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Characterization of heat transfer in nutrient materials, part 2 (1973)

Cox, J. E. ; Witte, L. C. ; Bannerot, R. B. ; [et al.]

In: CASI

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Publication Date: 2019-06-27

Description: A thermal model is analyzed that takes into account phase changes in the nutrient material. The behavior of fluids in low gravity environments is discussed along with low gravity heat transfer. Thermal contact resistance in the Skylab food heater is analyzed. The original model is modified to include: equivalent conductance due to radiation, radial equivalent conductance, wall equivalent conductance, and equivalent heat capacity. A constant wall-temperature model is presented.

Keywords: BIOTECHNOLOGY

Type: NASA-CR-134383 , REPT-9-11676-32-PT-2

Format: application/pdf

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2

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Characterization of heat transfer in nutrient materials, part 1 (1973)

Bannerot, R. B. ; Witte, L. C. ; Chen, C. K. ; [et al.]

In: CASI

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Publication Date: 2019-06-27

Description: The principles involved in food heating are discussed. The food heating system for Skylab is described. Thermal models of nutrient materials are analyzed including models in zero-g and low pressure conditions. Results are presented of parametric studies to establish the effect of individual parameters on the thermal response of the system.

Keywords: BIOTECHNOLOGY

Type: NASA-CR-134382

Format: application/pdf

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Thermal preparation of foods in space-vehicle environments (1974)

Bannerot, R. B. ; Cox, J. E. ; Chen, C. K. ; [et al.]

In: Other Sources

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Publication Date: 2019-06-27

Description: Convection is the primary heat transfer mechanism for most foods heated in an earth-based environment. In contrast, in the low-gravity environment of space flight, the primary heat transfer mechanism is conduction (or radiation in the absence of a conducting medium). Conduction heating is significantly slower and less efficient than convection heating. This fact poses a problem for food heating during space flight. A numerical model has been developed to evaluate this problem. This model simulates the food-heating process for Skylab. The model includes the effect of a thermally controlled on/off heat flux. Parametric studies using this model establish how the required heating time is affected by: the thermal diffusivity of the nutrient materials, the power level of the heater, the initial food temperatures, and the food container dimensions.

Keywords: BIOTECHNOLOGY

Type: Aerospace Medicine; 45; Mar. 197

Format: text

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Heating of foods in space-vehicle environments (1973)

Heidelbaugh, N. D. ; Bannerot, R. B. ; Chen, C. K. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: In extended space missions, foods will be heated to enhance the psychological as well as the physiological well-being of the crew. In the low-gravity space environment natural convection is essentially absent so that the heat transfer within the food is by conduction alone. To prevent boiling in reduced pressure environments the maximum temperature of the heating system is severely limited. The Skylab food-heating system utilizes a tray with receptables for the food containers. The walls of the receptacles are lined with thermally controlled, electrical-resistance, blanket-type heating elements. A finite difference model is employed to perform parametric studies on the food-heating system. The effects on heating time of the (1) thermophysical properties of the food, (2) heater power level, (3) initial food temperatures, (4) container geometry, and (5) heater control temperature are presented graphically. The optimal heater power level and container geometry are determined.

Keywords: BIOTECHNOLOGY

Type: ASME PAPER 73-WA/HT-15 , Winter Annual Meeting; Nov 11, 1973 - Nov 15, 1973; Detroit, MI

Format: text

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