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TECHNICAL PAPERS

Influence of Clearance Between Plates in Metal Pushing V-Belt Dynamics

[+] Author and Article Information
G. Carbone, L. Mangialardi, G. Mantriota

Dipartimento di Ingegneria Meccanica e Gestionale, Politecnico di Bari, V.le Japigia 182, 70126 Bari, Italy

J. Mech. Des 124(3), 543-557 (Aug 06, 2002) (15 pages) doi:10.1115/1.1486015 History: Received December 01, 2000; Online August 06, 2002
Copyright © 2002 by ASME
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References

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Figures

Grahic Jump Location
Drive pulley: traction coefficient λ versus force ratio ξ (μ=0.1, β=11°)
Grahic Jump Location
Drive pulley: dimensionless parameter δ versus force ratio ξ (μ=0.1, β=11°)
Grahic Jump Location
Belt dynamical behavior: steady-state condition
Grahic Jump Location
Displacement of the generic belt’s element: active arc
Grahic Jump Location
Kinematic and dynamical quantities
Grahic Jump Location
Clearance among the plates
Grahic Jump Location
Drive pulley (no clearance among the segments): λ versus force ratio ξ (μ=0.1, β=11°)
Grahic Jump Location
Drive pulley: dimensionless net tension κ versus ψ for different values of γDR* (w>0, μ=0.1, β=11°)
Grahic Jump Location
Drive pulley: dimensionless net tension κ versus ψ for different values of γDR* (w<0, μ=0.1, β=11°)
Grahic Jump Location
Drive pulley: κ2 for different values of the active arc’s extension α (w<0, μ=0.1, β=11°)
Grahic Jump Location
Driven pulley: dimensionless parameter δ versus force ratio ξ (μ=0.1, β=11°)
Grahic Jump Location
Drive pulley (no clearance among the segments): δ versus force ratio ξ (μ=0.1, β=11°)
Grahic Jump Location
Driven pulley: belt motion and net tension diagram, pitch radius decreasing phases (w<0)
Grahic Jump Location
Driven pulley: belt motion and its sliding velocity, pitch radius increasing phases (w>0)
Grahic Jump Location
Driven pulley: dimensionless net tension κ versus ψ (μ=0.1, β=11°)
Grahic Jump Location
Driven pulley: traction coefficient λ versus force ratio ξ (μ=0.1, β=11°)

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