Metal Liner Research Articles

Dynamical Penetration Simulation of Solid Target under Shaped Charge Liner

A finite element model of rock mass under linear conical shaped charge liner including explosive, metal liner, air and rock mass is built. The ALE algorithm is applied to simulate the penetration characteristic of rock mass and analyze the influencing factors such as the cone angle, the wall thickness of metal liner, and the standoff distance. Fluid-structure coupling condition is used between metal liner and air as well as between air and rock mass. The present results show that LS-DYNA can be well used to simulate the progress of jet formation and rock penetration with the transmission and focusing of shock stress wave. The different cone angles, wall thicknesses of the metal liner, and the standoff distances will influence the penetration effect.

Long term performance of metal seals for transport and storage casks

AbstractDual purpose casks for the transportation and storage of spent nuclear fuel and other radioactive materials require very high leak tightness of lid closure systems under accident conditions as well as in the long term to prevent activity release. For that purpose metal seals of specific types with an inner helical spring and outer metal liners are widely used and have shown their excellent performance if certain quality assurance requirements for fabrication and assembling are satisfied. Well defined surface roughness, clean and dry inert conditions are therefore essential. No seal failure in a loaded cask happened under these conditions until today. Nevertheless, the considered and licensed operation period is limited and all safety assessments have been performed and approved for this period of time which is 40 years in Germany so far. However, in the meantime longer storage periods might be necessary for the future and therefore additional material data will be required. BAM is involved in the ...

Nanocomposite glide surfaces for FRP hydraulic cylinders – Evaluation and test

The use of continuous fibre-reinforced plastics (FRP) can significantly reduce the mass of hydraulic cylinders, such that light-weight actuators are becoming increasingly common especially in mobile applications. Currently, metallic inner liners are used as piston glide surfaces, which are commonly subject to failure-critical stresses due to the different mechanical behaviour of FRP laminate and metal structure. Adapted polymeric nanocomposites offer great potential to counteract these deficits, based on their good wear characteristics and chemical resistance as well as their high fracture strain and layer adhesion strength appropriate for the laminate deformation. Given this background, theoretical and experimental studies are being carried out on a nanoparticle-reinforced epoxy gelcoat, which has been adapted for load and for efficient manufacturing, as a piston glide surface layer under combined tribological, mechanical and media load. To evaluate the theoretical projection of the mechanical and hygrothermal load on the nanocomposite layer, the stresses and deformations are calculated using multi-layer composite theory for thick-walled anisotropic cylinder shells, and are then compared with experimental data.

Characterization of Fire Suppression of an Idealized Commodity Using Uniform Water Fluxes

An experimental study was conducted to investigate fire suppression behaviors of an idealized commodity using uniform water fluxes. The objectives of this work are to better understand the physics of sprinkler suppression and to provide validation data for numerical fire modeling. The commodities used in the experiments consisted of corrugated cardboard boxes with a metal liner inside. The cardboard boxes were supported by steel beams to maintain the rack storage geometry similar to the standard commodity where wood pallets supported the cardboard boxes. The uniform water fluxes were generated by a water application apparatus (WAA), and adjusted to achieve uncontrolled and controlled fire scenarios. All fire tests were carried out in rack storage configurations with controlled fuel moisture content to minimize its impact on fire growth. The key measurements included heat release rate (HRR), fuel surface temperature, incident heat flux to the fuel surface and water flow rate transported to the bottom of the fuel array. The test results show that the measured heat release rates under various experimental conditions are very repeatable, and thus are suitable for model validation purposes. The fire test outcomes, i.e., controlled vs. uncontrolled fires, are directly correlated with the amount of water collected during the suppression stage, indicating that the sprinkler suppression mechanism is dominated by water transport in the fuel array. The idealized commodity exhibited fire growth rates similar to the standard commodity, largely due to the impact of the beam support on the fire spread. Furthermore, the critical delivered flux (CDF) that can prevent fire growth is very close between the idealized and the standard commodity. The similarities in fire growth and suppression characteristics suggest that it may be feasible to use the idealized commodity in numerical simulation of fire suppression, as an alternative to the more complex real fuel.

Numerical Simulation of Sprinkler Suppression of Rack Storage Fires

Fire suppression tests with ceiling sprinkler protection in a rack storage fuel configuration are simulated using a Computational Fluid Dynamics tool. The fuel is arranged in a double-row, six pallet-load wide and three-tier high (2×6×3) rack storage array. Each pallet load consists of three nested double-wall corrugated cardboard boxes surrounding a metal liner. Two types of ceiling sprinklers are used in this study: a pendent quick response sprinkler designated as K14, and an upright standard response sprinkler designated as K11.2. The tests are simulated using FireFOAM, which couples necessary sub-models for fire growth, sprinkler response, and fire suppression. Numerical results are compared with experiments for both free burn tests under a 20-MW calorimeter and sprinkler suppression tests under a 7.6 m high ceiling. For the free burn case, the model results show good quantitative agreement of heat release rates in all three phases, from ignition to fire growth and steady burning. For the suppression cases, the model reproduces the suppression effectiveness of the two sprinkler protection designs: K14 sprinklers suppress the fire rapidly with only one sprinkler activation, while with K11.2 sprinklers, both in the tests and simulation, the fire spreads to the pallets on the end of the fuel array with multiple sprinkler activations. The modeled sprinkler activation times are within the estimated experimental uncertainty following three repeat tests. Quantitative results characterizing sprinkler suppression performance obtained from the simulations, such as the actual delivered density (ADD) and water evaporation rate, are also reported.

Application of surrogate based particle swarm optimization to the reliability-based robust design of composite pressure vessels

A surrogate based particle swarm optimization (SBPSO) algorithm which combines the surrogate modeling technique and particle swarm optimization is applied to the reliability-based robust design (RBRD) of composite pressure vessels. The algorithm and efficiency of SBPSO are displayed through numerical examples. A model for filament-wound composite pressure vessels with metallic liner is then studied by netting analysis and its responses are analyzed by using Finite element method (performed by software ANSYS). An optimization problem for maximizing the performance factor is formulated by choosing the winding orientation of the helical plies in the cylindrical portion, the thickness of metal liner and the drop off region size as the design variables. Strength constraints for composite layers and the metal liner are constructed by using Tsai-Wu failure criterion and Mises failure criterion respectively. Numerical examples show that the method proposed can effectively solve the RBRD problem, and the optimal results of the proposed model can satisfy certain reliability requirement and have the robustness to the fluctuation of design variables.

Microsecond ramp compression of a metallic liner driven by a 5 MA current on the SPHINX machine using a dynamic load current multiplier pulse shaping

SPHINX is a 6 MA, 1-μs Linear Transformer Driver (LTD) operated by the CEA Gramat (France) and primarily used for imploding Z-pinch loads for radiation effects studies. Among the options that are currently being evaluated to improve the generator performances are an upgrade to a 20 MA, 1-μs LTD machine and various power amplification schemes, including a compact Dynamic Load Current Multiplier (DLCM). A method for performing magnetic ramp compression experiments, without modifying the generator operation scheme, was developed using the DLCM to shape the initial current pulse in order to obtain the desired load current profile. In this paper, we discuss the overall configuration that was selected for these experiments, including the choice of a coaxial cylindrical geometry for the load and its return current electrode. We present both 3-D Magneto-hydrodynamic and 1D Lagrangian hydrodynamic simulations which helped guide the design of the experimental configuration. Initial results obtained over a set of experiments on an aluminium cylindrical liner, ramp-compressed to a peak pressure of 23 GPa, are presented and analyzed. Details of the electrical and laser Doppler interferometer setups used to monitor and diagnose the ramp compression experiments are provided. In particular, the configuration used to field both homodyne and heterodyne velocimetry diagnostics in the reduced access available within the liner's interior is described. Current profiles measured at various critical locations across the system, particularly the load current, enabled a comprehensive tracking of the current circulation and demonstrate adequate pulse shaping by the DLCM. The liner inner free surface velocity measurements obtained from the heterodyne velocimeter agree with the hydrocode results obtained using the measured load current as the input. An extensive hydrodynamic analysis is carried out to examine information such as pressure and particle velocity history profiles or magnetic diffusion across the liner. The potential of the technique in terms of applications and achievable ramp pressure levels lies in the prospects for improving the DLCM efficiency through the use of a closing switch (currently under development), reducing the load dimensions and optimizing the diagnostics.

Metal liner-driven quasi-isentropic compression of deuterium

Properties of degenerate hydrogen and deuterium (D) at pressures of the order of terapascals are of key interest to Planetary Science and Inertial Confinement Fusion. In order to recreate these conditions in the laboratory, we present a scheme, where a metal liner drives a cylindrically convergent quasi-isentropic compression in a D fill. We first determined an external pressure history for driving a self-similar implosion of a D shell from a fictitious flow simulation [D. S. Clark and M. Tabak, Nucl. Fusion 47, 1147 (2007)]. Then, it is shown that this D implosion can be recreated inside a beryllium liner by shaping the current pulse. For a peak current of 10.8 MA cold and nearly isochoric D is assembled at around 12 500 kg/m3. Finally, our two-dimensional Gorgon simulations show the robustness of the implosion method to the magneto-Rayleigh-Taylor instability when using a sufficiently thick liner.

Evaluation of Established Cleanup Models in Dynamic Underbalanced Perforating

This article, written by JPT Technology Editor Chris Carpenter, contains highlights of paper SPE 159413, ’Evaluation of Established Perforation-Cleanup Models in Dynamic Underbalanced Perforating,’ by Dennis Haggerty, G.G. Craddock, and Clinton C. Quattlebaum, SPE, Halliburton, prepared for the 2012 SPE Annual Technical Conference and Exhibition, San Antonio, Texas, USA, 8-10 October. The paper has not been peer reviewed. Dynamic underbalanced (DUB) perforating is a process that creates a negative pressure differential, or underbalance, causing fluid to move toward the wellbore even in an initial overbalanced static condition. A DUB condition can be controlled by understanding and carefully managing the temporal pressure transients by use of multiple methods within the wellbore during and after gun-system detonation. Recently, a series of instrumented perforation experiments demonstrated that existing cleanup models do not accurately predict perforation cleanup when perforating in a DUB condition. Introduction Underbalanced perforating methods have been applied successfully since the 1950s, shooting both wireline and tubing-conveyed perforating guns. As shaped-charge jet-perforator systems became more advanced, using powdered metal liners, performance steadily improved. The art of minimizing the compacted and damaged area surrounding the perforation tunnel, commonly known as the crushed zone (Fig. 1), began shortly afterward. Much of the initial work involved shooting charges into prepared Berea sandstone cores while documenting the effect of a differential pressure toward the wellbore upon perforation efficiencies. As the benefits of an underbalanced pressure differential were observed, extensive testing established criteria for flow volumes and differential pressures required to remove or minimize the crushed zone created during the perforating event. Specifically documented was the role of trapped atmospheric pressure inside a perforating gun surrounding the shaped charge and components, known as free gun volume (FGV), which enabled the formation pressure to act as a differential and expel charge and crushed formation into the gun. As perforating research and field observations continued, a series of widely used and accepted formulas was established to document the magnitude of differential pressure required to ensure cleaned perforation tunnels. This paper reviews the effectiveness of each of these models, originally developed for a static underbalanced condition before perforating, to predict cleaning and removal of the crushed zone in a series of tests with a dynamic pressure differential. The test series uses an advanced perforation-flow laboratory to detonate an 11.1-g deep-penetrating shaped charge. Each charge will perforate a 24-in.-long, 7-in.-diameter Berea sandstone core with 3,950-psi applied pore pressure; 9,950-psi simulated overburden stress; and 4,900-psi wellbore pressure, creating a static 950-psi overbalance. Although the initial static condition will be overbalanced, a DUB condition will be established by wellbore and pore fluids filling the FGV upon detonation.

(Invited) Optimization of WAl2O3Cu(-Te) Material Stack for High-Performance Conductive-Bridging Memory Cells

In this paper, we optimize the thermal stability of WAl2O3Cu and WAl2O3Cu-Te conductive-bridging cells for integration of 1-Transistor/1-Resistor (1T1R) memory elements. Thermal stability up to the back-end-of-line (BEOL) processing temperature of 400°C is ensured by Cu-Te composition tuning and carbon alloying developments, while Cu in-diffusion processes during BEOL processing is limited through the engineering of thin Ti-, Ta-, and TiW-based metallic liners inserted at the Al2O3Cu(-Te) interface. The integrated 1T1R cells are demonstrated to operate in the nanosecond range using moderate voltages. Write endurance of >106 cycles is achieved using 10ns-short pulses while high voltage-disturb robustness is observed at lower voltages, resulting in excellent voltage-time characteristics of the cells. Finally, images of device filaments programmed in low- and high-resistance states are successfully obtained by means of conductive atomic-force-microscopy

Smoothed particle hydrodynamics modeling of linear shaped charge with jet formation and penetration effects

Shaped charge, as a frequently used form of explosive charge for military and industrial applications, can produce powerful metal jet and lead to stronger penetration effects onto targets than normal charges. After the explosion of high explosive (HE) charge, the detonation produced explosive gas can exert tremendous pressure on surrounding metal case and liner with very large deformation and even quick phase-transition. In this paper, the entire process of HE detonation and explosion, explosion-driven metal deformation and jet formation as well as the penetrating effects is modeled using a smoothed particle hydrodynamics (SPH) method. SPH is a Lagrangian, meshfree particle method, and has been widely applied to different areas in engineering and science. A modified scheme for approximating kernel gradient (kernel gradient correction, or KGC) has been used in the SPH simulation to achieve better accuracy and stability. The modified SPH method is first validated with the simulation of a benchmark problem of a TNT slab detonation, which shows accurate pressure profiles. It is then applied to simulating two different computational models of shaped-charge jet with or without charge cases. It is found that for these two models there is no significant discrepancy for the length and velocity of the jet, while the shapes of the jet tip are different. The modified SPH method is also used to investigate the penetrating effects on a steel target plate induced by a linear shaped charge jet. The effectiveness of the SPH model is demonstrated by the good agreement of the computational results with experimental observations and the good energy conservation during the entire process.

Fabrication of metallic liners for composite overwrapped pressure vessels by tube forming

In a previous work the authors introduced an innovative tube forming concept that is capable of shaping commercial tubes into small size, seamless, reservoirs made from a variety of materials and available in many shapes. The aims and objective of this article is to present the role played by finite element modelling and experimentation in scaling-up the original tube forming concept to an industrial manufacturing process capable of fabricating real size metallic liners, at room temperature, for composite overwrapped pressure vessels (COPV's) that are commonly utilized in aerospace applications.A tool comprising unconventional dies with very sharp edges and recyclable metallic mandrels made from a low melting point alloy are comprehensively described with the objective of understanding its combined influence in the deformation mechanics and formability limits of the process. Metallic liners with 120 mm diameter and different storage capacity, made from commercial tubes of aluminium AA6063-T0, are included in the presentation to illustrate the effectiveness and flexibility of the new industrial tube forming process.

Control of metal/oxide electron barriers in CBRAM cells by low work-function liners

The difference in effective work functions (EWF) between metal electrodes in metal–insulator–metal structures used in resistive switching memory cells determines the value of the static built-in voltage. The latter may affect the retention properties because the corresponding electric field remains present even if no external voltage is applied to the cell. Using the spectroscopy of internal photoemission of electrons, we evaluated the possibility to adjust the EWFs of the back (TiNy, y ≈ 1) and ion-injecting electrodes (Cu or CuxTe1−x) at interfaces with the Al2O3 insulator by inserting a thin layer (a liner) of low work function metal (Ta, Ti, Hf). It is found that even a 3-nm thick layer of Ta allows for a reduction of the EWF of copper by ≈1.5 eV. A thicker, ≈6 nm, layer of Ti is required to attain a similarly low EWF while in the case of an Hf liner, scavenging of oxygen from the alumina results in a laterally nonuniform barrier.

The influence of head diameter and wall thickness on deformations of metallic acetabular press-fit cups and UHMWPE liners: a finite element analysis

BackgroundTo increase the range of motion of total hip endoprostheses, prosthetic heads need to be enlarged, which implies that the cup and/or liner thickness must decrease. This may have negative effects on the wear rate, because the acetabular cups and liners could deform during press-fit implantation and hip joint loading. We compared the metal cup and polyethylene liner deformations that occurred when different wall thicknesses were used in order to evaluate the resulting changes in the clearance of the articulating region. MethodsA parametric finite element model utilized three cup and liner wall thicknesses to analyze cup and liner deformations after press-fit implantation into the pelvic bone. The resultant hip joint force during heel strike was applied while the femur was fixed, accounting for physiological muscle forces. The deformation behavior of the liner under joint loading was therefore assessed as a function of the head diameter and the resulting clearance. ResultsPress-fit implantation showed diametral cup deformations of 0.096, 0.034, and 0.014mm for cup wall thicknesses of 3, 5, and 7mm, respectively. The largest deformations (average 0.084±0.003mm) of liners with thicknesses of 4, 6, and 8mm occurred with the smallest cup wall thickness (3mm). The smallest liner deformation (0.011mm) was obtained with largest cup and liner wall thicknesses. Under joint loading, liner deformations in thin-walled acetabular cups (3mm) reduced the initial clearance by about 50%. ConclusionAcetabular press-fit cups with wall thicknesses of ≤5mm should only be used in combination with polyethylene liners >6mm thick in order to minimize the reduction in clearance.

Design, Development and Qualification of High Performance Load Sharing Composite Pressure Vessel for Aircraft Application

Load sharing metal lined composite pressure vessel(COPV) enables significant safety and reliability over those vessels with non-load-sharing metallic or non-metallic liners, The key technical challenge in developing these vessels will be to calculate the optimized liner thickness and liner elastic strain. This paper presents techniques developed at Lanzhou Institute of Physics(LIP) for the design of elastically operating metal liner COPV in terms of NET theory which modified by LIP. Five metal materials are discussed and analytical techniques for determining liner thickness are presented, selection of materials for maximizing performance and minimizing weight is discussed. L490A-COPV development is introduced, performance factor is improved from 23 Km to 29.5Km.

Electromagnetic pulse emission produced by Z pinch implosions

In this paper, we represent the radiation characteristics of electromagnetic pulse generated by Z pinch implosion. Magnetic energy which couples with motions of metallic wire arrays or solid liners driven by Z pinch can radiate away. Theoretical results indicate that the radiation power of electromagnetic pulse is determined by both load current and implosion trace. Experiments are carried on primary test stand facility at Institute of Fluid Physics where a current rising to 7 MA in (10%–90%) 65 ns is used to drive a wire array Z pinch. The measured load current and implosion trace show that the Z pinch can deliver about 1 GW, 10 ns full width, 20–70 MHz central frequency, broadband electromagnetic pulse with an energy conversion efficiency of 10-7. Parameters of electromagnetic pulse are much smaller than those of X-ray with a power of 50 TW and an energy of 0.5 MJ. In the approximation of weak relativistic case, the power of electromagnetic pulse which is proportional to sixth power of load current, dramatically increases with current increasing. Soft X-ray radiation is an important channel for dissipating a considerable fraction of energy provided by facility. The results presented here demonstrate that electromagnetic pulse emission in the case of higher load current can cause significant damage to diagnostic devices. Moreover, intense electromagnetic pulse produced by this method may have many potential applications.

OS0607 衝撃を受けた複合圧力容器の金属ライナ層の変形が容器の健全性に及ぼす影響

A COPV (Composite Overwrapped Pressure Vessel) is consisting of a thin metallic liner wrapped with a fiber composite. The outer side CFRP layers bear the load due to internal pressure, and the inside liner provides a barrier between the fluid and the composite. Because of its high specific strength compared to metal pressure vessel, COPV have been applied to the field of aerospace. If it suffers impact load such as by falling tools, both CFRP and liner cause the impact failure, and a dent remains in liner by metal plastic deformation. Usually, the liner deforms elastically in MEOP (Maximum Expected Operating Pressure), but in the part of liner dent, there is a possibility of plastic deformation by adding the bending moment as well as the load due to internal pressure. If tensile and compressive plastic deformation repeats by pressurizing and depressurizing, the ratchetting plastic deformation occurs and plastic strain is accumulated in liner dent. This study discusses the ratchettig defomation of the COPV liner, and investigates the presence of ratcheting by FEM.

Physical design of the "Ying-Guang 1" device

"Ying-Guang 1" is a multi-bank pulsed power device for investigating the formation, confinement and instability of the high temperature and high density field-reversed configuration (FRC) plasma injector for the magnetized target fusion (MTF). This paper described the physical design of the "Ying-Guang 1" device which will be constructed in 2013 at the Institute of Fluid Physics, CAEP. Theoretical results show that the peak reversed current and magnetic field of this device are 1.5 MA and 4 T respectively with the rise time of 3 μ s. Based on the semi-empirical formula developed by Tuszewski the magnetized plasma of equilibrium density 6.6×1016 cm-3 and temperature (Ti+Te) ～ 300 eV could be achieved on the "Ying-Guang 1" device when the initially filled D2 gas pressure is about 50 mTorr, and the length of the FRC separatrix is 17 cm with a radius of 2 cm. The average ratio of the thermal pressure to magnetic pressure β is about 0.95, and the magnetic field embedded in plasma is 0.5 T. From the adiabatic compression scaling laws and the corresponding ignition conditions, the formated FRC plasma target of the "Ying-Guang 1" device approaches the necessity of the MTF if the radius compression ratio of the solid metal liner were set to 10.

Hydrodynamics Computation of Jet Formation and Penetration for Micro-shaped Charges

Understanding the hydrodynamic mechanisms in millimeter size shaped charges and smaller, is important for defence- related applications but also for material processing, remote sensing and potential biological applications. Our current focus is to perform a high-fidelity computational study to investigate micro-shaped charge jet formation and penetration depth. We seek to develop an understanding of the limits of our current ability to predict the formation and penetration characteristics of micro-shaped charges by simulation. The LLNL's advanced multiphysics hydrodynamics code, ALE3D, is used as the computational framework. Results obtained for a series of multi-material computations using very small charges and cones will be discussed. The typical thickness of the metal liner is 0.0254cm (0.01 in) at a stand-off distance of approximately 2.6 Liner Diameters. A complimentary experiment was performed with a very small shaped charge based on a detonator, to generate a representative realization for a simple baseline computational validation/comparison. Various Equation of State (EOS) models have been invoked including JWL, Mie-Gruneisen and γ-law gas with a programmed burn capability. It was found from the experimental data that the penetration depth corresponds to 3.3 Liner Diameter.

Fabrication of metallic liners for composite overwrapped pressure vessels

This paper presents a new manufacturing process for producing metallic liners for composite overwrapped pressure vessels (COPV’s) that are commonly utilized in spacecraft. The process combines an innovative tube-forming operation, which is capable of shaping commercial tubes into seamless metallic liners in a single stroke of a press, with a sequence of post-forming operations comprising machining, joining by crimping and welding, and gas tightness testing by means of non-destructive examination. The presentation focuses on the manufacturing process as a whole, but tube-forming in particular, and was written with the objective of providing details of the deformation mechanics, formability limits and tooling system of the tube-forming operation. Different types of COPV’s liners with 120 mm diameter are included in the presentation to illustrate the effectiveness and flexibility of the tube-forming operation in meeting the specific requirements of aerospace applications concerning storage capacity and available shapes. The process running under steady-state production conditions is expected to reduce the overall production costs of COPV’s by roughly one third.