Structure Optimization and Sealing Performance of Double Corrugated Self-Sealing Composite Gasket

The seal is the key part of the cone bit. To reduce the failure probability, a new seal was designed and studied. The sealing performance and structure optimization of the X-O composite seal was analyzed and compared by finite-element analysis. The stress and contact pressure were analyzed to establish the main structural parameters that affect sealing performance and the direction of the structural optimization. By optimizing these structural parameters, including the height, and the radial and axial arc radii, an optimized structure is obtained. The results show that (1) the X-O composite seal can meet the seal requirement, the excessive height of the X seal ring is the root cause of the uneven distribution of stress, pressure, and distortion. (2) A new seal structure is obtained, the distribution of pressure and stress is reasonable and even, and the values of stress and pressure are reduced to avoid distortion and reduce the wear. Finally, the field test results of the X-O composite seal of cone bit showed that the service life of the bit bearing increased by 16% on average and the drilling efficiency increased by 11% on average compared with the original cone bit with the O seal ring.

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

The Open Mechanical Engineering Journal ◽

10.2174/1874155x01509010564 ◽

2015 ◽

Vol 9 (1) ◽

pp. 564-568

Author(s):

Wensheng Xiao ◽

Chao Hou ◽

Jian Liu ◽

Bo Luan ◽

Hongyan Wang

Keyword(s):

Working Conditions ◽

Structure Optimization ◽

Surface Method ◽

Sealing Performance ◽

Metal Seal ◽

Seal Assembly ◽

Security And Reliability ◽

And Performance ◽

Coefficient Of Regression ◽

Optimization And Performance

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.

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Structural Optimization Design of the Arc Finger Seal

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.365-366.1194 ◽

2013 ◽

Vol 365-366 ◽

pp. 1194-1197

Author(s):

Fang Qi ◽

Hua Su

Keyword(s):

Optimization Design ◽

Structural Parameters ◽

Geometric Model ◽

Structure Optimization ◽

Performance Comparison ◽

Ansys Software ◽

Mathematical Relationship ◽

Relationship Analysis ◽

Sealing Performance ◽

Finger Pad

According to the working condition of the finger seal, a geometric model applied to optimization of finger seal with arc curve (arc finger seal) is established based on mathematical relationship analysis of the finger seal structural parameters. Two performances, the hysteresis and contact pressure between finger pad and rotors surface, are put forward as the objectives for the structure optimization of the finger seal. The optimization model of C/C composites arc finger seal is presented and the multi-objective optimization process is carried out based on ANSYS software. An optimization design example is given which shows that comprehensive performance of finger seal can be obviously improved through the structure optimization. The performance comparison between a C/C composites and a metal material arc finger seal with the same structural and working conditions proves that the choice of C/C composites as the finger seal material, to a certain extent, may improve the sealing performance effectively. It provides a new choice for the design of the finger seal.

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