Geoffrey C R Waters, Ammar Olabi, Jean B Hunter, Mike A Dixon, Christophe Lasseur
{"title":"Bioregenerative food system cost based on optimized menus for advanced life support.","authors":"Geoffrey C R Waters, Ammar Olabi, Jean B Hunter, Mike A Dixon, Christophe Lasseur","doi":"","DOIUrl":null,"url":null,"abstract":"<p><p>Optimized menus for a bioregenerative life support system have been developed based on measures of crop productivity, food item acceptability, menu diversity, and nutritional requirements of crew. Crop-specific biomass requirements were calculated from menu recipe demands while accounting for food processing and preparation losses. Under the assumption of staggered planting, the optimized menu demanded a total crop production area of 453 m2 for six crew. Cost of the bioregenerative food system is estimated at 439 kg per menu cycle or 7.3 kg ESM crew-1 day-1, including agricultural waste processing costs. On average, about 60% (263.6 kg ESM) of the food system cost is tied up in equipment, 26% (114.2 kg ESM) in labor, and 14% (61.5 kg ESM) in power and cooling. This number is high compared to the STS and ISS (nonregenerative) systems but reductions in ESM may be achieved through intensive crop productivity improvements, reductions in equipment masses associated with crop production, and planning of production, processing, and preparation to minimize the requirement for crew labor.</p>","PeriodicalId":81864,"journal":{"name":"Life support & biosphere science : international journal of earth space","volume":"8 3-4","pages":"199-210"},"PeriodicalIF":0.0000,"publicationDate":"2002-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Life support & biosphere science : international journal of earth space","FirstCategoryId":"1085","ListUrlMain":"","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Optimized menus for a bioregenerative life support system have been developed based on measures of crop productivity, food item acceptability, menu diversity, and nutritional requirements of crew. Crop-specific biomass requirements were calculated from menu recipe demands while accounting for food processing and preparation losses. Under the assumption of staggered planting, the optimized menu demanded a total crop production area of 453 m2 for six crew. Cost of the bioregenerative food system is estimated at 439 kg per menu cycle or 7.3 kg ESM crew-1 day-1, including agricultural waste processing costs. On average, about 60% (263.6 kg ESM) of the food system cost is tied up in equipment, 26% (114.2 kg ESM) in labor, and 14% (61.5 kg ESM) in power and cooling. This number is high compared to the STS and ISS (nonregenerative) systems but reductions in ESM may be achieved through intensive crop productivity improvements, reductions in equipment masses associated with crop production, and planning of production, processing, and preparation to minimize the requirement for crew labor.
根据作物产量、食物可接受性、菜单多样性和机组人员的营养需求等指标,开发了生物再生生命支持系统的优化菜单。作物特定生物量需求是根据菜单配方需求计算的,同时考虑到食品加工和制备损失。在交错种植的假设下,优化后的菜单要求6名工作人员的作物生产总面积为453平方米。生物再生食品系统的成本估计为每个菜单周期439公斤或ESM工作人员每天7.3公斤,其中包括农业废物处理成本。平均而言,食品系统成本中约60% (263.6 kg ESM)与设备有关,26% (114.2 kg ESM)与劳动力有关,14% (61.5 kg ESM)与电力和冷却有关。与STS和ISS(非再生)系统相比,这个数字很高,但ESM的减少可以通过集约化作物生产力的提高,减少与作物生产相关的设备质量,以及对生产、加工和准备的规划来实现,以最大限度地减少对机组人员的需求。