The prediction of thermal stability of self-reactive chemicals - From milligrams to tons

Roduit  B; Borgeat  C; Berger  BFolly  PAlonso  BAebischer  JN

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The prediction of thermal stability of self-reactive chemicals - From milligrams to tons

机译：The prediction of thermal stability of self-reactive chemicals - From milligrams to tons

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An advanced study on the thermal behaviour of double base (boost and sustain propellant) rocket motor used in a ground to air missile has been carried out by differential scanning calorimetry (DSC). The presence of two propellants as well as the different experimental conditions (open vs. closed crucibles) influence the relative thermal stability of the energetic materials. Several methods have been presented for predictions of the reaction progress of exothermic reactions under adiabatic conditions. However, because decomposition reactions usually have a multi-step nature, the accurate determination of the kinetic characteristics strongly influences the ability to correctly describe the progress of the reaction. For self-heating reactions, incorrect kinetic description of the process is usually the main source of serious errors for the determination of the time to maximum rate under adiabatic conditions (TMRad). It is hazardous to develop safety predictive models that are based on simplified kinetics determined by thermoanalytical methods. Applications of finite element analysis (FEA) and accurate kinetic description allow determination of the effect of scale, geometry, heat transfer, thermal conductivity and ambient temperature on the heat accumulation conditions. Due to limited thermal conductivity, a progressive temperature increase in the sample can easily take place resulting in a thermal explosion. Use of both, kinetics and FEA [1], enables the determination of the reaction progress and temperature profiles in storage containers. The reaction progress and temperature can be determined quantitatively at every point in time and in space. This information is essential for the design of containers of self-reactive chemicals, cooling systems and the measures to be taken in the event of a cooling failure.

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来源
《Journal of thermal analysis and calorimetry》 |2005年第1期|91-102|共12页
作者
Roduit B; Borgeat C; Berger BFolly PAlonso BAebischer JN;
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作者单位

Adv Kinet & Technol Solut AKTS AG, TECHNO Pole, CH-3960 Siders, Switzerland;

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正文语种英语
中图分类分析化学;
关键词
adiabatic conditions; kinetics; safety; thermal ageing; thermal hazards; time to maximum rate; TMRad; ICTAC KINETICS PROJECT; SOLID-STATE REACTIONS; COMPUTATIONAL ASPECTS; PART; THERMOGRAVIMETRY;

The prediction of thermal stability of self-reactive chemicals - From milligrams to tons

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