Experiments and modelling of air flow in impacted flexible polyurethane foams

Nigel Mills; Griselda Lyn

Experiments and modelling of air flow in impacted flexible polyurethane foams

Nigel Mills
, Griselda Lyn

Metallurgy and Materials

Research output: Contribution to journal › Article

Abstract

Polyurethane (PU) chip foam was characterised for air flow resistance, using a modification of the BS 4443 method, and for compressive impact response. A finite difference model was developed for the air flow in the impacted foam, including the effects of strain on foam permeability: It successfully predicted a non-uniform stress distribution across foam block of diameter > 100 mm, and showed that air flow is responsible for some but not all the hysteresis in this distribution for impact velocities > 3 m/s. Air pressure measurements, made in narrow vertical cavities inside impacted blocks of the foam, confirm the air pressure contribution to the total stress.

Original language	English
Pages (from-to)	343-367
Number of pages	25
Journal	Cellular Polymers
Volume	21
Publication status	Published - 1 Jan 2002

Cite this

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title = "Experiments and modelling of air flow in impacted flexible polyurethane foams",

abstract = "Polyurethane (PU) chip foam was characterised for air flow resistance, using a modification of the BS 4443 method, and for compressive impact response. A finite difference model was developed for the air flow in the impacted foam, including the effects of strain on foam permeability: It successfully predicted a non-uniform stress distribution across foam block of diameter > 100 mm, and showed that air flow is responsible for some but not all the hysteresis in this distribution for impact velocities > 3 m/s. Air pressure measurements, made in narrow vertical cavities inside impacted blocks of the foam, confirm the air pressure contribution to the total stress.",

author = "Nigel Mills and Griselda Lyn",

year = "2002",

month = jan,

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language = "English",

volume = "21",

pages = "343--367",

journal = "Cellular Polymers",

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T1 - Experiments and modelling of air flow in impacted flexible polyurethane foams

AU - Mills, Nigel

AU - Lyn, Griselda

PY - 2002/1/1

Y1 - 2002/1/1

N2 - Polyurethane (PU) chip foam was characterised for air flow resistance, using a modification of the BS 4443 method, and for compressive impact response. A finite difference model was developed for the air flow in the impacted foam, including the effects of strain on foam permeability: It successfully predicted a non-uniform stress distribution across foam block of diameter > 100 mm, and showed that air flow is responsible for some but not all the hysteresis in this distribution for impact velocities > 3 m/s. Air pressure measurements, made in narrow vertical cavities inside impacted blocks of the foam, confirm the air pressure contribution to the total stress.

AB - Polyurethane (PU) chip foam was characterised for air flow resistance, using a modification of the BS 4443 method, and for compressive impact response. A finite difference model was developed for the air flow in the impacted foam, including the effects of strain on foam permeability: It successfully predicted a non-uniform stress distribution across foam block of diameter > 100 mm, and showed that air flow is responsible for some but not all the hysteresis in this distribution for impact velocities > 3 m/s. Air pressure measurements, made in narrow vertical cavities inside impacted blocks of the foam, confirm the air pressure contribution to the total stress.

M3 - Article

VL - 21

SP - 343

EP - 367

JO - Cellular Polymers

JF - Cellular Polymers

ER -

Experiments and modelling of air flow in impacted flexible polyurethane foams

Abstract

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