Design features of pressure vessels working with internal pressure at low temperatures

Very thin cylindrical pressure vessels with torispherical end-closures have been tested under internal pressure until buckles developed in the knuckles of the ends. These were prototype vessels in an austenitic stainless steel. The preparation of the ends and the closed test vessels is outlined, and the instrumentation, test installation, and test procedure are described. Results are given and discussed for three typical ends (diameters 54, 81, and 108in.; thickness to diameter ratios 0.00237, 0.00158, and 0.00119). These include measured thickness and curvature distributions, strain data and the derived elastic stress indices, and pole deflection measurements. Some details of the observed time-dependent plasticity (or ‘cold creep’) are given. Details of two types of buckle that developed eventually in the vessel ends are also reported.

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A Noncyclic Method for Determination of Accumulated Strain in Stainless Steel 304 Pressure Vessels

Journal of Pressure Vessel Technology ◽

10.1115/1.4026940 ◽

2014 ◽

Vol 136 (6) ◽

Author(s):

Gongfeng Jiang ◽

Gang Chen ◽

Liang Sun ◽

Yiliang Zhang ◽

Xiaoliang Jia ◽

...

Keyword(s):

Stainless Steel ◽

Internal Pressure ◽

Pressure Vessel ◽

Peak Stress ◽

Pressure Vessels ◽

Experimental Results ◽

Elastic Domain ◽

Ratcheting Strain ◽

Stainless Steel 304 ◽

Accumulated Strain

Experimental results of uniaxial ratcheting tests for stainless steel 304 (SS304) under stress-controlled condition at room temperature showed that the elastic domain defined in this paper expands with accumulation of plastic strain. Both ratcheting strain and viscoplastic strain rates reduce with the increase of elastic domain, and the total strain will be saturated finally. If the saturated strain and corresponded peak stress of different experimental results under the stress ratio R ≥ 0 are plotted, a curve demonstrating the material shakedown states of SS304 can be constituted. Using this curve, the accumulated strain in a pressure vessel subjected to cyclic internal pressure can be determined by only an elastic-plastic analysis, and without the cycle-by-cycle analysis. Meanwhile, a physical experiment of a thin-walled pressure vessel subjected to cyclic internal pressure has been carried out to verify the feasibility and effectiveness of this noncyclic method. By comparison, the accumulated strains evaluated by the noncyclic method agreed well with those obtained from the experiments. The noncyclic method is simpler and more practical than the cycle-by-cycle method for engineering design.

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Failure probability analysis of pressure vessels that contain defects under the coupling of inertial force and internal pressure

International Journal of Pressure Vessels and Piping ◽

10.1016/j.ijpvp.2018.09.005 ◽

2018 ◽

Vol 168 ◽

pp. 59-65 ◽

Cited By ~ 5

Author(s):

Zhiyan Xiao ◽

Junping Shi ◽

Xiaoshan Cao ◽

Yong Xu ◽

Yifeng Hu

Keyword(s):

Internal Pressure ◽

Failure Probability ◽

Inertial Force ◽

Pressure Vessels ◽

Probability Analysis

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A Single Technically Consistent Design Formula for the Thickness of Cylindrical Sections Under Internal Pressure

Journal of Pressure Vessel Technology ◽

10.1115/1.2389035 ◽

2006 ◽

Vol 129 (1) ◽

pp. 211-215 ◽

Cited By ~ 2

Author(s):

John D. Fishburn

Keyword(s):

Experimental Data ◽

Internal Pressure ◽

State Of The Art ◽

Original Data ◽

Pressure Vessels ◽

Time Dependent ◽

Design Codes ◽

Recent Developments ◽

Current Design ◽

Single Formula

Within the current design codes for boilers, piping, and pressure vessels, there are many different equations for the thickness of a cylindrical section under internal pressure. A reassessment of these various formulations, using the original data, is described together with more recent developments in the state of the art. A single formula, which can be demonstrated to retain the same design margin in both the time-dependent and time-independent regimes, is shown to give the best correlation with the experimental data and is proposed for consideration for inclusion in the design codes.

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Fracture of laminated woven GFRP composite pressure vessels under combined low-velocity impact and internal pressure

Archives of Civil and Mechanical Engineering ◽

10.1016/j.acme.2018.07.006 ◽

2018 ◽

Vol 18 (4) ◽

pp. 1715-1728 ◽

Cited By ~ 8

Author(s):

Shokrollah Sharifi ◽

Soheil Gohari ◽

Masoumeh Sharifiteshnizi ◽

Reza Alebrahim ◽

Colin Burvill ◽

...

Keyword(s):

Internal Pressure ◽

Pressure Vessels ◽

Low Velocity Impact ◽

Low Velocity ◽

Velocity Impact ◽

Gfrp Composite ◽

Composite Pressure Vessels

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Maximum Condensable Pressure in a Sealed Container With Arbitrary Temperature Distribution

Volume 8: Energy ◽

10.1115/imece2020-23142 ◽

2020 ◽

Author(s):

J. I. Watjen ◽

M. T. Schifano ◽

M. N. Sexton

Keyword(s):

Temperature Distribution ◽

Internal Pressure ◽

Strong Relationship ◽

Pressure Vessels ◽

Large Temperature ◽

Internal Temperature ◽

Seal Integrity ◽

Arbitrary Temperature ◽

Vapor Mixtures ◽

Saturated Boiling

Abstract Pressure vessels and sealed canisters are designed to maintain seal integrity under a maximum internal pressure. When the temperature inside the canister rises, the internal pressure rises accordingly. The presence of condensable liquid-vapor mixtures can create a strong relationship between the pressure and temperature. An isothermal container admits a straightforward thermodynamic pressure calculation; however, large temperature gradients inside the container require complex multiphase conjugate heat transfer calculations to predict accurate pressures. A simplified prediction using the peak internal temperature to find the saturated pressure of the condensable fluid may introduce unrealistic pressures when significant fluid mass exists in a cooler location of the container. This work presents methodology to calculate the pressure of a condensable fluid in a sealed container with large internal temperature differences using a two-temperature approach to predict saturated boiling and superheating of the vapor phase. An arbitrary temperature distribution allows for pressure calculations by considering the expected location of the liquid mass and the peak internal temperature. An enthalpy balance provides the effects of the temperature distribution and the peak pressure condition is easily predicted using the proposed method. This work provides a means to calculate the maximum internal pressure of a sealed container with a condensable fluid without the need for complex multiphase computer modeling.

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A Comprehensive Study on Burst Pressure Performance of Aluminum Liner for Hydrogen Storage Vessels

Journal of Pressure Vessel Technology ◽

10.1115/1.4049644 ◽

2021 ◽

Vol 143 (4) ◽

Author(s):

Serkan Kangal ◽

A. Harun Sayı ◽

Ozan Ayakdaş ◽

Osman Kartav ◽

Levent Aydın ◽

...

Keyword(s):

Internal Pressure ◽

Axial Strain ◽

Cylindrical Part ◽

Pressure Vessels ◽

Fe Analysis ◽

Burst Pressure ◽

Experimental Investigations ◽

Fe Model ◽

Stress Criterion ◽

Analytical Approaches

Abstract This paper presents a comparative study on the burst pressure performance of aluminum (Al) liner for type-III composite overwrapped pressure vessels (COPVs). In the analysis, the vessels were loaded with increasing internal pressure up to the burst pressure level. In the analytical part of the study, the burst pressure of the cylindrical part was predicted based on the modified von Mises, Tresca, and average shear stress criterion (ASSC). In the numerical analysis, a finite element (FE) model was established in order to predict the behavior of the vessel as a function of increasing internal pressure and determine the final burst. The Al pressure vessels made of Al-6061-T6 alloy with a capacity of 5 L were designed. The manufacturing of the metallic vessels was purchased from a metal forming company. The experimental study was conducted by pressurizing the Al vessels until the burst failure occurred. The radial and axial strain behaviors were monitored at various locations on the vessels during loading. The results obtained through analytical, numerical, and experimental work were compared. The average experimental burst pressure of the vessels was found to be 279 bar. The experimental strain data were compared with the results of the FE analysis. The results indicated that the FE analysis and ASSC-based elastoplastic analytical approaches yielded the best predictions which are within 2.2% of the experimental burst failure values. It was also found that the elastic analysis underestimated the burst failure results; however, it was effective for determining the critical regions over the vessel structure. The strain behavior of the vessels obtained through experimental investigations was well correlated with those predicted through FE analysis.

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Isothermal compressibility and internal pressure studies of some non-electrolytes in aqueous solutions at low temperatures

The Journal of Chemical Thermodynamics ◽

10.1016/j.jct.2006.08.007 ◽

2007 ◽

Vol 39 (4) ◽

pp. 667-673 ◽

Cited By ~ 11

Author(s):

Sudhakar S. Dhondge ◽

L. Ramesh

Keyword(s):

Aqueous Solutions ◽

Internal Pressure ◽

Low Temperatures ◽

Isothermal Compressibility

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Diagnostics of the technical condition of pressure vessels operating under internal pressure by a thermal (thermal imaging) method

Russian Journal of Nondestructive Testing ◽

10.1134/s1061830908100033 ◽

2008 ◽

Vol 44 (10) ◽

pp. 669-675

Author(s):

O. N. Budadin ◽

V. Yu. Kutyurin ◽

V. O. Kaledin

Keyword(s):

Internal Pressure ◽

Thermal Imaging ◽

Technical Condition ◽

Pressure Vessels ◽

Imaging Method

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Validity of Assessment Procedure in p-M Method for Multiple Volumetric Flaws

Volume 16: Safety Engineering, Risk Analysis and Reliability Methods ◽

10.1115/imece2008-68473 ◽

2008 ◽

Author(s):

Shinji Konosu ◽

Masato Kano ◽

Norihiko Mukaimachi ◽

Shinichiro Kanamaru

Keyword(s):

Internal Pressure ◽

Yield Stress ◽

Bending Moment ◽

Pressure Vessels ◽

Assessment Procedure ◽

Plastic Collapse ◽

Storage Tanks ◽

Collapse Load ◽

The Status ◽

Single Flaw

General components such as pressure vessels, piping, storage tanks and so on are designed in accordance with the construction codes based on the assumption that there are no flaws in such components. There are, however, numerous instances in which in-service single or multiple volumetric flaws (local thin areas; volumetric flaws) are found in the equipment concerned. Therefore, it is necessary to establish a Fitness for Service (FFS) rule, which is capable of judging these flaws. The procedure for a single flaw or multiple flaws has recently been proposed by Konosu for assessing the flaws in the p–M (pressure-moment) Diagram, which is an easy way to visualize the status of the component with flaws simultaneously subjected to internal pressure, p and external bending moment, M due to earthquake, etc. If the assessment point (Mr, pr) lies inside the p–M line, the component with flaws is judged to be safe. In this paper, numerous experiments and FEAs for a cylinder with external multiple volumetric flaws were conducted under (1) pure internal pressure, (2) pure external bending moment, and (3) subjected simultaneously to both internal pressure and external bending moment, in order to determine the plastic collapse load at volumetric flaws by applying the twice-elastic slope (TES) as recommended by ASME. It has been clarified that the collapse (TES) loads are much the same as those calculated under the proposed p–M line based on the measured yield stress.

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