Development of pulse mechanical seal calculation methods on the basis of its physical model construction

A set of systematic experimental methods, including 3D accuracy scanning and identification of discontinuous surface topography, physical model construction, and laboratory direct shear experiment under different directions and normal stresses, was proposed to research the influence of discontinuity roughness on strength and deformation of discontinuity. During physical model construction of discontinuity, three types of discontinuity and rough natural rock joint surface models were constructed and moulded. Meanwhile, many influence factors of discontinuity surface topography, such as asperity inclination angle (AIA), asperity height (AH), normal stress (NS), and shear direction (SD), were considered during the direct shear experiment. On the basis of the experimental results, it can be found that there were two types of failure modes under different loading conditions, which were named “failure by shearing through the asperities” and “failure by sliding over the asperities”. The obvious stress concentration phenomenon, climbing, and cutting effects appeared in the process of the direct shear experiment. In addition, the accurate identification of surface topography of natural rough rock joint surface was carried out using three-dimensional sensing system (3DSS) and self-programming software before and after the experiment. The subsamples with the same surface topography as the original samples were moulded using a self-developed instrument. Then, the mechanical behavior of the original samples and subsamples for the natural rough rock joint surface under different shear directions and normal stresses was studied. The results show that the shear displacement under different shear directions and normal stresses is very large before it reaches the failure state. And the residual strength of the original samples is higher than that of the subsamples. In addition, failure modes of the subsamples are main failure by shearing through the asperities due to the significant difference between peak shear strength and residual strength. The failure modes for parts of the original samples are failure by sliding over the asperities. The change ratio of area for the discontinuity after the experiment depends on surface topography, strength of heave on the surface of discontinuity, and particle size of minerals on the surface of discontinuity.

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Physical Modeling and Simplification of FPSO Topsides Module in Wind Tunnel Model Tests

10.1115/omae2021-63459 ◽

2021 ◽

Author(s):

Zhenjia (Jerry) Huang ◽

Hyun Joe Kim

Keyword(s):

Quality Assurance ◽

Wind Tunnel ◽

Physical Model ◽

Model Test ◽

Physical Modeling ◽

Model Tests ◽

Model Construction ◽

Wind Tunnel Model ◽

Tunnel Model ◽

Modeling Practices

Abstract To evaluate wind load on offshore structures, such as FPSO’s, wind tunnel model test is a common industry practice. Configuration of topsides structures and equipment can be very complex, and it is a practical challenge to model all the structural details for wind tunnel model tests. Sometimes, there may be significant modifications to the topsides over FPSO operation life cycle and there may not be detailed topsides drawing for wind tunnel to use in physical model construction. In practice, wind tunnel laboratories have to simplify physical topsides models. They also use metal meshes to cover the topsides modules to compensate for the force reduction due to the simplification. In order to help establish physical modeling practices of wind tunnel model test, we performed extensive tests using a single topsides module. The original topsides module without simplification and mesh was tested first. Then, two simplifications were adopted in the physical model construction. The module was covered with and without metal mesh of different porosities. Thorough test quality assurance (QA) and quality control (QC) were performed to ensure data quality. Test setup, quality assurance (QA) and results are presented in the paper. The results can be used not only for appropriate physical modeling practices of complex topsides modules, but also for validation of numerical predictions such as Computational Fluid Dynamics (CFD), as well as empirical formulas.

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Physical model construction of traffic conflict formation and dissipation process

10.1109/eiecs53707.2021.9588168 ◽

2021 ◽

Author(s):

Guanzheng Pang

Keyword(s):

Physical Model ◽

Model Construction ◽

Dissipation Process ◽

Traffic Conflict

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Block Mechanism of Microclearance Block Liquid and Lifting Height Calculating

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.430-432.1970 ◽

2012 ◽

Vol 430-432 ◽

pp. 1970-1973

Author(s):

Yan Nian Gong ◽

Jin Dan Yin ◽

Chi Ai ◽

Yong Kun Zhang

Keyword(s):

Physical Model ◽

Mechanical Seal ◽

Gas Migration ◽

First Time ◽

Block Mechanism

Mechanical seal mechanism was applied to study block mechanism of gaswell microclearance block liquid for the first time, which explained block mechanism of microclearance block liquid. The paper has built a block physical model of microclearance block liquid and has got calculation formulas of the block liquid lifting height. Then the block liquid lifting heights were calculated and analyzed in different microclearance widths and pressures. The sealing effect of the block liquid was discussed. The analyzed results showed that sealing effect of the block liquid was very obvious when microclearance width was lesser than 12μm. The paper not only enriched the study on block mechanism of gaswell microclearance block liquid but also proposed theoretical guidance to solve radically gas migration problem of micro-annulus.

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A physical model construction for turning wave study

10.1190/1.1887326 ◽

1995 ◽

Author(s):

Mei Zhang ◽

K. K. Sekharan ◽

Jay G. Henderson ◽

John A. McDonald ◽

Robert H. Tatham

Keyword(s):

Physical Model ◽

Model Construction

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Optimized Design and Research on Technology Parameters of Concentric Dual-Tube Steam Injection Horizontal Well

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.675-677.1505 ◽

2014 ◽

Vol 675-677 ◽

pp. 1505-1511 ◽

Cited By ~ 1

Author(s):

Hong Qin Liu ◽

Zai Hong Shi ◽

Jing Zhu ◽

Zhen Ma

Keyword(s):

Physical Model ◽

Heat Loss ◽

Heavy Oil ◽

Horizontal Well ◽

Horizontal Wells ◽

Steam Injection ◽

Injection Technique ◽

Optimized Design ◽

Calculation Methods ◽

Liaohe Oilfield

The screen pipe completion is the predominated method for heavy oil horizontal well in Liaohe Oilfield, accounting for 83.4% of the total completions. General steam injection has been used for the horizontal wells, resulting in a better exploitation percentage in heel part but a poorer exploitation percentage beyond 1/3 of the distance from the tiptoe to heel in horizontal well. As the concentric dual-tube steam injection technique for horizontal well has just been developed in Liaohe Oilfield, the related supporting technique is not enough. In this paper, researchers consider achieving horizontal wells concentric dual-tube steam injection optimized design as main goal so that the physical model will be established, and also the calculation methods for pressure, the calculation models for quality, heat loss and tapered string parameters along the wellbore will be provided during the concentric dual-tube steam injection for horizontal wells.

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