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Standard Test Method for Heat of Ablation
STANDARD published on 1.5.2015
Designation standards: ASTM E458-08(2015)
Note: WITHDRAWN
Publication date standards: 1.5.2015
SKU: NS-590497
The number of pages: 7
Approximate weight : 21 g (0.05 lbs)
Country: American technical standard
Category: Technical standards ASTM
Keywords:
ablation, cold-wall heat of ablation, effective heat of ablation, heat of ablation, thermochemical heat of ablation ,, ICS Number Code 17.200.10 (Heat. Calorimetry)
Significance and Use | |||||||||||||||||||||
4.1 General—The heat of ablation provides a measure of the ability of a material to serve as a heat protection element in a severe thermal environment. The parameter is a function of both the material and the environment to which it is subjected. It is therefore required that laboratory measurements of heat of ablation simulate the service environment as closely as possible. Some of the parameters affecting the heat of ablation are pressure, gas composition, heat transfer rate, mode of heat transfer, and gas enthalpy. As laboratory duplication of all parameters is usually difficult, the user of the data should consider the differences between the service and the test environments. Screening tests of various materials under simulated use conditions may be quite valuable even if all the service environmental parameters are not available. These tests are useful in material selection studies, materials development work, and many other areas. 4.2 Steady-State Conditions—The nature of the definition of heat of ablation requires steady-state conditions. Variances from steady-state may be required in certain circumstances; however, it must be realized that transient phenomena make the values obtained functions of the test duration and therefore make material comparisons difficult. 4.2.1 Temperature Requirements—In a
steady-state condition, the temperature propagation into the
material will move at the same velocity as the gas-ablation surface
interface. A constant distance is maintained between the ablation
surface and the isotherm representing the temperature front. Under
steady-state ablation the mass loss and length change are linearly
related.
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