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Proceedings Papers

Application of the Vincent Circle to Noise Suppression

D. W. Herrin, G. Sampath
Proc. ASME. NCAD2008, ASME 2008 Noise Control and Acoustics Division Conference, 271-275, July 28–30, 2008
Paper No: NCAD2008-73009
DOI: https://doi.org/10.1115/NCAD2008-73009
Abstract
The Vincent Circle principle may be stated as follows. If a structure is excited harmonically, the response at another position at a particular frequency will trace a circle in the complex plane as a result of a dynamic stiffness modification between two points. As either the real or imaginary part of an introduced dynamic stiffness is varied from plus and minus infinity, the structural or acoustic response will map a circle in the complex plane. This paper summarizes the basis for this little known principle. Two numerical simulations are included to demonstrate how the principle can be applied. In the first example, a cantilevered plate is used to confirm that the principle is amenable to noise problems. A similar analysis is then performed on a construction cab to illustrate the applicability of the method if the structure is excited at multiple locations. The results suggest that the principle can be used in place of or in conjunction with more sophisticated numerical optimization schemes.
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Topics: Noise (Sound), Stiffness, Acoustics, Computer simulation, Construction, Optimization
Journal Articles

Closure to “Discussion of ‘Steady-State Crack Propagation in Pressurized Pipelines Without Backfill’” (1976, ASME J. Pressure Vessel Technol., 98, pp. 323–324)

M. F. Kanninen, S. G. Sampath, C. Popelar
Journal: Journal of Pressure Vessel Technology
Article Type: Discussions
J. Pressure Vessel Technol. November 1976, 98(4): 324–325.
DOI: https://doi.org/10.1115/1.3454419
Published Online: November 1, 1976
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Topics: Crack propagation, Pressure pipes, Pressure vessels, Steady state
Journal Articles

Steady-State Crack Propagation in Pressurized Pipelines Without Backfill

M. F. Kanninen, S. G. Sampath, C. Popelar
Journal: Journal of Pressure Vessel Technology
Article Type: Research Papers
J. Pressure Vessel Technol. February 1976, 98(1): 56–64.
DOI: https://doi.org/10.1115/1.3454326
Published Online: February 1, 1976
Abstract
In a previous paper, a simplified dynamic-shell theory representation was formulated for steady-state motion in a pipeline without backfill. The present work extends this model by (1) incorporating a gas dynamics treatment to determine the axial variation in the pressure exerted by the gas on the pipe walls, and (2) incorporating a plastic yield hinge behind the crack tip. Solutions to the governing dynamic equations are obtained for these conditions and used to calculate the steady-state dynamic energy release rate as a function of crack speed. In the single full-scale experiment in which an independent estimate of the dynamic fracture energy is available for a pipe without backfill, the model predicts a steady-state speed of 780 fps. This can be compared with measured speeds which ranged from 725 to 830 fps in the test. Because the calculated steady-state dynamic energy release rate exhibits a maximum, it is suggested that this approach may offer a basis for crack arrest design of pipelines.
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Topics: Crack propagation, Pressure pipes, Steady state, Fracture (Materials), Pipelines, Pipes, Design, Equations of motion, Gasdynamics, Hinges
Journal Articles

Closure to “Discussion of ‘Steady-State Crack Propagation in Pressurized Pipelines Without Backfill’” (1976, ASME J. Pressure Vessel Technol., 98, p. 65)

M. F. Kanninen, S. G. Sampath, C. Popelar
Journal: Journal of Pressure Vessel Technology
Article Type: Discussions
J. Pressure Vessel Technol. February 1976, 98(1): 65.
DOI: https://doi.org/10.1115/1.3454328
Published Online: February 1, 1976
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Topics: Crack propagation, Pressure pipes, Pressure vessels, Steady state
Journal Articles

Analysis of Multiholed Orthotropic Laminated Plates by the Boundary-Point-Least-Squares Method

S. G. Sampath, L. E. Hulbert
Journal: Journal of Pressure Vessel Technology
Article Type: Research Papers
J. Pressure Vessel Technol. May 1975, 97(2): 118–122.
DOI: https://doi.org/10.1115/1.3454261
Published Online: May 1, 1975
Abstract
The paper describes the application of boundary-point-least-squares method (BPLS) for the determination of stresses in multiply connected finite orthotropic plates under plane stress. Series solutions composed of mapping functions are employed. Numerical solutions presented include the case of an orthotropic plate with an elliptical hole with orientation noncoincident with the material axes.
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Topics: Plates (structures), Stress
Journal Articles

Thermal Stress Analysis of Multiholed Composite Plates and Cylinders by the Boundary-Point-Least-Squares Method

L. E. Hulbert, S. G. Sampath
Journal: Journal of Pressure Vessel Technology
Article Type: Research Papers
J. Pressure Vessel Technol. August 1974, 96(3): 214–219.
DOI: https://doi.org/10.1115/1.3454170
Published Online: August 1, 1974
Abstract
The paper describes the application of the boundary-point-least-squares method (BPLS) to the determination of the two-dimensional temperatures and thermal stresses in composite multiply connected domains. Series solutions are first determined for the steady-state temperatures. Using these temperature solutions, the solution to the thermally-induced stresses is automatically found in terms of Airy stress function series. Applications are described which illustrate use of the method in specific problems.
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Topics: Composite materials, Cylinders, Plates (structures), Thermal stresses, Temperature, Stress, Steady state