, the re-induced plants for the production of second bunch of fruits by recirculating hydroponic system was not applicable. Producing strawberry fruits in recirculating hydroponic system required more study to avoid nutrient deficiency after the floral induction problem was solved.