Plant production, energy balance and monitoring-control-telepresence in a recirculating hydroponic vegetable crop production system: prototype lunar greenhouse

G. Giacomelli; M. Kacira; R. Furfaro; R.L. Patterson; P. Sadler

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Plant production, energy balance and monitoring-control-telepresence in a recirculating hydroponic vegetable crop production system: prototype lunar greenhouse

机译：循环水培蔬菜作物生产系统中的植物生产，能量平衡和监控远程控制：原型月球温室

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The goals of this investigation were to evaluate a Bioregenerative Life Support System (BLSS) approach for a sustained human surface presence on the Moon (or Mars) for a four-person crew by the development and/or demonstration of poly-culture crop production, system mass balances and flow of input/output resources, biomass recycling, energy generation, and monitoring/control with non-contact sensing and telepresence technologies. Food production efficiency (kg/unit time/resource input) was determined based on fresh and dry weights produced per unit time, volume, and input resources. A Solar Concentrated Power System using a Himawari was evaluated. A Remote Experts Network and Decision Support System (RENDSys) was created to improve the monitoring and control capability with non-contact sensing and telepresence technologies. An Energy Cascade Model for a multi-crop lunar greenhouse system was evaluated. These component systems represent several of the major developmental needs for a future BLSS as determined by the Arizona-NASA Steckler Space Grant Program: Prototype Lunar Greenhouse Development. Each was discussed individually in detail within the proceedings of the 44th International Conference on Environmental Systems, Tucson, Arizona. This paper represents an overview of the Prototype Lunar Greenhouse Development based on those reports.

机译：这项调查的目的是通过开发和/或演示多种养殖作物的生产方法，评估一种生物再生生命支持系统（BLSS）方法，以确保四人乘员在月球（或火星）上持续存在于人类表面，系统质量平衡和输入/输出资源的流量，生物质的循环利用，能源的产生以及使用非接触式传感和网真技术进行的监视/控制。根据每单位时间，数量和投入资源产生的鲜重和干重确定食品生产效率（千克/单位时间/资源投入）。评估了使用Himawari的太阳能集中发电系统。创建了一个远程专家网络和决策支持系统（RENDSys），以利用非接触式传感和网真技术提高监视和控制能力。评估了多作物月球温室系统的能量梯级模型。这些组件系统代表了未来的BLSS的几个主要开发需求，这些需求由Arizona-NASA Steckler太空资助计划确定：原型月球温室开发。在亚利桑那州图森市举行的第44届国际环境系统会议的会议记录中，分别对每个问题进行了详细讨论。本文根据这些报告概述了原型月球温室开发。

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《Acta Horticulturae》 |2015年第1107期|共7页
作者
G. Giacomelli; M. Kacira; R. Furfaro; R.L. Patterson; P. Sadler;
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NASA Steckler Space Grant; BLSS; Bioregenerative Life Support; Moon; Mars; controlled environment; planetary habitat; urban agriculture;

机译：NASA Steckler太空津贴;BLSS;生物再生生命支持;月亮;火星;受控环境;行星生境;城市农业;

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1. Plant production, energy balance and monitoring-control-telepresence in a recirculating hydroponic vegetable crop production system: prototype lunar greenhouse [J] . G. Giacomelli, M. Kacira, R. Furfaro, Acta Horticulturae . 2015,第1107期

机译：循环水培蔬菜作物生产系统中的植物生产，能量平衡和监控远程控制：原型月球温室
2. Evaluation of Hydroponic Production of Vegetables and Ornamental Pot-Plants in a Heated Greenhouse in Western Macedonia, Greece | Science Publications [J] . Christina Gianneli, Christos Papadopoulos, Fotis Chatzitheodoridis, American journal of agricultural and biological sciences . 2008,第3期

机译：希腊马其顿西部一座加热温室中蔬菜和观赏盆栽植物的水培生产评价科学出版物
3. Recycling crop residues for use in recirculating hydroponic crop production [J] . Mackowiak CL, Garland JL, Sager JC, Acta Horticulturae . 1996,第440期

机译：回收农作物残渣用于循环水培作物生产
4. Poly-Culture Food Production and Air Revitalization Mass and Energy Balances Measured in a Semi-Closed Lunar Greenhouse Prototype (LGH) [C] . R. Lane Patterson, Gene A. Giacomelli, Erica Hernandez International Conference on Environmental Systems . 2014

机译：聚集食品生产和空气振兴质量和能量余额在半封闭的月球温室原型（LGH）测量
5. Development of a urethane-based plant growth substrate for hydroponic greenhouse vegetable production. [D] . Huber, Jeffery John. 2006

机译：开发用于水培温室蔬菜生产的氨基甲酸酯基植物生长基质。
6. Remote Control of Greenhouse Vegetable Production with Artificial Intelligence—Greenhouse Climate Irrigation and Crop Production [O] . Silke Hemming, Feije de Zwart, Anne Elings, 2019

机译：利用人工智能对温室蔬菜生产进行远程控制-温室气候灌溉和作物生产
7. Conversão e balanço de energia de sistemas de produção com integração lavoura-pecuária sob plantio direto Energy conversion and balance of integrated crop-livestock production systems under no-tillage [O] . Henrique Pereira dos Santos, Renato Serena Fontaneli, Silvio Tulio Spera, 2011

机译：免耕模式下作物与畜牧业一体化的能源转换和生产系统的平衡
8. Continuous hydroponic wheat production using a recirculating system [R] . Mackowiak, C. L., Owens, L. P., Hinkle, C. R., 1989

机译：使用再循环系统连续水培小麦生产

Plant production, energy balance and monitoring-control-telepresence in a recirculating hydroponic vegetable crop production system: prototype lunar greenhouse

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