Your search keyword '"POCKET GEOMETRY"' showing total 5 results

1. Dynamic Performance of an Externally Pressurized Porous Thrust Bearing Employing Different Pocket Shape

Author

Vivek Kumar, Vatsalkumar Ashokkumar Shah, Kuldeep Narwat, and Satish C. Sharma

Subjects

porous thrust bearing, permeability, pocket geometry, fem, Physics, QC1-999, Engineering (General). Civil engineering (General), TA1-2040, Mechanical engineering and machinery, TJ1-1570, Chemistry, QD1-999

Abstract

The use of porous facing/layer in fluid film bearings offers some unique advantages such as self-lubricating properties (acting as lubricant reservoir), compactness, economical over conventional bearing etc. This article presents a numerical simulation of an externally pressurized porous thrust bearing. The collective effect of permeability of porous facing and lubricant supplying pocket shape has been investigated on steady-state and dynamic performance indices of bearing. Flow governing equation i.e. Reynolds equation, Darcy’s Law and fluid flow equation (through an orifice device) has been solved simultaneously (using finite element approach) to compute fluid film pressure distribution. The bearing performance indices i.e. film reaction force, lubricant flow, stiffness and damping parameters are computed as a function of permeability and geometric shape of pocket. It has been reported that high value of permeability of porous facing have an adverse effect on the load supporting capacity, lubricant flow, stiffness and damping parameters of the bearing. There exist a range of permeability value ((2.2~3)10-14 m2; ψ = 0.001~0.01) within which the adverse effect of using porous facing can be partially reduced/mitigated by appropriate selection of pocket shape (Circular and square) in thrust pad.

Published

2020

2. Optimization of Pocket Geometry for Friction Reduction in Piston-Liner Contacts.

Author

Vlădescu, Sorin-Cristian, Ciniero, Alessandra, Tufail, Khizer, Gangopadhyay, Arup, and Reddyhoff, Tom

Subjects

LUBRICATION & lubricants, MECHANICAL wear, SURFACE roughness, SHEAR strength, SOIL mechanics

Abstract

It has recently been shown that rectangular surface pockets are effective in reducing friction in a piston-liner type contact, providing that they are oriented with their long axis transverse to the sliding direction so that entrained features fit completely within the contact area (Vlădescu, et al., Tribology International, 82, 28-42, 2015; Vlădescu, et al., Tribology International, 115, 140-153, 2017). The aim of the current study was to identify the optimal geometric parameters of theses rectangular features. To do this, a friction rig that simulated a piston-liner contact under highly controlled conditions was used to test a series of textured specimens with pockets of different depth, breadth and density. Each of these geometric parameters was varied and tested independently, while keeping the other two constant. Experimental conditions were set in order to place the contact in different lubrication regimes. Results were analyzed to determine a set of criteria for the optimum pocket geometry; however, this was shown to change depending on the test conditions and should therefore be adjusted depending on the position along the stroke. Specifically, at low speed when the contact is operating under boundary lubrication, pockets should be deep, wide, and densely spaced. This confirms recent findings, which suggested that, in this regime, pocket volume is often a more critical parameter than depth, width, or spacing individually. Conversely, under mixed lubrication toward the transition to the full film regime, pockets should be narrow and sparsely spaced. These results also explain the difficulties encountered in several previous studies that attempted to define a single optimum pocket geometry. Finally, the impact of pocket position relative to reversal was assessed for various lubrication conditions. This revealed how pockets should be placed close to, but not directly at, top and bottom dead center to provide a beneficial squeeze film, which is present at reversal. [ABSTRACT FROM AUTHOR]

Published

2018

3. Dynamic Performance of an Externally Pressurized Porous Thrust Bearing Employing Different Pocket Shape

Author

Satish C. Sharma, Kuldeep Narwat, Vivek Kumar, and Vatsalkumar Ashokkumar Shah

Subjects

fem, Materials science, Physics, QC1-999, Mechanical engineering, Engineering (General). Civil engineering (General), pocket geometry, Surfaces, Coatings and Films, law.invention, Chemistry, Thrust bearing, law, TJ1-1570, Mechanical engineering and machinery, permeability, TA1-2040, Porosity, QD1-999, porous thrust bearing

Abstract

The use of porous facing/layer in fluid film bearings offers some unique advantages such as self-lubricating properties (acting as lubricant reservoir), compactness, economical over conventional bearing etc. This article presents a numerical simulation of an externally pressurized porous thrust bearing. The collective effect of permeability of porous facing and lubricant supplying pocket shape has been investigated on steady-state and dynamic performance indices of bearing. Flow governing equation i.e. Reynolds equation, Darcy’s Law and fluid flow equation (through an orifice device) has been solved simultaneously (using finite element approach) to compute fluid film pressure distribution. The bearing performance indices i.e. film reaction force, lubricant flow, stiffness and damping parameters are computed as a function of permeability and geometric shape of pocket. It has been reported that high value of permeability of porous facing have an adverse effect on the load supporting capacity, lubricant flow, stiffness and damping parameters of the bearing. There exist a range of permeability value ((2.2~3)10-14 m2; ψ = 0.001~0.01) within which the adverse effect of using porous facing can be partially reduced/mitigated by appropriate selection of pocket shape (Circular and square) in thrust pad.

Published

2020

4. Extrusion Benchmark 2007 – Benchmark Experiments: Study on Material Flow Extrusion of a Flat Die

Author

Lorenzo Donati, M. Schikorra, Luca Tomesani, A. Erman Tekkaya, L. Donati, L. Tomesani, M. Schikorra, A. E. Tekkaya, and Luca Tomesani, Lorenzo Donati

Subjects

Work (thermodynamics), Engineering, business.product_category, Design stage, business.industry, Mechanical Engineering, Process (computing), Mechanical engineering, EXTRUSION, BENCHMARK, ALUMINUM, Material flow, Set (abstract data type), POCKET GEOMETRY, Mechanics of Materials, SIMULATION, Benchmark (computing), Die (manufacturing), General Materials Science, Extrusion, business, MATERIAL FLOW

Abstract

The experimental conditions chosen as a reference for the 2007 edition of the extrusion benchmark that was held in Bologna, Italy, and the corresponding main results are sum-marized in this work. The die design stage is first explained in order to address the main features of the experiment and its objectives. The die is a flat one with multiple holes; four angular profiles were produced with different pocket geometries, the experimental plan being entirely described. The initial temperatures for the billet and the die set, together with the temperature development during the process strokes, are also reported. The results are shown, for each profile, in terms of final profile length, mean exit speed, global process load, profile exit temperature.

Published

2008

5. Evaluation of process speed effect in aluminium extrusion by experiment and simulations

Author

Barbara Reggiani, Donati, L., Tomesani, L., THE MINERALS, METALS & MATERIALS SOCIETY, INC., B. Reggiani, L. Donati, and L. Tomesani

Subjects

POCKET GEOMETRY, PROCESS SPEED, EXTRUSION, FE SIMULATION

Abstract

In the first part of the paper, experimental trials performed in the extrusion of 4 L-shaped profiles made by AA6082 aluminium alloy were presented and analyzed in order to investigate the effect of different pockets concepts on process results like extrusion load, profile lengths, die and profile temperature. The trials were performed at 0,5 and 5 mm/sec ram speed thus producing unexpected differences especially in term of profile lengths. Then two FE codes, COMSOL® Multiphysics and DEFORMTM 3D, were applied in the simulation of the problem in order to validate FEM simulations by comparison with the experimental trials. In particular the two codes adopt different formulations for process analysis: eulerian the first updated lagrangian the second, thus producing also an interesting comparison of the solving methods for the prediction of process outputs like loads, final profiles speeds and exit temperatures.