Mussel-inspired PTW@PDA composites for developing high-energy gun propellants with reduced erosion and enhanced mechanical strength

The severe erosion and inadequate mechanical strength are prominent challenges for high-energy gun propellants.To address it,novel PTW@PDA composites was prepared by polydopamine(PDA)-modifying onto potassium titanate whisker(PTW,K_(2)Ti_(6)O_(13)),and after was incorporated into gun propellant as erosion-reducing and mechanical-reinforcing fillers.The interfacial characterizations results indicated that as-prepared PTW@PDA composites exhibits an enhanced surface compatible with propellant matrix,thereby facilitating their dispersion into propellants more effectively than raw PTW materials.Compared to original propellants,PTW@PDA-modified propellants exhibited significant less erosion,with a Ti-Kbased protective coating being detected on the eroded steel.And 0.5 wt%and 1.0 wt%addition of PTW@PDA significantly improved impact,compressive and tensile strength of propellants.Despite the inevitably reduction in relative force,PTW@PDA slightly increase propellant burning rate while exerting little adverse impact on propellant dynamic activity.This strategy can provide a promising alternative to develop high-energy gun propellant with less erosion and more mechanical strength.

One-step green method to prepare progressive burning gun propellant through gradient denitration strategy

Gradiently denitrated gun propellant(GDGP)prepared by a“gradient denitration”strategy is obviously superior in progressive burning performance to the traditional deterred gun propellant.Currently,the preparation of GDGP employed a tedious two-step method involving organic solvents,which hinders the large-scale preparation of GDGP.In this paper,GDGP was successfully prepared via a novelty and environmentally friendly one-step method.The obtained samples were characterized by FT-IR,Raman,SEM and XPS.The results showed that the content of nitrate groups gradiently increased from the surface to the core in the surface layer of GDGP and the surface layer of GDGP exhibited a higher compaction than that of raw gun propellant,with a well-preserved nitrocellulose structure.The denitration process enabled the propellant surface with regressive energy density and good progressive burning performance,as confirmed by oxygen bomb and closed bomb test.At the same time,the effects of different solvents on the component loss of propellant were compared.The result showed that water caused the least component loss.Finally,the stability of GDGP was confirmed by methyl-violet test.This work not only provided environmentally friendly,simple and economic preparation of GDGP,but also confirmed the stability of GDGP prepared by this method.

Construction of smart propellant with multi-morphologies

Smart materials,which exhibit shape memory behavior in response to external stimuli,have shown great potential for use in biomedical applications.In this study,an energetic composite was fabricated using a UV-assisted DIW 3D printing technique and a shape memory material(SMP)as the binder.This composite has the ability to reduce the impact of external factors and adjust gun propellant combustion behavior.The composition and 3D printing process were delineated,while the internal structure and shape memory performance of the composite material were studied.The energetic SMP composite exhibits an angle of reversal of 18 s at 70°,with a maximum elongation typically reaching up to 280% of the original length and a recovery length of approximately 105%during ten cycles.Additionally,thermal decomposition and combustion behavior were also demonstrated for the energetic SMP composite.

Experimental Simulation for Fracture of Gun Propellant Charge Bed

The simulation of compression and fracture of charge bed in chamber is one of the key problems in the study of launch safety of gun propellant charge. A new kind of experimental device that can be used for simulation is given. Its structure and operational principle are introduced. Using a semi-closed vessel as a source of compression force, the device can simulate any kind of dynamic environment in a gun propellant charge. Using the low temperature inert gas （N2） as the compression medium, the device can not only ensure that the simulation is real, but also protect the fragmentized propellant from combustion after experiment. Using the device, many simulation experiments have been accomplished, and dynamic environment of propellant fracture is acquired. With the experiments, fragmentized propellant for the compression and fracture of charge bed is obtained. Results of experiments show that the new device can be used to study the principle of the compression and fracture of charge bed.

Thermal Behavior,Nonisothermal Decomposition Reaction Kinetics of Mixed Ester Double-base Gun Propellants

The thermal decomposition behavior and nonisothermal reaction kinetics of the double-base gun propellants containing the mixed ester of triethyleneglycol dinitrate（TEGDN） and nitroglycerin（NG） were investigated by thermogravimetry（TG） and differential thermogravimetry（DTG）, and differential scanning calorimetry（DSC） under the high-pressure dynamic ambience. The results show that the thermal decomposition processes of the mixed nitric ester gun propellants have two mass-loss stages. Nitric ester evaporates and decomposes in the first stage, and nitrocellulose and centralite II（C2） decompose in the second stage. The mass loss, the DTG peak points, and the terminated temperatures of the two stages are changeable with the difference of the mass ratio of TEGDN to NG. There is only one obvious exothermic peak in the DSC curves under the different pressures. With the increase in the furnace pressure, the peak temperature decreases, and the decomposition heat increases. With the increase in the content of TEGDN, the decomposition heat decreases at 0.1 MPa and rises at high pressure. The variety of mass ratio of TEGDN to NG makes few effect on the exothermic peak temperatures in the DSC curves at different pressures. The kinetic equation of the main exothermal decomposition reaction of the gun propellant TG0601 was determined as： dα/dt=1021.59（1-α）3e-2.60×104/T. The reaction mechanism of the process can be classified as chemical reaction. The critical temperatures of the thermal explosion（Tbe and Tbp） obtained from the onset temperature（Te） and the peak temperature（Tp） are 456.46 and 473.40 K, respectively. ΔS≠, ΔH≠, and ΔG≠ of the decomposition reaction are 163.57 J·mol^-1·K^-1, 209.54 kJ·mol^-1, and 133.55 kJ·mol^-1, respectively.

Influence of Firing Temperature on Properties of Gun Propellants

Initial firing temperatures play an important role on the combustion rate of propellant. In gun propellants, initial temperature is a key factor for both accuracy and safety. Ideally, the initial temperature of the propellant should not influence the ballistic properties of the round. Nevertheless, constant initial temperature coefficients can not be achieved easily. This work focuses on the influence of the firing temperature on the ballistic properties, the mechanical integrity and the sensitivity to impact of nitrocellulose based propellants. Combustion rates have been determined by closed vessel tests. Ballistic properties have been investigated by firing 5.56 cartridges. The propellants have been conditioned at temperatures ranging from -54 ℃ to ＋71 ℃ before firing. The largest temperature coefficient is observed at high temperatures. The temperature sensitivity of the peak pressure in the combustion chamber can not be fully explained by the results from the closed vessel test. The authors speculated that the mechanical behaviour of the propellant grains at low temperatures influences also the overall ballistic properties of the round. Impact tests with propellants conditioned at low and high temperatures permit to investigate their mechanical strength under extreme temperatures and to better understand the propellant performance during firing. Tests on aged propellants have been conducted as well.

Formulation development and characterization of cellulose acetate nitrate based propellants for improved insensitive munitions properties

Cellulose acetate nitrate(CAN) was used as an insensitive energetic binder to improve the insensitive munitions(IM) properties of gun propellants to replace the M1 propellant used in 105 mm artillery charges.CAN contains the energetic nitro groups found in nitrocellulose(NC),but also acetyl functionalities,which lowered the polymer's sensitivity to heat and shock,and therefore improved its IM properties relative to NC.The formulation,development and small-scale characterization testing of several CAN-based propellants were done.The formulations,using insensitive energetic solid fillers and high-nitrogen modifiers in place of nitramine were completed.The small scale characterization testing,such as closed bomb testing,small scale sensitivity,thermal stability,and chemical compatibility were done.The mechanical response of the propellants under high-rate uni-axial compression at,hot,cold,and ambient temperatures were also completed.Critical diameter testing,hot fragment conductive ignition(HFCI) tests were done to evaluate the propellants' responses to thermal and shock stimuli.Utilizing the propellant chemical composition,theoretical predictions of erosivity were completed.All the small scale test results were utilized to down-select the promising CAN based formulations for large scale demonstration testing such as the ballistic performance and fragment impact testing in the105 mm M67 artillery charge configurations.The test results completed in the small and large scale testing are discussed.

Innovative boron nitride-doped propellants

The U.S. military has a need for more powerful propellants with balanced/stoichiometric amounts of fuel and oxidants. However, balanced and more powerful propellants lead to accelerated gun barrel erosion and markedly shortened useful barrel life. Boron nitride(BN) is an interesting potential additive for propellants that could reduce gun wear effects in advanced propellants(US patent pending 2015-026P). Hexagonal boron nitride is a good lubricant that can provide wear resistance and lower flame temperatures for gun barrels. Further, boron can dope steel, which drastically improves its strength and wear resistance, and can block the formation of softer carbides. A scalable synthesis method for producing boron nitride nano-particles that can be readily dispersed into propellants has been developed. Even dispersion of the nano-particles in a double-base propellant has been demonstrated using a solvent-based processing approach. Stability of a composite propellant with the BN additive was verified. In this paper, results from propellant testing of boron nitride nano-composite propellants are presented, including closed bomb and wear and erosion testing. Detailed characterization of the erosion tester substrates before and after firing was obtained by electron microscopy,inductively coupled plasma and x-ray photoelectron spectroscopy. This promising boron nitride additive shows the ability to improve gun wear and erosion resistance without any destabilizing effects to the propellant. Potential applications could include less erosive propellants in propellant ammunition for large, medium and small diameter fire arms.

An Operational Modal Analysis Experimental Technique for Self-propelled Gun

The experimental modal analysis of the selected self-propelled gun was completed to obtain its modal frequency distribution and modes by using an operational modal analysis experimental technique.The result obtained by the method was compared with that obtained by the traditional method.It indicates that the two results are in good agreement.

Discussion on Mechanism of Breech-Blow Caused by Propellant Charge

From the view point of launch safety caused by fracture of propellant charge,this paper points out that the safety criterion of pressure wave is inadequate to evaluate the launch safety of propellant charge based on the initial negative differential pressure and sensitivity tests.Generally,the maximum barrel pressure does not depend upon the intensity of pressure wave correspondingly.The pressure wave intensity can not describe the fracture degree of propellant charge in chamber and reflect the mechanical environment of propellant charge fracturing exactly and wholly.The evaluation criterion for launch safety of propellant charge should be built on the basis of depicting the fracture degree of propellant bed.

现代火炮内弹道面临的问题与对策

从现代火炮及弹药技术的发展趋势,分析了火炮内弹道面临的问题,阐述了火炮内弹道理论与技术的发展方向,集中体现在三个方面,一是提高常规固体发射药火炮的作战效能;二是发展与制导弹药等特种弹药发射方式相适应的内弹道理论与控制技术;三是研究新能源火炮的内弹道理论与控制技术。在此基础上,结合国内外研究状况,对若干重点问题进行了述评,并提出了研究对策。

DIANP合成及其在发射药中的应用研究进展

DIANP发射药作为一种新型发射药,具有能量高,爆温低,燃烧洁净性好,烟焰残渣少等特点。研究介绍了DIANP合成与材料特性,DIANP发射药配方及性能,DIANP发射药制备工艺、表面处理、装药应用和测试方法等方面的研究进展。指出了DIANP发射药在燃烧分解机理和相互作用机制等基础理论研究方面存在的不足;提出了应开展适用于DIANP发射药的温度系数控制技术研究、环境适应性研究和DIANP合成的绿色工艺研究;并认为DIANP发射药的改进需将理论研究和实际应用相结合,以此推进高能低烧蚀特征材料在行业内的发展。

环糊精金属有机框架材料对发射药静态燃烧火焰特性的影响

通过蒸汽扩散法成功合成了3种环糊精金属有机框架(CD-MOF)材料,并采用单晶X-射线衍射对其单晶结构进行解析。作为潜在的消焰剂,相比传统的硝酸钾热分解温度(722.0℃),3种CD-MOF更低(250.9℃;261.0℃;290.3℃),更容易释放钾离子,且在硝化纤维素(NC)中显示出良好的物理分散性和化学相容性。此外,添加CD-MOF的NC在热分解时产生的易燃和有害气体(CO、NO、NO_(2)和N_(2)O)更少。添加γ-CD-MOF的单基药在燃烧时表现出最小的火焰面积(119.6 mm^(2)),而添加β-CD-MOF的单基药显示出更低的火焰面积标准偏差(8.4 mm^(2)),表明其消焰效能更稳定。相比之下,添加KNO_(3)的单基药火焰面积最大(392.7 mm^(2))。

含叠氮增塑剂AZDEGDN发射药的制备和燃烧性能

为了探索新型叠氮增塑剂1,5-二叠氮基-3-氧杂戊烷(AZDEGDN)在发射药配方中的应用前景,采用半溶剂法制备了以AZDEGDN为增塑剂的双基和三基发射药,并对含AZDEGDN发射药的形貌、密度及在不同温度下的静态燃烧性能进行了研究。结果表明,使用半溶剂法挤出成型工艺能够制备得到外观无明显瑕疵的含AZDEGDN的双基发射药(ADG-2)和三基发射药(ADG-3)。SEM观测显示,固体添加剂黑索今(RDX)和硝基胍(NGu)能够较为均匀地分布在ADG-3发射药内部。密度测试显示,ADG-2和ADG-3发射药的密度分别为1.44 g·cm^(-3)和1.52 g·cm^(-3),均接近理论密度,说明发射药内部结构较为致密。密闭爆发器试验表明,常温(20℃)下,ADG-2和ADG-3发射药的静态燃烧性能均较为稳定,燃速随着压强增大而均匀上升,未出现明显的燃速-压强曲线(u-p曲线)转折现象,燃烧最大压强分别为237.71 MPa和263.80 MPa,燃速压强指数分别为0.9098和0.9754;RDX和NGu的添加使得含AZDEGDN发射药在低压段(50~100 MPa)和中压段(100~150 MPa)的燃速压强指数分别增大了15.5%和10.9%,而在高压段(150~p_(dpm) MPa)的燃速压强指数减小了4.2%;高温(50℃)和低温(-40℃)下,ADG-3发射药仍然能够保持稳定燃烧,燃烧最大压强由常温下的263.80 MPa分别变为265.92 MPa和261.13 MPa,燃烧时间由14.70 ms分别变为13.52 ms和16.40 ms,燃速压强指数由0.9754分别变为0.9464和0.9938。可见含AZDEGDN发射药的制备方法简单成熟,结构致密无瑕疵,静态燃烧性能稳定,有望成为一种新型低烧蚀发射药。

模糊综合评价模型在高能硝胺发射药改性评价中的应用研究

为研究模糊综合评价模型在高能硝胺发射药改性评价中的应用,采用包覆工艺,分别选取三氨基三硝基苯(TATB)和聚酯(NA)作为包覆工艺中的降燃速材料,制备了TATB包覆发射药和NA包覆发射药,对比了包覆和未包覆发射药的堆积密度、局部燃速、爆热、燃烧渐增性以及内弹道性能;基于此实验结果,采用层次分析法,评价了TATB和NA对发射药基本性质和燃烧性能的影响程度。研究建立了发射药基本性质和发射药燃烧性能间的模糊评价方法;发现面向发射药燃烧性能,局部燃速的影响权重最大,为0.82;爆热的影响权重次之,为0.11;堆积密度的影响权重为0.07。在堆积密度差异较小的情况下,由于NA包覆发射药的降燃速效果明显强于TATB包覆发射药,NA包覆发射药的能量损失虽然较TATB包覆发射药更大,NA包覆发射药的燃烧性能优于TATB包覆发射药,且二者明显强于未包覆的空白发射药。

发射药燃气对身管材料的烧蚀速率的计算模型

为构建贴合实际需求的发射药烧蚀性能评价体系,设计半密闭爆发器烧蚀管实验,根据烧蚀管的几何尺寸及实验测量p-t曲线,建立了二维非稳态流动与传热模型,通过烧蚀管壁温的时空分布建立了烧蚀速率模型参数与烧蚀总量的关系。将半密闭爆发器烧蚀管实验的烧蚀量作为基准,采用粒子群算法对烧蚀速率模型参数进行了优化计算。结果表明:随着发射药燃气对烧蚀管冲刷时间增加,燃气与烧蚀管间的流固耦合界面温度有所降低,烧蚀管截面熔融深度的增速减缓;烧蚀管材料为45#钢,发射药为典型双基药(双芳-3)时,优化得到烧蚀速率的指前因子和表观活化能分别为0.3403 s^(-1)和134.6 kJ·mol^(-1),此时损失函数值仅为3.0×10^(-6),可推广应用于身管武器平台的烧蚀状态计算。

超临界二氧化碳在螺杆挤出过程中塑化混合酯发射药的研究:在线流变仪设计与实验测量

为了改善混合酯发射药的加工流动性,在其挤出过程中注入超临界二氧化碳(SC-CO_(2))作为增塑剂;为了更好地研究塑化过程,设计制造了一个在线狭缝流变仪用来测量混合酯发射药的剪切黏度和流变参数。流动曲线表明,混合酯发射药和SC-CO_(2)/发射药混合物都是非牛顿假塑性流体,幂律模型可以用来描述SC-CO_(2)/发射药混合物的流变行为。实验研究了剪切黏度随加工温度和增塑剂含量的变化规律,结果显示较高的加工温度有利于降低剪切黏度。在注入SC-CO_(2)后,黏流活化能降低了约20 kJ/mol。SC-CO_(2)被证明是一种有效的增塑剂,可以显著改善混合酯发射药的流动性。并且随着SC-CO_(2)含量的增加,挤出过程中的流动性会更好,但增塑剂含量的不断增加并不能无限制地提升塑化效果。

含CL-20的微孔发射药的设计及性能研究

为了研究六硝基六氮杂异伍兹烷(CL-20)含量及微孔结构对发射药性能的影响,采用超临界发泡工艺设计并制备了含CL-20的微孔发射药。利用扫描电子显微镜(SEM)观察了发射药的形貌结构,通过密闭爆发器实验、简支梁冲击仪和摩擦感度仪等研究了发射药的燃烧性能、力学性能和感度。结果表明:CL-20颗粒均匀地分散在样品表面及内部,样品内部形成了大量尺寸为0.08~2.00μm的泡孔;CL-20颗粒的加入降低了样品的力学性能,CL-20含量越高,样品的抗冲击强度与拉伸强度降低得越明显;随着CL-20含量的增加,样品的摩擦感度和静电感度会随之升高,燃速也会得到一定程度的提高;经发泡改性后的样品的力学性能弱于未经发泡改性的样品;发泡工艺能够抑制因CL-20含量上升而导致的感度上升;经过发泡后的样品,燃烧性能得到了显著提升,样品的L-B(相对动态活度-相对压力)曲线在B为0~0.10范围内即出现急速上升趋势,L在B为0.14~0.18范围内达到最大,CL-20质量分数为15%和20%时,L_(max)分别为14.39 MPa^(-1)·s^(-1)和9.70 MPa^(-1)·s^(-1)。

自行高炮稳定跟踪系统建模与谐振抑制方法

未来战场的高机动作战环境对自行高炮稳定跟踪系统提出了更高的性能要求,根据自行高炮稳定跟踪系统的机械结构特点,应用动量矩定理及矢量求导,基于牛顿-欧拉方法建立描述伺服电机配以减速机驱动方位炮塔和俯仰身管的多刚体动力学模型。通过对动力学模型的进一步分解,得到方位俯仰姿态角与输入力矩的关系式。综合考虑传动机构的刚度和控制对象的变惯量特性,建立载体运动姿态耦合条件下具有复杂动载荷力矩干扰的双轴稳定跟踪系统控制模型。针对结构谐振设计一种基于极点配置法和变增益加速度反馈的自整定PI控制方法与基于观测等效惯量的自整定陷波器,采用大地坐标系下的等效闭环干扰速率补偿式稳定控制策略,对该控制方法进行仿真验证。仿真结果表明:在传动机构存在连接弹性的条件下,所给出的控制方法实现了稳定误差不大于2.2×10^(-2) mrad、正弦稳定跟踪误差不大于3.5×10^(-2) mrad,具有良好的控制精度和抗扰动性能;在保证系统拥有较快响应速度的同时,有效抑制了伺服电机变速和稳态过程中的机械谐振,显著降低了负载力矩振荡和负载有效转矩值。

发射药与装药技术发展展望

发射药作为枪炮武器发射与精准毁伤的功能单元,具有关键与核心技术地位。通过总结归纳发射药与装药技术的发展历程,系统分析其演化规律,从科学、技术、产品三个层次阐述了发射药与装药技术的研究现状和主要问题。同时从科学探索发现、技术创新发明进步、产品与武器装备应用等方面对发射药与装药技术未来的发展方向进行了分析与展望,以期为发射药研究者、行业管理、制造企业提供参考,推动行业领域的发展。