Metal Seal Research Articles

Inverse method to estimate anthocyanin degradation kinetic parameters in cherry pomace during non-isothermal heating

Cherry pomace, a by-product of juice production, is rich in health beneficial anthocyanins (ACY). This study aimed to determine ACY retention in 25, 41, and 70% moisture content (MC) pomace at elevated temperatures. Pomace was heated in sealed metal cans at 105 °C and 127 °C in a steam retort up to 125 min. ACY levels were measured by the pH-differential method. A first-order degradation model with an Arrhenius dependence for the rate constant was used for modeling ACY levels. The rate constant and activation energy for the pomace at each moisture level were estimated by two inverse methods. For 70% MC, k115.8°C = 0.0129 min−1 and Ea = 75.7 kJ/mol. MC had no significant effect on the parameter estimates. Sequential estimation showed that the experiment had to be run to ≤25% ACY retention to obtain accurate parameter estimates. The estimation methods presented will be helpful for designing dynamic processes.

Reversible Cryopreservation of Living Cells Using an Electron Microscopy Cryo-Fixation Method.

Rapid cooling of aqueous solutions is a useful approach for two important biological applications: (I) cryopreservation of cells and tissues for long-term storage, and (II) cryofixation for ultrastructural investigations by electron and cryo-electron microscopy. Usually, both approaches are very different in methodology. Here we show that a novel, fast and easy to use cryofixation technique called self-pressurized rapid freezing (SPRF) is–after some adaptations–also a useful and versatile technique for cryopreservation. Sealed metal tubes with high thermal diffusivity containing the samples are plunged into liquid cryogen. Internal pressure builds up reducing ice crystal formation and therefore supporting reversible cryopreservation through vitrification of cells. After rapid rewarming of pressurized samples, viability rates of > 90% can be reached, comparable to best-performing of the established rapid cooling devices tested. In addition, the small SPRF tubes allow for space-saving sample storage and the sealed containers prevent contamination from or into the cryogen during freezing, storage, or thawing.

Experimentally Determined Ti-Al-Cl Phase Diagram at T = 150 to 400

Introduction The titanium aluminum chlorine, Ti-Al-Cl, system encompasses a range of current industrial processes and a number of processes currently under development. The major industries and processes are: TiCl4 production via high temperature chlorination of titanium oxide ore for the pigment industry, Ziegler-Natta catalysts, β-TiCl3(AlCl3)1/3 produced by Al driven reduction of TiCl4(l) for use in polypropylene production [1], Ti metal production via high temperature reduction of TiCl4 using metal reducing agents (Mg, Na, etc.) and Ti-Al alloy production for transport and chemical industries. Despite the importance of these processes, there are no published phase diagrams for the Ti-Al-Cl system and only limited thermodynamic data for TiCl3-AlCl3 and TiCl2-AlCl3 solution phases [2].A number of issues make this system difficult to study. The salts compounds react with H2O, O2 and many organic compounds and they can only be handled in clean glove boxes. The salts are volatile, form complex molecular species that are non-ideal; which make it difficult to identify the molecular species and measure their partial pressures [3,8]. Titanium and aluminium have a range of oxidation states (Ti: 4+, 3+, 2+ and Al: 3+, 2+, 1+), the stability of each oxidation state depend on the local chemical environment and a series of disproportionation reactions allow conversion between ions [3,4]. The unique properties of AlCl3(s) and Al2Cl6(l) result in the formation of a range of complex solution phases with TiCl3 and TiCl2 [2,4]. Many container materials react with these salts and Ti-Alloys at temperatures above 200°C [5]. Finally, it is difficult to prepare metallographic samples containing salt and metal for characterization via scanning electron microscopy (SEM), electron probe microanalysis (EPMA) and X-ray diffraction needed for a phase equilibria study. However, recent work has solved a number of these experimental problems allowing an initial investigation of the phase equilibria in Ti-Al-Cl system. Experimental and Results The experiments consisted of mixing different amounts of high purity TiCl3(s) and AlCl3(s), loading the mixtures into a container, where the “sample” is the salt mixture plus the container. Multiple samples were loaded into wells a metal block that was sealed and a controlled over pressure of static high purity argon was supplied to limit vapour loss. The sealed metal block was loaded into the isothermal zone of a vertical tube furnace for annealing. (All sample preparation, loading and unloading was done inside a clean glove box.) To study salt / metal equilibrium pure-aluminium, pure-titanium and various Ti-Alloy containers were used. To study the equilibrium between the TiCl3-AlCl3 and TiCl2-AlCl3 pseudo binaries an Al2O3 container was used together with a small amount of Al(s).The samples were equilibrated at temperatures between 150 and 400°C for 50 ~ 200hr and quenched. After unloading the samples were mounted in epoxy and prepared for SEM and EPMA. All metallographic sample preparation and carbon coating was done inside a clean glove box. The prepared samples were transferred into the SEM / EPMA without exposure to air. Similarly, XRD sample preparation was performed inside a clean glove box, with powders mounted into a bespoke sample holder and sealed from exposure to air and moisture using Mylar film.This worked focused on determining the solubility range of nominally binary salt phases, TiCl3(s), TiCl2(s) and AlCl3(s) and the stability of ternary salts like TiAlCl5(s) [7] and Ti(AlCl4)2(s,l) [2-4,6] and determining phase compositions in three phase fields between: 1) TiCl3-AlCl3 and TiCl2-AlCl3 and 2) TiCl2-AlCl3 and Ti-Al. Results from initial experiments are reported as a number of isothermal sections between 150 and 400°C. References Brant, P. and E. G. M. Tornqvist, Inorganic Chemistry, 1986, 25(21): 3776-3779. Schafer, H. Angewandte Chemie International Edition, 1976, 15(12): 713-788. Sørlie, M. and H. A. Øye Inorganic Chemistry, 1978, 17(9): 2473-2484. Sørlie, M. and H. A. Øye. Inorganic Chemistry, 1981, 20(5): 1384-1390. Berg, R. W., H. A. Hjuler, et al. Inorganic Chemistry, 1984, 23(5): 557-565. Justnes, A., E. Rytter, et al. Polyhedron, 1982, 1(4): 393-396. Brynestad, J., S. von Winbush, et al. Inorganic and Nuclear Chemistry Letters, 1970, 6(12): 889-893. Hildenbrand, D. L., K. H. Lau, et al. Journal of Physical Chemistry, 1991, 95(8): 3435-3437.

Design and fabrication of a window for the gas Cherenkov detector 3.

The gas Cherenkov detector 3 was designed at Los Alamos National Laboratory for use in inertial confinement fusion experiments at both the Omega Laser Facility and the National Ignition Facility. This instrument uses a low-Z gamma-to-electron convertor plate and high pressure gas to convert MeV gammas into UV/visible Cherenkov photons for fast optical detection. This is a follow-on diagnostic from previous versions, with two notable differences: the pressure of the gas is four times higher, and it allows the use of fluorinated gas, requiring metal seals. These changes force significant changes in the window component, having a unique set of requirements and footprint limitations. The selected solution for this component, a sapphire window brazed into a stainless steel flange housing, is described.

Leakage of Metallic Seals: Role of Plastic Deformations

I study the influence of plastic deformations on the leakage of metallic seals. The solids are assumed to deform elastically as long as the stress is below the penetration hardness of the material, and yield plastically when the local stress reaches the penetration hardness. The metal surfaces are assumed to exhibit self-affine fractal surface roughness. We use the Persson contact mechanics theory and the Bruggeman effective medium theory to estimate the leak rate of the plastically deformed interface.

Criterion for non-interference of solid metal seal pair in double-offset butterfly valve

To avoid leakage of the seal pair is one of the key considerations in valve designs. As to double-offset butterfly valves (DOBVs) with solid metal seal pair, it means that no interference should occur at the seal pair. By constructing a mathematical model for the sealing surface of DOBV, this paper provides a criterion for non-interference for the seal pair in DOBV. Detailed investigations show that the interference area can be influenced by the radial offset, the diameter of valve disc, the sealing thickness, and the cone angle of the sealing surface. The top and the bottom parts of the sealing surface are the areas where interference is least likely to be avoided. The axial offset can also influence the interference areas, resulting in its nonlinear changes. Moreover, the minimum radial offset for entire non-interference of the seal pair of a DOBV changes nonlinearly with the increase of the axial offset or the cone angle. The results presented in this paper may suggest a strategy for parameter optimization of DOBVs.

Protection of historical lead against acetic acid vapour

Abstract Historical lead artefacts (small figurines, appliques, bull (metal seal) can be stored in depository and archives in inconvenient storage conditions. The wooden show-case or paper packagings release volatile organic compound to the air during their degradation. These acids, mainly acetic acid are very corrosive for lead. The thin layer of corrosion products which slows atmospheric corrosion is formed on lead surface in atmospheric condition. In presence of acetic acid vapour the voluminous corrosion products are formed and fall off the surface. These corrosion products do not have any protection ability. The lead could be protected against acid environment by layer of “metal soup” which is formed on surface after immersion in solution of salt of carboxylic acid for 24 hours. The solutions of acids (with vary long of carbon chain) and their salts are examined. Longer carbon chain provides better efficiency convers layer. The disadvantages are low solubility of carboxylic acids in water and bad abrasion resistance of formed layer.

High-performance diamond radiation detectors produced by lift-off method

For stable semiconductor detector operation under harsh environments, an ideal single-crystal diamond without a charge trapping centre is required. For this study, a self-standing single-crystal CVD diamond was fabricated using a lift-off method. The reduction of charge trapping factors such as structural defects, point defects, and nitrogen impurities, was attempted using 0.2% of low-methane concentration growth and using a full metal seal chamber. A high-quality self-standing diamond with strong free-exciton recombination emission was obtained. Charge collection efficiencies were 100.1% for holes and 99.8% for electrons, provided that and . Energy resolutions were 0.38% for both holes and electrons. We produced a high-performance diamond radiation detector using the productive lift-off method.

Mechanical analyses of the waveguide flange coupling for the first confinement system of the ITER electron cyclotron upper launcher

The four electron cyclotron (EC) upper port antennas (or “upper launchers” —UL) will be used to drive current locally inside magnetic islands located at the q=2 (or smaller) rational surfaces in order to stabilize neoclassical tearing modes (NTMs), as well as heat inside of ρ of about 0.4. Each antenna consists of eight beam lines that are designed for the transmission of 1.5 MW of mm-wave power at 170GHz. The First Confinement System (FCS) is formed by the ex-vessel mm-wave waveguide components, for which SIC-1 classification requirements apply.The beam lines in the FCS comprise a Z shaped set of straight corrugated waveguides with a nominal diameter of 50mm connected by miter bends. This system is subjected to imposed displacements coming mainly from the thermal expansion of the vacuum vessel, seismic events and/or plasma disruption events. In absence of suitable SIC-1 waveguide bellows, the FCS waveguides must provide the necessary mechanical functional compliance. This has required the development of a dedicated, flange type coupling system with double metallic seals, capable of resisting the generated external loads while maintaining vacuum tightness and alignment. This paper presents the results of the design, analysis and pre-qualification experimental work done on the waveguides and the integrated SIC-1 compliant coupling system.

Hybrid heat pipe based passive cooling device for spent nuclear fuel dry storage cask

Conventional dry storage facilities for spent nuclear fuel (SNF) were designed to remove decay heat through the natural convection of air, but this method has limited cooling capacity and a possible re-criticality accident in case of flooding. To enhance the safety and capacity of dry storage cask of SNF, hybrid heat pipe-based passive cooling device was suggested. Heat pipe is an excellent passive heat transfer device using the principles of both conduction and phase change of the working fluid. The heat pipe containing neutron absorber material, the so-called hybrid heat pipe, is expected to prevent the re-criticality accidents of SNF and to increase the safety margin during interim and long term storage period. Moreover, a hybrid heat pipe with thermoelectric module, a Stirling engine and a phase change material tank can be used for utilization of the waste heat as heat-transfer medium. Located at the guide tube or instrumentation tube, hybrid heat pipe can remove decay heat from inside the sealed metal cask to outside, decreasing fuel rod temperature. In this paper, a 2-step analysis was performed using computational fluid dynamics code to evaluate the heat and fluid flow inside a cask, which consisted of a single spent fuel assembly simulation and a full-scope dry cask simulation. For a normal dry storage cask, the maximum fuel temperature is 290.0 °C. With hybrid heat pipe cooling, the temperature decreased to 261.6 °C with application of one hybrid heat pipe per assembly, and to 195.1 °C with the application of five hybrid heat pipes per assembly. Therefore, a dry storage cask with hybrid heat pipes produces relatively low temperature inside a cask and reduces the possibility of structural failure due to thermal degradation.

A new design concept of metal O-ring seal for long-term performance

Elastic recovery is one of the major elements determining sealing performance of the metal seal. Therefore, it is required to increase the elastic recovery for long time operation in extreme environments i.e. high temperature, radiation dose.This paper presents how much elastic recovery can be improved by optimizing the design of the metal O-ring seal without any aids such as an Inconel spring. The shape optimization has been performed based on the result from the topology optimization of the previous study. In order to determine its shape for high elasticity, the cubic B-spline was used and the real coded genetic algorithm (RCGA) was adopted as an optimization algorithm. This study was accompanied with the elasto-plastic analysis to calculate major parameters for performance estimation. Lastly, the elastic recovery and the stored elastic energy rate on the final optimal shape were compared to that of the typical metal O-ring seal.

A leakage model of metallic static seals based on micromorphology characteristics of turning flange surface

Purpose – The purpose of this paper is to develop a leakage model of metallic static seals, which can be used to accurately predict the leakage rate and study the corresponding seal characteristics. The metallic static seal is effectively applied to severe rugged environments where conventional seals cannot meet the needs. More research efforts for deepening the understanding of its seal characteristics are important for its effective and safe applications, of which the study about its leak is one key component. Design/methodology/approach – In the microscopic observations of the turning surface that is general in the processing of flange surfaces, it is found that the spiral morphology is dominant, which had been also obtained by other researches. There are two potential leakage paths for the flange surface of spiral morphology, one is the radial direction perpendicular to the spiral ridges and the other is the circumferential direction along the spiral groove. Based on the microgeometry characteristics of spiral morphology, the micromorphology of turning flange surface is simplified for the calculation of leakage rate, and the simplified methods of the radial and circumferential leakage paths are presented separately. The topography of flange surface studied in this paper is actually measured, and the Abbott bearing surface curve is adopted to represent the micro-profiles parameters. The radial and circumferential leakage models are further developed based on the assumption of laminar flow of the viscous compressible gas. Findings – The experiments used to verify the leakage models were carried out, and the experimental values are well agreed with the calculated values. As the contact pressure increases, the change rules of both radial and circumferential leakage rates are obtained and the obvious transition from radial leak to circumferential leak can be found. Using the proposed leakage models, the effects of the key micro-profiles parameters on the leakage rates are studied, and some specific conclusions are given simultaneously, which are favorable for the theoretical study and practical application of the metallic static seal. Practical implications – By the interpretations of the micromorphology characteristics of turning flange surface, the leakage mechanism of the metallic static seal is further made clear. The proposed leakage model reveals the relationships between the key micro-profiles parameters and some sealing performances about the leakage and can predict the leakage rates of the metallic static seal used in various working conditions. Originality/value – For the metallic static seal, the simplification of the radial leakage path and the radial leakage model are put forward for the first time, so the total leakage model can be systematically reported based on the micromorphology characteristics of turning flange surface. The effects of the key micro-profiles parameters on the seal behaviors including of the leak rate, critical contact pressure and transition from radial leak to circumferential leak etc are also clarified firstly.

Structure Optimization and Performance Analysis of Subsea High Pressure Wellhead Metal Seal

Security and reliability are the main focus of annular metal seal assembly. It is concluded that the factors influence sealing performance of annular metal seal assembly most in view of working conditions of annular metal seal assembly. Taking major influencing factors with response surface method (RSM) analysis, and determining coefficient of regression analysis with finite element method (ANSYS) experiment. Second-order corresponding model is established and the best corresponding interval is concluded. Getting the reasonable values of bulge radius r and loading F on the premise of guarantee the y value and providing theoretical guidance for field operation combined with metal sealing seal principles and experimental research.

Force analysis and tightening optimization of gas sealing drill pipe joints

In this article threaded tool joints of gas sealing drill pipes, which are exposed to different tightening turns and tension load, are analyzed using an elaborate finite element modeling through the use of MSC.Marc13.0. The corresponding mechanics model is also established and the reliability of the model is verified by finite element simulation and full scale test. Some conclusive results have been drawn from the analysis including that the force distribution of the gas sealing joints is quite different from the API standard one, and the metal seal structure can greatly improve the seal performance of the joint under tension load. Research also shows that reasonable tightening turns can effectively reduce the thread axial load growth amplitude under the tensile load as a result improving the fatigue life of the tool joints.

Development and test of a rectangular CERN ConFlat-type flange

Standard circular ConFlat® (CF) flanges are widely used in industry due to their high sealing reliability after being subjected to a bakeout process. The Beam Gas Ionisation (BGI) instrument for the CERN Proton Synchrotron accelerator will require a CF-like rectangular sealing system. Although rectangular CF-type flanges with plastically deforming metal seals have been used, no published designs with validated tests for bakeout under UHV conditions are available. Existing circular CERN CF flanges were compared and a design for a rectangular CF flange was proposed. Two prototypes were manufactured along with copper gaskets. The flanges and gaskets were cleaned and prepared for extensive vacuum testing after bakeout cycles up to 350 °C. This paper summarises the design, analysis and manufacturing process and describes the testing procedures and results. Additionally, the limitations when designing a flange of any shape were explored.

Experimental Study on Thermal Discharge Performance of A Phase Change Thermal Storage Material

Thermal energy storage (TES) equipment utilizing phase change material (PCM) was designed and built. The PCM was sealed inside metal tubes and exchanged heat with process fluid flowing outside. The storage capacity characteristics of the system were analyzed based on data covering the inlet and outlet temperatures of the process fluid, volumetric flow rate of the process fluid and temperature change of the PCM.

The “Philistine Tomb” at Tel ‘ETON

Tomb C1 at Tel ‘Eton (Israel) is a unique Iron Age I elite burial cave (excavated in 1968 by Gershon Edelstein). The finds include many metal artifacts, seals, beads, and dozens of ceramic vessels, including Philistine bichrome pottery. Although some have interpreted the finds as reflecting Philistine occupation at Tel ‘Eton, the ethnic composition of the region and the cultural significance of various objects suggest that the interred were members of the indigenous Canaanite elite. By combining the current understanding of cultural interaction in the region during Iron Age I and similar processes elsewhere, the present study reexamines this tomb and the associated finds. This will enable us to gain new insights into the interaction between the various groups that inhabited the region, internal developments within Canaanite society, and the nature of local responses to colonialism.

A model for analysing the self-tightening coefficient of a metallic lenticular ring gasket joined by a bolted flange

The metallic lenticular ring gasket seal belongs to the half self-tightening category. The self-tightening capability of the gaskets directly determines the sealing performance of the pipeline joined by a bolted flange. Self-tightening coefficients of the lenticular gasket are defined by a mathematical model for the maximum contact pressure and preloaded force of the joint. Following this assumption, new formulae for the gasket stiffness and its member stiffness were derived using the theory of elastic mechanics. The relationship of their deformation coordination to different working conditions was analysed. The theoretical results indicate that the self-tightening capability of the metallic lenticular ring gasket is a function of the member stiffness. To ensure the lenticular ring gasket has self-tightening capability the ratio of member stiffness to gasket stiffness must be greater than a certain value.

Metal sealing performance of subsea X-tree wellhead connector sealer

The metal sealing performance of subsea X-tree wellhead connectors is crucial for the safety and reliability of subsea X-trees. In order to establish the theoretical relation between metal sealing ring’s contact stress and its structural parameters and working pressure, a mechanical analysis method for double-cone sealing of high pressure vessels is applied in analyzing the metal sealing ring under the condition of preload and operation. As a result, the formula of the unit sealing load for the metal sealing ring under operation with residual preload is shown in this paper, which ensures that the metal sealing ring has an excellent sealing effect and can prevent the metal sealing ring from yielding. Besides, while analyzing the sealing process of the metal sealing ring, the change rule of contact stress and working pressure is concluded here, putting forward that the structural parameters of the metal sealing ring are the major factors affecting the change rule. Finally, the analytical solution through theoretical analysis is compared with the simulation result through finite element analysis in a force feedback experiment, and both are consistent with each other, which fully verifies for the design and calculation theory on metal sealing ring’s contact stress and its structural parameters and working pressure deduced in this paper. The proposed research will be treated as an applicable theory guiding the design of metal seal for subsea X-tree wellhead connectors.

An internal ALD-based high voltage divider and signal circuit for MCP-based photodetectors

We describe a pin-less design for the high voltage (HV) resistive divider of the all-glass LAPPDTM 8in.-square thin photodetector module. The divider, which distributes high voltage applied to the photocathode to the two micro-channel plates (MCPs) that constitute the amplification stage, is comprised of the two MCPs and three glass mechanical spacers, each of which is coated with a resistive layer using atomic layer deposition (ALD). The three glass grid spacers and the two MCPs form a continuous resistive path between cathode and anode, with the voltages across the MCPs and the spacers determined by the resistance of each. High voltage is applied on an external tab on the top glass window that connects to the photocathode through the metal seal. The DC ground is supplied by microstrips on the bottom glass plate that form the high-bandwidth anode. The microstrips exit the package through the glass-frit seal of the anode base-plate and the package sidewall. The divider is thus completely internal, with no HV pins penetrating the low-profile flat glass package. Measurements of the performance of the divider are presented for the 8in.-square MCP and spacer package in a custom test fixture and for an assembled externally pumped LAPPDTM prototype with an aluminum photocathode.