Combustion heat of the Al/B powder and its application in metallized explosives in underwater explosions

Xu, Sen; Chen, Yu; Chen, X.; Wu, Dejun; Liu, D.

doi:10.1134/s001050821603014x

Cited by 35 publications

(15 citation statements)

References 14 publications

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“…Song et al [20][21][22] prepared the AlÀB alloy powder by a mechanical milling method and found that the combustion performance and the burning rate pressure index of the boron powder can be effectively improved. Xu et al [23] mechanically blended a certain amount of elemental B powder and Al powder, and measured the combustion enthalpy of this Al/B mixed powder by oxygen bomb calorimeter. They indicated when the content of B was 40 %, the combustion enthalpy reached the [ A large number of researches have shown that the preparation of AlÀB alloy powder can not only effectively increase the total calorific value but also optimize the oxidation and combustion performance [24].…”

Section: Introductionmentioning

confidence: 99%

The Oxidation and Combustion Properties of Gas Atomized Aluminum−Boron−Europium Alloy Powders

Wang

Zou

Cai

2019

Propellants Explo Pyrotec

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In this paper, the Aluminum−boron−europium ternary alloy fuels with boron content of 1.5∼4.85 wt. % and europium content of 3 wt. % were prepared by the close‐coupled gas atomization. XRD, SEM, TG‐DTA and oxygen bomb test were used to analyze the phase constituents, morphology, thermal oxidation behavior and combustion exothermic property of powders, respectively. The functions of boron and europium on the combustion of metal fuels were studied, and a reasonable oxidation model of the alloy particles was proposed. The results show that there are Al, AlB2, Al4Eu and B6Eu in the alloy. When the europium content is constant, the combustion enthalpy of the Al−B−Eu alloy powder firstly increases and then decreases as the boron content increases. Additionally, at oxygen pressure of 3.0 MPa, the Al−3.5B−3Eu ternary alloy powder burned completely with the maximum combustion enthalpy of 33324.5 J g−1. This increases by 11 % compared with theoretical combustion enthalpy of aluminum powder (31.1 kJ g−1). Al−3.5B−3Eu undergoes a dramatic oxidation exothermal phenomenon at 1110 °C with the weight increase efficiency of 53.66 %, which is 1.7 times that of aluminum. Due to the synergistic effects between the phase of B6Eu and AlB2 inside the alloy particles, the Al−3.5B−3Eu alloy powder shows excellent exothermic performance.

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Section: Introductionmentioning

confidence: 99%

The Oxidation and Combustion Properties of Gas Atomized Aluminum−Boron−Europium Alloy Powders

Wang

Zou

Cai

2019

Propellants Explo Pyrotec

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“…However, the application of boron powder is complicated by the formation of an inert oxide layer on the particles surface, which leads to an increase in the ignition delay time and complete combustion time. To reduce the time and the temperature of boron ignition and to increase its combustion completeness, additives based on Mg, Al, Fe, Cu, Bi, Ce [10][11][12][13][14] are used, which make it possible to reduce the ignition times by up to two times [10], and the ignition temperature by 10 % [11]. In addition, the introduction of such additives makes it possible to increase the completeness of conversion [10,11,13], which makes the use of bimetal powder in HEM one of the most promising areas of research.…”

Section: Introductionmentioning

confidence: 99%

Effect of Me/B‐Powder on the Ignition of High‐Energy Materials

Коротких

Sorokin

2021

Propellants Explo Pyrotec

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The study of the ignition characteristics of highenergy materials (HEMs) is important in solving a number of practical problems related to the assessment of explosion safety, the calculation of transition processes in power installation for various purposes (rocket and space technologies, weapons, pyrotechnics). This paper presents the experimental data on the thermal oxidation of ultrafine powder (UFP) based on Al/B, Ti/B, Ni/B, and Fe/B and the experimental characteristics of the ignition of HEM based on ammonium perchlorate, butadiene rubber, and metal fuel. In the course of processing thermal analysis data, the values of oxidation temperatures, the specific heat effect of the oxidation reaction, and the rate of weight gain of powder during heated at a constant rate of 10 °C/min in air were determined. It was shown that the oxidation of Ti/B and Ni/B UFPs begins at temperature of 490-500 °C, which is 60-70 °C lower than the onset oxidation temperature for boron powder. The use of 15.7 wt.% the mixed UFP based on Al/B, Ti/B, Ni/B or Fe/B in HEM reduces the ignition delay time by 7-50 % compared to boron-based HEM in the range of heat flux density from 60 to 200 W/cm 2 . Based on experimental data of the ignition delay time versus the heat flux density, the formal activation energy, the multiplication of the specific heat flux of the reactions by the pre-exponent and the ignition temperature are calculated which could be used in mathematical modeling of the ignition for composite solid propellant containing metal fuels.

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“…6 Research has shown that compared with aluminum-containing compositions, such as Al/octogen (HMX) and hexogen (RDX)/Al/ammonium perchlorate (AP), boron-containing ones, B/HMX and RDX/Al/B/AP, have a higher energy. 7 This indicates that boron is a potential candidate for use as a fuel additive in almost all energetic materials. Nevertheless, the elemental boron particles have a tight coating layer in the form of oxides and hydrates, which reduces the performance as a fuel and leads to inefficient burning.…”

Section: Introductionmentioning

confidence: 99%

Preparation and properties of a novel covalently bonded energetic boron powder and its composite

et al. 2018

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Combustion heat of the Al/B powder and its application in metallized explosives in underwater explosions

Cited by 35 publications

References 14 publications

The Oxidation and Combustion Properties of Gas Atomized Aluminum−Boron−Europium Alloy Powders

The Oxidation and Combustion Properties of Gas Atomized Aluminum−Boron−Europium Alloy Powders

Effect of Me/B‐Powder on the Ignition of High‐Energy Materials

Preparation and properties of a novel covalently bonded energetic boron powder and its composite

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