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2024, 38(6)  
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2024, 38(6): 1-2.  
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High Pressure Technology and Material Synthesis
High-Temperature and High-Pressure Synthesis of High-Entropy Transition Metal Diborides
LONG Haidong, CHEN Jie, XIAO Xiong, PENG Fang
2024, 38(6): 063101.   doi: 10.11858/gywlxb.20240790
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High-entropy transition metal diborides have been extensively studied due to their high mechanical and thermodynamic properties. However, the conventional synthesis methods of these materials are inefficient. In this paper, we synthesized six types of high-entropy transition metal diborides based on VB2, NbB2, and TaB2 by high-temperature and high-pressure solid-state reactions at 5.5 GPa and 2300 °C. The high pressure promoted the efficiency of solid-state reaction and facilitated the synthesis of high-entropy transition metal diborides. The X-ray diffraction and energy dispersive X-ray spectroscopy results have been confirmed that the six types of high-entropy transition metal diborides possessed pure phase compositions without oxide impurities or second phases, and exhibited uniform elemental distribution without elemental segregation. These results demonstrate that the synthesis of high-entropy transition metal diborides by using high-temperature and high-pressure solid-state reaction method is effectiveness and practicality.

Measurement of the Melting Point of Hexagonal Boron Nitride under Pressures below 5 GPa
ZHANG Ruike, GUO Rui’ang, XIAO Xiong, HE Duanwei
2024, 38(6): 063401.   doi: 10.11858/gywlxb.20240813
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In this study, a flash-heating device was designed and assembled to achieve instantaneous discharge heating of samples under high pressure in the DS 6×14 MN domestic hinged six-anvil large chamber press. By combining large chamber static high pressure and instantaneous discharge heating technologies, the melting state of crystals has been determined by the nucleation and growth characteristics during solidification. The melting behavior of h-BN powder crystal under high pressure was studied by instantaneous discharge heating treatment. Using scanning electron microscopy (SEM), the microstructures of samples obtained by high-pressure instantaneous discharge heating treatment was analyzed in order to assess the melting state of h-BN crystals. It was determined that the melting points of h-BN under 3.4 and 4.3 GPa are (4251±150) K and (4531±200) K, respectively. These results are beneficial for exploring the applications of h-BN and revising the existed temperature-pressure phase diagram of boron nitride.

Dynamic Response of Matter
Effects of Shock Peak Stress and Pulse Duration on Spall Damage of NbTiZr Medium-Entropy Alloy
LUO Xiaoping, LI Xuhai, TANG Zeming, LI Zhiguo, CHEN Sen, WANG Yuan, YU Yuying, HU Jianbo
2024, 38(6): 064101.   doi: 10.11858/gywlxb.20240771
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Dynamic mechanical behaviors of high entropy alloys (HEAs) or medium-entropy alloys (MEAs) have attracted significant attention due to their exceptional strength-toughness balance and promising potential applications in extreme conditions. This work investigates the effects of peak shock stress and pulse duration on the spall damage of the NbTiZr MEA under dynamic shock loading. Peak shock stresses, pulse durations and spall strengths are determined by analyzing free surface velocity profiles, with postmortem microstructural analysis to reveal the underlying deformation and failure mechanisms. The measured spall strength of NbTiZr MEA ranges from 3.77 GPa to 4.80 GPa, showing minimal dependence on the peak shock stress but high sensitivity to the pulse duration. Furthermore, the damage morphologies are significantly influenced by pulse durations. The damage is recognized as a quasi-cleavage fracture mode. No phase transition or deformation twins are observed within the recovered NbTiZr alloy.

Experimental Study on Dynamic High Pressure Properties of G54 Steel
WANG Bo, PEI Hongbo, LI Xuhai, GAO Qi, HE Yu, CHEN Yonglong, GUI Yulin
2024, 38(6): 064102.   doi: 10.11858/gywlxb.20240833
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G54 steel is a new type of ultra-high strength steel independently developed in China, which has strong potential application value. In order to study the dynamic high-pressure performance of the material and provide data support for its application and popularization, the flyer symmetric impact experiments of G54 steel were conducted by using artillery as loading means. The experimental flyer velocities ranged from 600 m/s to 1400 m/s. By measuring the velocity-time history of particles on the back surface of G54 steel samples, the typical impact transformation and spallation signals were obtained. By analyzing particle velocities, material density and sound velocity measurements, the Hugoniot elastic limit, spallation strength, shock wave velocity-particle velocity (D-u) relationship and impact transformation point of G54 steel under impact pressure of 13–23 GPa were obtained. The metallographic analysis results of the recovered sample show that the damage mechanism of the spallation surface changes from ductile fracture dominated by micropore polymerization to ductile fracture dominated by adiabatic shear with the increase of flyer velocity.

Acoustic Emission Characteristics and Crack Types Evolution of Soft and Hard Interbedded Rock-Like Specimens under Uniaxial Compression
WANG Zheng, GUO Jiaqi, GAO Fenghui, CHENG Lipan, TIAN Yongchao
2024, 38(6): 064103.   doi: 10.11858/gywlxb.20240812
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In order to further reveal the acoustic emission characteristics and crack propagation law of soft and hard interbedded rock with different bedding plane dip angles under uniaxial compression, the soft and hard interbedded rock-like samples were prepared by rock-like materials. Based on the RMT-150B rock mechanics test system equipped with DS-5 acoustic emission monitoring system, uniaxial compression experiments were carried out on soft and hard interbedded rock-like samples with different bedding plane dip angles (0°, 30°, 45°, 60°, and 90°). Accordingly, the influences of bedding plane dip angle on acoustic emission characteristics, damage evolution and crack propagation of rock samples were analyzed. The results show that the acoustic emission activity of the sample presents obvious stage characteristics, and its distribution characteristics are obviously different under different bedding plane dip angles. The acoustic emission characteristic parameters show obvious bedding effect, and the cumulative ringing count and cumulative energy of acoustic emission decrease first and then increase with the increase of bedding plane dip angle. The sudden appearance or increase in the proportion of low frequency-ultra high amplitude signals can be used as a precursor information for the failure of soft-hard interbedded rock samples. The failure of low-angle (0° and 30°) samples is the steady expansion of large-scale cracks. The failure of medium-angle (45° and 60°) samples is the sudden instability expansion of large-scale cracks. The failure of high-angle (90°) samples is the sudden instability expansion of small-scale cracks. The dip angle of 60° is the most unfavorable angle for sample failure. The damage accumulation process of the specimens also has obvious stage characteristics. Before the peak stress, the damage accumulation of the specimens is mainly concentrated in the high rate damage stage, and the medium angle (45° and 60°) bedding surfaces accelerate the damage accumulation process of the specimens. The influence of different bedding plane dip angles on the evolution of tensile-shear cracks in soft-hard interbedded rock-like samples is obviously different. The horizontal bedding plane promotes the generation of tensile-shear cracks, and the gradual increase of bedding plane inclination angle promotes the development of tensile-shear cracks in rock-like samples. Under the joint action of bedding plane and rock matrix, with the gradual increase of bedding plane dip angle, the proportion of shear cracks in rock-like samples increases first and then decreases, and the number of shear cracks is at a high level. The research results have certain reference value for the stability evaluation of surrounding rock structure in underground engineering.

Bubble Dynamics Characteristics Near Double-Layer Cylindrical Structures with a Hole Based on PIV Experiments
SUN Yuanxiang, QIN Jiahong, CHEN Yanwu, WANG Cheng
2024, 38(6): 064104.   doi: 10.11858/gywlxb.20240756
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After the outer shell of the double-shell submarine is damaged by the near-field underwater explosion shock wave, the subsequent bubble pulsation and jet load will continue to cause serious damage to the inner shell of the submarine. Therefore, it is of great significance to study the characteristics of bubble pulsation and bubble load near the hole. Based on the double-shell submarine structure damaged by the shock wave, a double-layer cylindrical structure model with a prefabricated circular hole is made. Using an electric spark device as the bubble generator, the interaction experiments between bubbles and double-layer cylindrical structure with a hole under different explosion distance parameters (the ratio of explosion distance to the maximum diameter of bubbles) and different hole parameters (the ratio of hole diameter to the maximum diameter of bubbles) are carried out. A high-speed camera is used to capture the bubble pulsation and jet formation process near the double-layer cylindrical structure. The particle image velocimetry technology is used to test the velocity of the explosion flow field to obtain the jet velocity after the bubble collapse. At the same time, a pressure sensor is used to measure the pressure load on the inner cylindrical shell wall. The experimental results show that the detonation distance parameters determine the form of pressure load on the inner wall, whether effective jet is generated after the bubble collapse, and the jet velocity. When the detonation distance parameters are within a certain range, the hole parameters will affect the bubble pulsation and the direction of the water jet generated after the bubble collapse.

Micro-Morphology and Mechanical Properties of Mg/Al Composites under Vacuum Explosion Welding
LI Xuejiao, SUN Biao, ZHANG Wenzhe, LIU Xiao, QIAN Jingye, HAN Ying
2024, 38(6): 064105.   doi: 10.11858/gywlxb.20240793
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Oxides are prone to occur in welded joints by using of conventional welding methods due to high specific oxidation activity of magnesium and aluminum alloys, which leads to a decrease in the bonding performance of the composite plates. In order to improve the bonding strength of Mg-Al composite plates, Mg-AZ31B/Al-6061 composite plates were manufactured by vacuum explosive welding method, and compared with fabricating the same composite plates in air environment. The microstructure, elements distribution and mechanical properties of the interface were analyzed by optical microscope, scanning electron microscope, energy spectrometer and universal testing machine. The results show that the interfacial morphology of composites welded in vacuum environment is largely different from that in air environment due to the difference of gas shock pressure. The vacuum environment effectively inhibited the oxidation of magnesium and aluminum, and no metal oxides were detected in the melting zone. In addition, it was observed that the shear strength and tensile strength of the samples increased significantly under vacuum explosive welding. Therefore, vacuum explosive welding plays an important role in improving the performance of Mg/Al composite plates, and can be used as an high-performance metal welding method.

Deformation Mode and Energy Absorption of Modularized Cellular Structures
HUANG Qiaoqiao, DENG Qingtian, LI Xinbo, CHEN Li
2024, 38(6): 064106.   doi: 10.11858/gywlxb.20240737
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Compared with the traditional integrated structures, modularized cellular structures can meet the assembly requirements more flexibly. The deformation modes and energy absorption were studied to provide new ideas for the application of cellular structures in engineering, the regular hexagon with positive Poisson’s ratio effect and the re-entrant hexagon with negative Poisson’s ratio effect were selected as the infill units of the modularized cellular structures in this paper, and eight kinds of structures were designed for quasi-static compression experiments. The experimental results were in good agreement with the simulation results. The cellular structures with different infill approaches had different deformation modes under the compression experiments, in which the regular hexagon infill units showed obvious shear failure bands, and the alternate infill approaches can maintain the original units shape. The peak force of the two-layer infill cellular structures were greater than the three-layer infill structures, and the specific absorption energy were greater than the corresponding three-layer infill structures. The total absorption energy, average compression force and specific absorption energy of the hexagon infill structures were always the smallest among the four infill approaches, while the total absorption energy and average compression force of the re-entrant hexagon infill structures were always the largest and the specific absorption energy was kept at a stable and high level.

Study on the Behavior of Blasting Crack Propagation under Different Crack Widths
JI Zhe, YUE Wenhao, SU Hong, GONG Yue, YAN Zhengtuan, LIU Buqing, CHEN Guodong, HAN Yujian
2024, 38(6): 064107.   doi: 10.11858/gywlxb.20240733
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To study the influence of slit width on the dynamic propagation behavior of blast cracks, the digital laser dynamic caustic line experimental system and fractal theory were used to study the propagation laws of blast cracks at six different crack widths. The results show that the length of burst cracks in the cut direction is greater than that in the non-cut direction. With the increase of the slit width, the propagation length of burst crack increases first and then decreases. When the slit width increases to 0.4 mm, the main crack propagation length is the largest, and when the slit width continues to increase, the main crack propagation length decreases. When the slit width is 0.2 and 0.4 mm, the fractal dimension is larger than that of other slit widths, the expansion length of the main crack is longer than that of other widths, and the directional fracture effect of the specimen is better. With the increase of the slit width, the stress intensity factor and velocity peak value of the main crack propagation of the slot shows a trend of first decreasing rapidly, then increasing to the secondary peak, and finally oscillating and decreasing. When the crack width is 0.2 and 0.4 mm, the peak value of the stress intensity factor and the expansion velocity of the main crack are larger than those of other crack widths. The research results provide a certain basis for the selection of slit parameters in actual blasting engineering.

Dynamic Response of Nacre-Like Voronoi Brick and Mortar Structure under Explosive Load
CHEN Xinkang, LI Zhiyang, LEI Jianyin, LIU Zhifang
2024, 38(6): 064108.   doi: 10.11858/gywlxb.20240772
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Inspired by the brick and mortar structure of multi-scale and multi-hierarchy, a nacre-like Voronoi brick and mortar structure was created. Afterwards, the dynamic response of nacre-like Voronoi brick and mortar structure under explosive load was explored by combining 3D printing, explosion experiments, and numerical simulations. The influence of the Voronoi unit cell size and the thickness of the intralaminar soft material on the damage mode as well as the energy absorption of the structure was analyzed. Under the spherical emulsion explosive charge of 40 g, the radial cracks appeared on the front face of the nacre-like Voronoi brick and mortar structure and then spread around, while small pieces of fragments fell off the back panel. A finite element model was built and showed good agreement with the experimental results. The damage modes of nacre-like Voronoi brick and mortar structures under different explosive charges include plastic deformation, cracks occurred on the front and back face, small pieces of material falling off, damage of whole structure accompanied with shear failure at the gripper end. The horizontal normal stress of the stiff material is much larger than the vertical normal stress. Meanwhile, the shear strain in the interlaminar soft material is much larger than that in the intralaminar soft material. The specific energy absorption is 1.8−2.3 times larger in the interlaminar soft material than that in the stiff material. With the increase of the Voronoi unit cell size, the specific energy absorption of the interlaminar soft material increases by 45.6%. As the thickness of the intralaminar soft material increases, the specific energy absorption of the intralaminar soft material increases by 31.1%. This study may provide some definite reference for the design of biologically inspired structures.

Numerical Simulation Study on Macro-Microscopic Damage of PBX Charge during Penetration of Double-Layer Targets
ZHANG Xiaowei, ZHAO Heming, ZHENG Xiaobo, ZHANG Qiao, WANG Zhijun, XIAO Youcai
2024, 38(6): 064201.   doi: 10.11858/gywlxb.20240795
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To study the charge damage evolution process when a high-velocity warhead penetrated a double-layer target, a numerical simulation study was conducted using a cohesive zone model to investigate the penetration of double-layer target. The cohesive zone model was utilized to calculate the occurrence and evolution of PBX damage, as well as to analyze the relationship between the penetration velocity and damage evolution. The quantification of damage was conducted by means of the damage ratio. Furthermore, a micro-damage finite element model for PBX was established to examine the microscopic damage mechanisms during penetration into a double-layer target. The results show that when the projectile penetrates the target plate vertically, the extent of damage of the charge increases with the increase of penetration velocity. From a microscopic perspective, it was observed that cyclic tensile and compressive loads induced the formation of vertical cracks perpendicular to the loading direction. The primary mechanism of damage in PBX charge penetration into double-layer target is interface debonding. Additionally, the microcracks destabilize, propagate, and converge into a continuous main crack.

Influence of Crack Angles on the Mechanical Behavior and Energy Evolution of Granite-Concrete under Uniaxial Compression
LI Qingwen, LI Hanjing, ZHONG Yuqi, LI Ling, CAI Shiting, LIU Yiwei
2024, 38(6): 064202.   doi: 10.11858/gywlxb.20240803
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To investigate the influence of the crack angle on the strength and energy evolution of granite-concrete composite specimens under uniaxial compression, a numerical simulation study was conducted using the two-dimensional particle flow code (PFC2D) based on the micro-parameters calibrated through laboratory tests. The research results indicate that the strength and deformation characteristics of granite-concrete are affected by crack angles, and their strength and deformation parameters gradually increase with the increase of crack angle. During the uniaxial compression process, the internal energy of the specimens transforms into macroscopic crack propagation, and the final failure modes are mainly tensile fractures and shear fractures. The total energy and dissipated energy of the composite specimens increase with the increase of crack angle, and the total strain energy is more than the dissipated energy when the specimens are damaged. Based on the calculation of dissipated energy, a damage constitutive equation was constructed, indicating that when the damage factor reaches 0.8, the specimen is already close to its limit state, resulting in significant energy consumption and a decrease in the strength of the composite specimen.

Blast Resistance and Prediction of Bi-Directional Corrugated Sandwich Tubes under Internal Blast Loading
TANG Bo, LI Zihao, LIU Zhifang, LI Shiqiang
2024, 38(6): 064203.   doi: 10.11858/gywlxb.20240782
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A bi-directional corrugated sandwich tube structure was proposed, inspired by the front jaw of peacock mantis shrimp. The dynamic responses and energy absorption characteristics of bi-directional corrugated sandwich tubes under inner blast loading were investigated numerically and experimentally. It was found that three typical deformation modes including localized plastic deformation, elliptical plastic large deformation and laceration. The numerical results of the mid-point deflection of the outer tube and the final deformation mode of the structure agree well with the experimental results. Subsequently, the effects of the number of corrugation of the bi-directional corrugated core tube, the inner and outer tube wall thicknesses and TNT dose on its dynamic response and energy absorption characteristics were investigated thoroughly. The results show that the energy absorption ratio of the structure increases first, and then decreases with the increase of the number of corrugation. Increasing the inner tube wall thickness and decreasing the outer tube wall thickness can improve the shock resistance performance. Compared with the inner tube wall thickness of 1.5 mm and an outer tube wall thickness of 2.5 mm, the structure with an inner tube wall thickness of 2.5 mm and an outer tube wall thickness of 1.5 mm can reduce the maximum mid-point deflection (MD) of the outer tube by 67.6% and reduce the mass by 6.0%. As the TNT dose increases, the percentage of energy absorbed by the inner tube decreases gradually, while the percentage of energy absorbed by the core and outer tube increases. Finally, the specific energy absorption (SEA) of the structure and MD of the outer tube were predicted using BP (back propagation) neural network model, PSO-BP (particle swarm optimization-back propagation) neural network model, and RSM (response surface methodology) model to optimize the proposed structure.

Force-Thermal Coupling Response of Sapphire under Impact Loading Based on Molecular Dynamics Simulation
ZHOU Mengqian, ZHAN Jinhui, HE Wen, CAO Xiuxia, ZHANG Wei, LIU Xiaoxing
2024, 38(6): 064204.   doi: 10.11858/gywlxb.20240749
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Sapphire is often chosen as the observation window in shock wave experiments due to its excellent strength, hardness and optical transparency. A deep understanding of the mechanical and thermodynamic response mechanisms of sapphire under impact loading and the causes of internal damage is crucial for accurately evaluating its performance and stability. In this work, molecular dynamics simulations were performed to explore the mechanical and thermal response of a sapphire single crystal under shock loading along the C-plane. The results indicate that the activated slip system after the impact loading is the rhombic plane slip based on the R-plane {$0 \overline 1 12 $}. When the impact velocity is in the range of 1−3 km/s, no slip occurs; when the impact velocity reaches 4 km/s, slip occurs. When the impact velocity reaches to the range of 5−6 km/s, the sample shows inhomogeneous deformation, mainly composed of irregular stripes. Such results suggest that the activation of the slip system in sapphire depends not only on its lattice structure, but also on the partial shear stress (which needs to reach a critical value). The analysis of the temperature field indicates that there is an intrinsic relation between the local slip and temperature increase, i.e., the formation of intense shear localization is accompanied by the higher temperature.

Preparation and Quasi-Isentropic Loading Characteristics of Ti-Pt Periodically Modulated Gradient Material
JIANG Yuda, ZHANG Ruizhi, WU Dun, CHEN Han, GAO Weilong, HUANG Zihao, ZHOU Yiheng, ZHANG Jian, HU Jianbo, LUO Guoqiang
2024, 38(6): 064205.   doi: 10.11858/gywlxb.20240816
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The quasi-isentropic loading technique based on wave impedance gradient materials is a crucial method for understanding the dynamic response characteristics of materials, which is essential for enhancing material service performance. In this study, Ti-Pt periodically modulated gradient materials were successfully prepared using electron beam evaporation deposition technology. By adjusting the thickness of the two components (Ti and Pt single layers) within the periodic layers, a macroscopic gradient in wave impedance was achieved. The total thickness error between the measured gradient material and the theoretical design was only 1.67%, with an average hardness and elastic modulus of 2.8 and 99.8 GPa, respectively. The interfaces between the internal layers of the material were clear, and no metal alloy phases were detected in the phase analysis. The Ti-Pt periodically modulated gradient material was loaded onto a 5 μm-thickness Al target by a one-stage light gas gun, generating a shock-quasi-isentropic loading waveform within the Al target. Numerical simulation results showed good agreement in the rising trend with the experimental curve. For the 5 μm-thickness Al target, the particle velocity, stress, and strain rate curves exhibit significant fluctuations in the quasi-isentropic stage, with the strain rate curve oscillating continuously between positive and negative values with large amplitudes. Stress contour maps indicate that the loading process of the periodically modulated gradient material involved the chasing, superposition, and integration of multiple wave systems. Simulation shows that when the target thickness is 60 μm, the wave systems complete integration and change into continuous compression wave loading. Based on the simulation result, light gas gun loading experiment for the Al target with a thickness of 60 μm were conducted. The particle velocity and stress curves in the quasi-isentropic stage change into smooth loading waveforms, and the strain rate curve remains overall positive, achieving a good quasi-isentropic loading. This indicates that the periodically modulated gradient material and target thickness need to be designed to match each other. The results of this study provide a guidance for the application of novel periodically modulated gradient structures.

High Pressure Applications
Protective Properties of Metal/CFRP Composite Laminates Subjected to Underwater Contact Explosion
ZHAO Yuxi, YUAN Haotian, WANG Xumin, ZHANG Zhifan
2024, 38(6): 065101.   doi: 10.11858/gywlxb.20240801
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Carbon fiber-reinforced polymer (CFRP) with excellent blast-resistant performances is gradually applied in the anti-shock design of warships. In order to investigate the protective performance of metal/CFRP composite laminates subjected to underwater contact explosion, a fluid-structure coupling numerical model was established based on arbitrary Lagrangian-Eulerian (ALE) method. The deformation and energy absorption characteristics of laminates were analyzed, and the effect of layup types on the blast-resistant performance was compared. The results show that steel-CFRP-steel structure had better blast-resistant performance. On the basis of this structure, the optimal thickness ratio was given as 1.1∶4.0∶1.1.

Influence of Damping Materials on Blasting Vibration of Cylindrical Pool
CHU Yakun, LI Pingfeng, LIANG Hao, LI Hongwei, LIU Wei, ZHANG Liguo, HUANG Xinxu, WU Yanmeng
2024, 38(6): 065102.   doi: 10.11858/gywlxb.20240780
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In the application research of underwater explosion theory and technology, an explosion tank is a very important basic experimental device. The research on the blasting vibration effect and vibration damping of the explosion tank is of guiding significance for the vibration control and the selection of vibration damping materials during the blasting of the cylindrical water tank. In order to explore the impact of explosive vibration caused by the internal charge explosion on the surrounding ground of the cylindrical pool, and to seek effective vibration reduction methods, two kinds of vibration reduction materials, construction gravel and SD-type rubber vibration reduction pad, were selected, and explosion tests were carried out in a small explosive pool under three modes, single charge without vibration reduction, with SD-type rubber vibration reduction pad and with gravel vibration reduction. The collected blasting vibration signals were analyzed by peak particle velocity, EEMD-HHT (ensemble empirical mode decomposition-Hilbert-Huang transform) processing and wavelet packet analysis. The results showed that the vibration signals include the blasting vibration caused by the explosion shock wave and the ground vibration caused by the pool jumping, and the the ground vibration caused by the pool jumping can be effectively identified by Hilbert instantaneous energy analysis. Compared to the single charge without vibration reduction, the vibration velocity and vibration energy under the gravel layer modes are reduced by 53.0% and 43.1%, the vibration velocity and vibration energy for SD-type rubber cushion modes are reduced by 64.9% and 57.4%. The frequency of blasting vibration signal for the three vibration reduction modes is mainly distributed in the range of 10–80 Hz. The energy proportions for the frequency range of 10–40 Hz under the three operating modes are 79%, 69% and 66%, respectively, and the energy proportions for the frequency range of 40–80 Hz are 11%, 29% and 31%, respectively. The gravel and SD-type rubber have the effect of absorbing energy and reducing low-frequency components, and increasing high-frequency components, which can effectively reduce the peak vibration velocity of nearby measurement points. Compared to the effect of the two kinds of vibration absorbing materials, the construction gravel results more uniform energy distribution of the vibration signal frequency band than that of the SD-type rubber.

Study on the Safety Characteristics of Flat Plate Compression of Sodium-Ion Batteries
MA Yuzhe, YANG Jun, CAO Zeyang, QIAO Zhijun, RUAN Dianbo
2024, 38(6): 065301.   doi: 10.11858/gywlxb.20240750
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Sodium-ion batteries (SIBs) have become one of the mainstream research objects of electric vehicle energy storage system due to their advantages of high safety performance and low cost. In the use of electric vehicles, thermal runaway may occur when the battery pack is subjected to compression loading, so it is crucial to study the collision safety characteristics and thermal runaway behaviors of SIBs for their development. In order to reveal the flat plate compression safety characteristics of SIBs, this work focused on 18650-type SIB with a positive electrode of NaNi1/3Fe1/3Mn1/3O2 and a negative electrode of hard carbon. A test platform for the flat plate compression safety characteristics of the batteries was established to investigate the force-electric-thermal response during the battery compression, the state of charge (SOC) range and the critical speed range for thermal runaway of SIBs were explored, the internal short-circuit process was analyzed, and the secondary usage limit of damaged batteries was determined. The results indicate that thermal runaway occurs at charge states of 80% and 90% for cylindrical SIBs, a critical speed for thermal runaway is between 14 mm/min and 15 mm/min, and the battery compression process conforms to a standard “4-stage” process. The damaged cylindrical SIBs under compression have a secondary usage safety limit.

Experimental Study of the Effect of Shear Stress on Phase Transition in c-Axis CdS Single Crystal under Dynamic Loading
TANG Zhi-Ping, Gupta Y M
1989, 3(4): 290-297 .   doi: 10.11858/gywlxb.1989.04.005
[Abstract](13635) [PDF 8643KB](2227)
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For a long time, the problem whether shear stress affects the phase transition initial pressure is not well solved. Duvall and Graham suggested that cadmium sulfide (CdS) crystal could be used to study the effect of shear stress on the initial pressure of phase transition in c-axis CdS single crystal specimens under high velocity impact systematically. The axial stress of initial phase transition measured is T=(3.250.1) GPa, corresponding to a mean pressure pT=(2.290.07) GPa, which agrees the value 2.3 GPa of static results quite well within the experimental error. The shear stress in this case, T=0.72 GPa, is as high as 31.5% of the mean pressure. This result shows that the mechanism of phase transition may be assumed only to relate to a critical mean pressure or critical thermodynamic state, and the effect of shear stress can be ignored.
Flattening of Cylindrical Shells under External Uniform Pressure at Creep
Shesterikov S A, Lokochtchenko A M
1992, 6(4): 247-253 .   doi: 10.11858/gywlxb.1992.04.002
[Abstract](9557) [PDF 2836KB](1977)
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Experimental studies of the deformation of cylindrical shells under creep to fracture conditions are described in this paper. Analyses of three series of test shells are given and experimental and theoretical results are compared with each other.
The Generation of 90 GPa Quasi-Hydrostatic Pressures and the Measurements of Pressure Distribution
LIU Zhen-Xian, CUI Qi-Liang, ZOU Guang-Tian
1989, 3(4): 284-289 .   doi: 10.11858/gywlxb.1989.04.004
[Abstract](15483) [PDF 6073KB](2640)
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Quasi-hydrostatic pressures up to 90 GPa were obtained at room temperature in the diamond cell by using solid argon as pressure medium. The pressure distribution was determined by measuring the special shift of the R1 line of ruby at different positions within the sample chamber. Experimental results showed that the pressure differences (p) between the pressures at each point within the chamber and the mean pressure (p) were very small, ratios of p/p were less than 1.5% when below 80 GPa. The shape of ruby R lines at 90 GPa is similar to that at ambient pressure. Thus, quasi-hydrostatic pressure near 100 GPa can be obtained by using solid argon as pressure medium. Moreover, the red shifts with pressures of the peak positions at 14 938 and 14 431 cm-1 in ruby emission spectra, were also examined. It concluded that the line, 14 938 cm-1, can be adopted in the pressure calibration.
A Study on Calculation of the Linear Thermal Expansion Coefficients of Metals
ZHENG Wei-Tao, DING Tao, ZHONG Feng-Lan, ZHANG Jian-Min, ZHANG Rui-Lin
1994, 8(4): 302-305 .   doi: 10.11858/gywlxb.1994.04.010
[Abstract](16091) [PDF 1350KB](1126)
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Based on the expression of pressure at temperature T and in terms of the universal equation of state Debye model and the thermodynamic relations, a general expression for the calculation of the linear thermal expansion coefficients of metals is obtained. This formula applied to the calculation of Al, Cu, Pb. Calculated results are in good agreement with the experiments.
Development of Large Volume-High Static Pressure Techniques Based on the Hinge-Type Cubic Presses
WANG Hai-Kuo, HE Duan-Wei, XU Chao, GUAN Jun-Wei, WANG Wen-Dan, KOU Zi-Li, PENG Fang
2013, 27(5): 633-661.   doi: 10.11858/gywlxb.2013.05.001
[Abstract](14257) [PDF 12118KB](1017)
Abstract:
The large volume press (LVP) becomes more and more popular with the scientific and technological workers in the high pressure area, because it could generate relatively higher pressure, provide better hydrostatic pressure and could be utilized in conjunction with in situ X-ray diffraction, neutron diffraction and ultrasonic measurement. There have been generally two LVP techniques to generate high-pressure: the double-anvil apparatus and the multi-anvil apparatus (MAA). Hinge-type cubic presses, as the main apparatus in china, have been widely used in the fields of both scientific research and diamond industry. However, for a long time past, the maximum pressure using the conventional one-stage anvil system for hinge-type cubic press is about 6 GPa, and the techniques about two-stage apparatus (octahedral press) that could generate pressure exceed 20 GPa is blank in our country. To a certain extent, the backwardness of the LVP technology in china restricts the development of high pressure science and related subjects. In recent years, we designed two kinds of one-stage high pressure apparatus and the two-stage apparatus based on hinge-type cubic-anvil press, the one-stage high pressure apparatus and the two-stage apparatus using cemented carbide as anvils could generate pressures up to about 9 GPa and 20 GPa respectively. This article mainly reviews the mechanics structure, design of cell assembly, pressure and temperature calibration, design and preparation of the sintered diamond anvils and pressure calibration to 35 GPa using sintered diamond as two-stage anvils about the one-stage high pressure apparatus and the two-stage apparatus designed in our laboratory.
Research on Deformation Shape of Deformable Warhead
GONG Bai-Lin, LU Fang-Yun, LI Xiang-Yu
2010, 24(2): 102-106 .   doi: 10.11858/gywlxb.2010.02.004
[Abstract](8408) [PDF 1765KB](341)
Abstract:
Basing on the detonation theory, the structure of the deformable warhead was simplified to be double layer cylindrical shells under the detonation. Plastic hinges were introduced into the loading section of the shell, which contacted with the deforming charge, and the deforming charge was divided into small segments accordingly. Loading and movement of these segments were analyzed. Deforming shape of the cylindrical shell under the loading with equal distribution was bulgy, and the displacement of shell segments was obtained. Deforming charge with different thickness, according to the displacement of the segment, was set up to realize the same displacement of the shell segments on the loading direction. The D-shape was achieved theoretically, and the shape of deforming charge was designed accordingly. Numerical simulation validated the feasibility of the designed plan. The results indicate that the deformable warhead with the new-designed deforming charge can realize the D-shape.
The Failure Strength Parameters of HJC and RHT Concrete Constitutive Models
ZHANG Ruo-Qi, DING Yu-Qing, TANG Wen-Hui, RAN Xian-Wen
2011, 25(1): 15-22 .   doi: 10.11858/gywlxb.2011.01.003
[Abstract](17376) [PDF 689KB](1008)
Abstract:
The analyzed and calculated results indicate that the concrete failure strength will decrease under higher hydrostatic pressure, when the original failure parameters of HJC and RHT models implemented in LS-DYNA and AUTODYN are adopted. A new method is introduced which using the characteristic strength of concrete to confirm the modified failure parameters of HJC and RHT models. The same physical experiment of concrete penetration was simulated using the modified HJC and RHT failure parameters respectively, and the numerical results demonstrated that the RHT model matched the experiments much better. But the numerical results with the HJC modified failure parameters were not enough satisfied, because the third invariant of the deviated stress tensor was not considered in the HJC model.
Recent Progresses in Some Fields of High-Pressure Physics Relevant to Earth Sciences Achieved by Chinese Scientists
LIU Xi, DAI Li-Dong, DENG Li-Wei, FAN Da-Wei, LIU Qiong, NI Huai-Wei, SUN Qiang, WU Xiang, YANG Xiao-Zhi, ZHAI Shuang-Meng, ZHANG Bao-Hua, ZHANG Li, LI He-Ping
2017, 31(6): 657-681.   doi: 10.11858/gywlxb.2017.06.001
[Abstract](11176) [FullText HTML](4759) [PDF 2527KB](4759)
Abstract:

In the last 10 years or so, nearly all major Chinese universities, schools and research institutes with strong Earth science programs showed strong interest in developing a new research branch of High-Pressure Earth Sciences.As a result, many young Chinese scientists with good training from the universities in the west countries were recruited.This directly led to a fast growing period of about 10 years for the Chinese high-pressure mineral physics research field.Here we take the advantage of celebrating the 30th anniversary of launching the Chinese Journal of High Pressure Physics, and present a brief summary of the new accomplishments made by the Chinese scientists in the fields of high-pressure mineral physics relevant to Earth sciences.The research fields include:(1) phase transitions in the lower mantle; (2) high spin-low spin transitions of iron in lower mantle minerals; (3) physical properties of the Earth core; (4) electrical measurements of rocks; (5) electrical measurements of minerals; (6) elasticity of minerals (especially equation of states); (7) high-pressure spectroscopic studies; (8) chemical diffusions in minerals; (9) ultrasonic measurements under high pressure; (10) physical properties of silicate melts; (11) geological fluids.In sum, the last 10 years have seen a rapid development of the Chinese high-pressure mineral physics, with the number of scientific papers increasing enormously and the impact of the scientific findings enhancing significantly.With this good start, the next 10 years will be critical and require all Chinese scientists in the research field to play active roles in their scientific activities, if a higher and advanced level is the goal for the Chinese mineral physics community.

Modification of Tuler-Butcher Model with Damage Influence
JIANG Dong, LI Yong-Chi, GUO Yang
2009, 23(4): 271-276 .   doi: 10.11858/gywlxb.2009.04.006
[Abstract](10835) [PDF 402KB](796)
Abstract:
A modificatin of Tuler-Butcher model including damage influence was presented, which was incorporated into a hydrodynamic one-dimensional finite difference computer code, to simulate the process of spall fracture of 45 steel and Al-Li alloy. The calculated results are in good agreement with experimental data, and shows the correctness of the model.
Experiment and Numerical Simulation of Cylindrical Explosive Isostatic Pressing
CHEN Lang, LU Jian-Ying, ZHANG Ming, HAN Chao, FENG Chang-Gen
2008, 22(2): 113-117 .   doi: 10.11858/gywlxb.2008.02.001
[Abstract](13687) [PDF 1180KB](831)
Abstract:
The experiments of cylindrical explosive isostatic pressing were carried out. The internal temperatures in pressed explosives were measured by thermocouples. A thermal/structural coupled model of the explosive isostatic pressing was set up. The numerical simulations of cylindrical explosive were conducted. The calculated pressures and temperatures in explosives were given. The deformations,pressures and temperatures distribution were analyzed. The calculated results indicated that each surface center of the cylindrical explosive was sunken by isostatic pressing. During the isostatic pressing of cylindrical explosive, the internal temperature of the explosives increases, and the temperature and pressure are not uniform.
Perimeter-Area Relation of Fractal Island
LONG Qi-Wei
1990, 4(4): 259-262 .   doi: 10.11858/gywlxb.1990.04.004
[Abstract](15748) [PDF 1508KB](2362)
Abstract:
The relationship of perimeter with area (P/A relation) of fractal island is discussed. It is shown that Mandelbrot's fractal relation between Koch perimeter and area does not hold in the island with finite self-similar generations. This might be the reason why the fractal dimension measured with P/A relation varied with the length of yardstick in previous work.
Long-Distance Flight Performances of Spherical Fragments
TAN Duo-Wang, WEN Dian-Ying, ZHANG Zhong-Bin, YU Chuan, XIE Pan-Hai
2002, 16(4): 271-275 .   doi: 10.11858/gywlxb.2002.04.006
[Abstract](14295) [PDF 2450KB](888)
Abstract:
Using two-stage light gas gun and laser technique for velocity easurement, we studied the long-distance flight performances of spherical fragments with different materials and different diameters. The flight distance is 60~120 m, and the initial velocity is 1.2~2.2 km/s. The experimental results show that: (1) the velocity attenuation coefficient of spherical fragment is constant, and (2) the air drag coefficient is slightly affected by the initial velocity of spherical fragment, the air drag coefficient is a linear function of initial velocity.
Factors Analysis of Debris Cloud's Shape of Hypervelocity Impact
TANG Mi, BAI Jing-Song, LI Ping, ZHANG Zhan-Ji
2007, 21(4): 425-432 .   doi: 10.11858/gywlxb.2007.04.016
[Abstract](13437) [PDF 1599KB](739)
Abstract:
The numerical simulations of hypervelocity impact of Al-spheres on bumper at normal are carried out using the smoothed particle hydrodynamics (SPH) technique. The simulation results are compared with experimental results, and the simulated hole diameters of bumper and debris cloud are well consistent with experimental results. The effect of impact velocity, bumper thickness, projectile diameter, materials, shape of projectile, interval on produced debris cloud are further analyzed. Regarding the length and diameter as index, orthogonal design method is applied to analyze the primary and secondary relations on the debris cloud's index of the three factors, that is impact velocity, bumper thickness and projectile diameter. The results indicate that bumper thickness is the main influence factor of debris cloud's length while projectile diameter is the main influence factor of debris cloud's diameter.
Design of the Sample Assembly for Ultrasonic Measurement at High Pressure and 300 K in Six-Side Anvil Cell
WANG Qing-Song, WANG Zhi-Gang, BI Yan
2006, 20(3): 331-336 .   doi: 10.11858/gywlxb.2006.03.019
[Abstract](10941) [PDF 411KB](662)
Abstract:
We introduced briefly the principle of design of sample assembly for ultrasonic measurements at high pressure, and designed a new kind of sample assembly to measure the isothermal compression of Al and Cu at 300 K. Ideal quasi-hydrostatic loading was realized, and high-quality ultrasonic signals were obtained under high pressure. It was indicated that the design of sample assembly was reasonable. We analyzed in brief main uncertainty of ultrasonic measurement in six-side anvil cell at 300 K.
Design and Temperature Calibration for Heater Cell of Split-Sphere High Pressure Apparatus Based on the Hinge-Type Cubic-Anvil Press
CHEN Xiao-Fang, HE Duan-Wei, WANG Fu-Long, ZHANG Jian, LI Yong-Jun, FANG Lei-Ming, LEI Li, KOU Zi-Li
2009, 23(2): 98-104 .   doi: 10.11858/gywlxb.2009.02.004
[Abstract](14878) [PDF 4054KB](850)
Abstract:
A new type of heater cell for the split-sphere high pressure apparatus based on the hinge-type cubic-anvil press was reported. This heating apparatus has the advantages of being simple, low cost, fast temperature rising, good heat insulation, and the temperature signal can be easily extracted. Carbon tube was used as a heating element for side-heating in our experiments. The size of the sample in the cell can reach 3 mm in diameter, and 7 mm in height. The relationship between the heating electric power and cell temperature was calibrated with Pt6%Rh-Pt30%Rt thermocouples under different pressures. The experimental results indicate that the temperature can reach 1 700 ℃ under the oil hydraulic pressure of 40 MPa (cell pressure is about 10 GPa).The temperature can keep stable for more than 2 h under a fixed power.
Detonation Shock Dynamics Calibration of JB-9014 Explosive at Ambient Temperature
TAN Duo-Wang, FANG Qing, ZHANG Guang-Sheng, HE Zhi
2009, 23(3): 161-166 .   doi: 10.11858/gywlxb.2009.03.001
[Abstract](14284) [PDF 794KB](832)
Abstract:
Detonation shock dynamics (DSD) is an approximation to the reactive Euler equations that allows numerically efficient tracking of curved detonation waves. The DSD parameters are the velocity curvature relation and the boundary angle. A computer code was developed to facilitate the calibration of these parameters for JB-9014 insensitive high explosive using the generalized optics model of DSD. Calibration data were obtained from measurements of the detonation velocities and fronts in JB-9014 rate sticks at ambient temperature, with diameters of 10~30 mm. The steady state detonation velocities and fronts predicted by these DSD parameters are in very good agreement with experiment.
Shock Wave Physics: The Coming Challenges and Exciting Opportunities in the New Century-Introduction of the 12th International Conference of Shock Compression of Condensed Matter (SCCM-2001)
GONG Zi-Zheng
2002, 16(2): 152-160 .   doi: 10.11858/gywlxb.2002.02.012
[Abstract](14250) [PDF 500KB](886)
Abstract:
The 12th Biennial International Conference of the APS Topical Group on Shock Compression of Condensed Matter (SCCM-2001) was introduced. Papers presented in SCCM-2001 were surveyed and the recent progresses on shock compression of condensed matter were retrospected. The basic paradigms and the great achievements of the physics and mechanics of condensed matter at high dynamic pressure and stress were surveyed and revaluated. The coming challenges and exciting opportunities of shock wave physics in the 21 century were prospected.
Application Research on JWL Equation of State of Detonation Products
ZHAO Zheng, TAO Gang, DU Chang-Xing
2009, 23(4): 277-282 .   doi: 10.11858/gywlxb.2009.04.007
[Abstract](15648) [PDF 365KB](913)
Abstract:
By investigating the JWL equation of state of detonation products of condensed explosive, we present a method to determine JWL parameters by fitting. This approach does not require cylinder test and is more economical, secure, convenient and accurate than existing methods. Using this method, four kinds of common explosive, e.g., TNT, C-4, PETN and HMX have been studied. By comparing to the p-V curve of JWL equation of state given by cylinder test, we showed that the fitting has a high precision and meets the need of explosion mechanics application.
The Constitutive Relationship between High Pressure-High Strain Rate and Low Pressure-High Strain Rate Experiment
CHEN Da-Nian, LIU Guo-Qing, YU Yu-Ying, WANG Huan-Ran, XIE Shu-Gang
2005, 19(3): 193-200 .   doi: 10.11858/gywlxb.2005.03.001
[Abstract](10814) [PDF 416KB](801)
Abstract:
It is indicated that the constitutive equations at high strain rates proposed by Johnson-Cook(J-C), Zerilli-Armstrong (Z-A) and Bodner-Parton (B-P) collapse the data of flow stress in compression, tension, torsion, and shear into simple curve with the scalar quatities 'effective' stress and 'effective' strain, however, the collapsed data of flow stress did not include the data in the planar shock wave tests. The SCG constitutive equation proposed by Steinberg et al for the planar shock wave tests is discussed, which describes the coupled high pressure and high strain rate effects on the plastic deformation of materials. Basing on the recent experiments at elevated temperatures and high strain rates and the shear strength measurements during shock loading, the flow stress for tungsten at high pressure and high strain rates is estimated with J-C and SCG constitutive equations, respectively. It is concluded that the J-C, Z-A and B-P constitutive equations may not be appropriate to describe the plastic behavior of materials at high pressure and high strain rates, comparing with SCG constitutive equation. It is emphasized that the physical background of the constitutive equation at high pressure and high strain rates is different from that at low pressure and high strain rates.
Experimental Study on the Damage Effect of Compound Reactive Fragment Penetrating Diesel Oil Tank
XIE Chang-You, JIANG Jian-Wei, SHUAI Jun-Feng, MEN Jian-Bing, WANG Shu-You
2009, 23(6): 447-452 .   doi: 10.11858/gywlxb.2009.06.008
[Abstract](12746) [PDF 5649KB](930)
Abstract:
Two new kinds of compound reactive fragments were designed and prepared, and the penetration tests of the compound reactive fragments against oil tank with diesel oil were performed. The compound reactive fragment is composed of shell, bare reactive fragment and coping. Bare reactive fragments prepared by high-temperature sintering in a vacuum container have two kinds of formulations, one is mixed aluminum powder with PTFE, another is mixed titanium powder with PTFE. Fragments were fired using 12.7 mm ballistic gun, and the penetration process against oil tank were recorded by high-speed camera. The experimental results show that two kinds of compound reactive fragment can penetrate through 6 mm thick oil tank and have obvious ignition effects. Comparing with inert fragments, compound reactive fragments have better capability of penetration and ignition.

Founded in 1987,    bimonthly

Hosted by:Topical Communitte of High Pressure,
Chinese Physical Society

Sponsored by:Institute of Fluid Physics,CAEP

Editor-in-Chief:ZOU Guangtian