Method for determining temperature correction coefficient of energetic material chemical combination process

A technology of temperature correction coefficient and determination method, applied in computer material science, computational theoretical chemistry, chemical process analysis/design, etc., can solve problems such as poor operability, difficult material risk assessment, lack of quantitative criteria, etc., to achieve safety Use high reliability, determine comprehensive and reliable effects, and conservative results

Pending Publication Date: 2020-12-18
XIAN MODERN CHEM RES INST
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Problems solved by technology

[0019] It can be seen from Table 1 that the temperature correction coefficient γ 1 The method of determination is a semi-quantitative method. Although there are corresponding evaluation parameter values, the actual operability is poor, and the values ​​cannot be accurately qua

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  • Method for determining temperature correction coefficient of energetic material chemical combination process
  • Method for determining temperature correction coefficient of energetic material chemical combination process
  • Method for determining temperature correction coefficient of energetic material chemical combination process

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Embodiment Construction

[0058] The present invention is a method for determining the temperature correction coefficient of the compounding process of energetic materials. Taking BuNENA, the material of the compounding process of butyl nitroxyethyl nitroamine, as the research object, the thermal decomposition reaction of the material is tested by differential scanning calorimetry, and different temperature rises are obtained. The characteristic quantity of thermal decomposition under the rate, according to the Kissinger equation regression to obtain the kinetic parameter apparent activation energy E of the thermal decomposition reaction of the material a and the pre-exponential factor A, and then obtain the TMR between the maximum reaction rates of adiabatic conditions with different hazard levels ad The required process temperature T p , and process temperature T with different hazard levels p And the ratio operating time coefficient δ is the scale, and the actual process temperature T of the materi...

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Abstract

The invention discloses a method for determining a temperature correction coefficient of an energetic material chemical combination process, which comprises the following steps of: obtaining a thermaldecomposition reaction kinetic parameter according to a material thermal decomposition characteristic quantity of an energetic material in a chemical combination process, and further obtaining a process temperature required by the maximum reaction rate arrival time of heat insulation conditions of different danger levels; and quantitatively obtaining a temperature correction coefficient gamma1 bytaking the process temperatures of different danger levels and the specific operation time as scales. The method has universality, is suitable for evaluating the thermal stability of different energetic materials, is comprehensive and reliable in temperature correction coefficient determination and high in operability, and the determined temperature correction coefficient is conservative in result and high in safe use reliability.

Description

technical field [0001] The invention belongs to the technical field of risk assessment of energetic materials, and mainly relates to a method for determining the temperature correction coefficient of the compounding process of energetic materials. Background technique [0002] Energetic materials are prone to combustion and explosion under thermal, static, mechanical and other stimuli. Carrying out the risk assessment of combustion and explosion in the compounding process of energetic materials is an important part of safety production design and control. The material in the energetic material compounding process is a poor conductor of heat and is extremely sensitive to thermal stimulation. It will undergo self-catalytic decomposition and exothermic reaction when heated, and it is easy to generate heat accumulation and cause thermal explosion, which is the inducing factor of a large number of safety accidents. Therefore, the process The assessment of combustion and explosion...

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Application Information

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IPC IPC(8): G16C20/10G16C10/00G16C60/00
CPCG16C20/10G16C10/00G16C60/00
Inventor 丁黎禄旭华栋黄蒙祝艳龙安静
Owner XIAN MODERN CHEM RES INST
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