Greenhouse Module for Space System: A Lunar Greenhouse Design

Zeidler, Conrad; Vrakking, Vincent; Bamsey, Matthew; Poulet, Lucie; Zabel, Paul; Schubert, Daniel; Paille, Christel; Mazzoleni, Erik; Domurath, Nico

doi:10.1515/opag-2017-0011

Cited by 23 publications

(11 citation statements)

References 8 publications

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“…The water cycle inside the underwater greenhouse depends on different parameters, such as the vapor partial pressure and the temperature inside the air volume, the radiation and the surface temperatures, the sea temperature, the vapor removal by specific heat exchangers and the plant watering system. In reference [22], Zeidler et al described the design of a technological greenhouse dedicated to the lunar space applications. In fact, the project aimed at developing a closed-loop bioregenerative life support system, essential for future human space missions, with the realization of a lunar greenhouse system able to produce specific quantities of selected plants.…”

Section: Smart Greenhouses Applicationsmentioning

confidence: 99%

Model Predictive Control versus Traditional Relay Control in a High Energy Efficiency Greenhouse

et al. 2021

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The sustainable agriculture cultivation in greenhouses is constantly evolving thanks to new technologies and methodologies able to improve the crop yield and to solve the common concerns which occur in protected environments. In this paper, an MPC-based control system has been realized in order to control the indoor air temperature in a high efficiency greenhouse. The main objective is to determine the optimal control signals related to the water mass flow rate supplied by a heat pump. The MPC model allows a predefined temperature profile to be tracked with an energy saving approach. The MPC has been implemented as a multiobjective optimization model that takes into account the dynamic behavior of the greenhouse in terms of energy and mass balances. The energy supply is provided by a ground coupled heat pump (GCHP) and by the solar radiation while the energy losses related to heat transfers across the glazed envelope. The proposed MPC method was applied in a smart innovative greenhouse located in Italy, and its performances were compared with a traditional reactive control method in terms of deviation of the indoor temperature in respect to the desired one and in terms of electric power consumption. The results demonstrated that, for a time horizon of 20 h, in a greenhouse with dimensions 15.3 and 9.9 m and an average height of 4.5 m, the proposed MPC approach saved about 30% in electric power compared with a relay control, guaranteeing a consistent and reliable temperature profile in respect to the predefined tracked one.

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Section: Smart Greenhouses Applicationsmentioning

confidence: 99%

Model Predictive Control versus Traditional Relay Control in a High Energy Efficiency Greenhouse

et al. 2021

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“…The EDEN ISS MTF was not the first design for a space greenhouse developed by DLR and partners-the greenhouse module for Space project for ESA involved the design of a deployable, expandable system [3]. Equipped with a central core, holding four deployable spherical growth chambers, this system provides a total of 650 m 2 of cultivation area.…”

Section: Previous Activities and Remaining Challengesmentioning

confidence: 99%

From ice to space: a greenhouse design for Moon or Mars based on a prototype deployed in Antarctica

et al. 2020

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The future of human space exploration is aimed at long-term missions to Moon and Mars. Currently, plans are elaborated by NASA, ESA, CNSA and others for a return to the lunar environment within the next decade as an intermediate step towards the goal of reaching the surface of Mars. For sustenance and crew comfort the crew of such long-duration missions should be provided with fresh food on the lunar or Martian surface. Due to the associated power demand, the required resources and technological complexity, this is a major challenge for this kind of missions. To continuously provide fresh food without the need for cargo transfer from Earth towards Moon or Mars an on-site greenhouse system is required, producing the fresh food in situ. The associated effort and cost for all resources to be transported to the base of operation prohibit any waste of resources, requiring a system operating in a (nearly) closed loop. Developing and validating a prototype for an effective and efficient greenhouse, labeled future exploration greenhouse (FEG) for space exploration has been the goal of the EDEN ISS project, funded by the EU, in the past 4 years. This paper shows the results of a design elaboration of the FEG into a greenhouse for planetary deployment on Moon or Mars. Guided by lessons learned from operating the FEG in Antarctica for one year and based on assumptions concerning the mission scenario, e.g. assuming an existing base infrastructure on-site, the presented design incorporates a plant growth area which is more than a factor of two larger than the prototype. The total mass of the cylindrical system, including equipment required during launch, transfer and landing, is about 19 mT, fitting into a Falcon 9 launcher. The versatile design is compatible with a wide variety of mission scenarios, e.g. ESA’s Moon Village, and currently public mission plans.

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“…On the inside is covered with mineral wool. Module design is inspired by DLR (German Aerospace Center) project [10]. Seed layer is placed on the rack.…”

Section: Cultivation Module Descriptionmentioning

confidence: 99%

Concept of aeroponic biomass cultivation and biological wastewater treatment system in extraterrestrial human base

Jurga

Kuźma

2018

E3S Web Conf.

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Greenhouse Module for Space System: A Lunar Greenhouse Design

Cited by 23 publications

References 8 publications

Model Predictive Control versus Traditional Relay Control in a High Energy Efficiency Greenhouse

Model Predictive Control versus Traditional Relay Control in a High Energy Efficiency Greenhouse

From ice to space: a greenhouse design for Moon or Mars based on a prototype deployed in Antarctica

Concept of aeroponic biomass cultivation and biological wastewater treatment system in extraterrestrial human base

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