Pressure drop hysteresis effect on biodiesel filtration

Kyoungtae Kim; Kai Xiao; David B Kittelson; David Y Pui

doi:10.1016/j.fuel.2013.07.079

Pressure drop hysteresis effect on biodiesel filtration

Kyoungtae Kim, Kai Xiao, David B Kittelson, David Y Pui

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Filter plugging is one of the main cold flow problems associated with the use of biodiesel blends in cold climates. We developed a new fuel screening test to analyze the cold flow properties of the biodiesel and its blends with ULSD based on pressure drop measurements across a test filter. The fuel is pumped through a test filter under controlled temperature and flow conditions and the pressure drop is measured. As temperature is reduced at a constant flow rate, the pressure drop increases and the rate of the pressure drop increase goes up sharply as a plugging condition is approached. Biodiesel blends in general exhibit higher pressure drops than ULSD and the pressure drop increases with the biodiesel fraction. When fuels are cooled to -30 C and then reheated, the pressure drop at each temperature is higher than that measured when the fuels are being cooled. The difference between the cooling and heating curves decreases as the fuel isheated but is still present at 20 C. Both ULSD and biodiesel blends exhibit this hysteresis effect, but the effect is much larger with biodiesel blends. This means that exposure of biodiesel blends to low temperatures predisposes them to filter plugging even if they are dispensed and used at higher temperatures. In addition, the pressure drop hysteresis will remain unless fuel properties return to their original state when reheated to 40 C or higher.

Original language	English (US)
Pages (from-to)	629-635
Number of pages	7
Journal	Fuel
Volume	115
DOIs	https://doi.org/10.1016/j.fuel.2013.07.079
State	Published - 2014

Bibliographical note

Funding Information:
This research was supported by Metro Transit, Western Petroleum Company , and their technical and financial support is gratefully acknowledged. The authors thank the support of members of the Center for Filtration Research: 3M Corporation, Boeing Commercial Airplanes, Cummins Filtration Inc., Donaldson Company, Inc., Entegris, Inc., Ford Research and Innovation Center, Hollingsworth &Vose Company, MANN + HUMMEL GMBH, MSP Corporation, Samsung Electronics Co., Ltd, Shigematsu Works Co., Ltd, TSI Inc., and W. L. Gore & Associates, Inc., and the affiliate member National Institute for Occupational Safety and Health (NIOSH) . The authors would like to thank Dr. Winthrop Watts at the University of Minnesota for his valuable comments and discussion.

Keywords

Biodiesel filtration
Cold flow properties
Filter plugging
Hysteresis effect

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "Pressure drop hysteresis effect on biodiesel filtration",

abstract = "Filter plugging is one of the main cold flow problems associated with the use of biodiesel blends in cold climates. We developed a new fuel screening test to analyze the cold flow properties of the biodiesel and its blends with ULSD based on pressure drop measurements across a test filter. The fuel is pumped through a test filter under controlled temperature and flow conditions and the pressure drop is measured. As temperature is reduced at a constant flow rate, the pressure drop increases and the rate of the pressure drop increase goes up sharply as a plugging condition is approached. Biodiesel blends in general exhibit higher pressure drops than ULSD and the pressure drop increases with the biodiesel fraction. When fuels are cooled to -30 C and then reheated, the pressure drop at each temperature is higher than that measured when the fuels are being cooled. The difference between the cooling and heating curves decreases as the fuel isheated but is still present at 20 C. Both ULSD and biodiesel blends exhibit this hysteresis effect, but the effect is much larger with biodiesel blends. This means that exposure of biodiesel blends to low temperatures predisposes them to filter plugging even if they are dispensed and used at higher temperatures. In addition, the pressure drop hysteresis will remain unless fuel properties return to their original state when reheated to 40 C or higher.",

keywords = "Biodiesel filtration, Cold flow properties, Filter plugging, Hysteresis effect",

author = "Kyoungtae Kim and Kai Xiao and Kittelson, {David B} and Pui, {David Y}",

note = "Funding Information: This research was supported by Metro Transit, Western Petroleum Company , and their technical and financial support is gratefully acknowledged. The authors thank the support of members of the Center for Filtration Research: 3M Corporation, Boeing Commercial Airplanes, Cummins Filtration Inc., Donaldson Company, Inc., Entegris, Inc., Ford Research and Innovation Center, Hollingsworth &Vose Company, MANN + HUMMEL GMBH, MSP Corporation, Samsung Electronics Co., Ltd, Shigematsu Works Co., Ltd, TSI Inc., and W. L. Gore & Associates, Inc., and the affiliate member National Institute for Occupational Safety and Health (NIOSH) . The authors would like to thank Dr. Winthrop Watts at the University of Minnesota for his valuable comments and discussion. ",

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doi = "10.1016/j.fuel.2013.07.079",

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AU - Xiao, Kai

AU - Kittelson, David B

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N1 - Funding Information: This research was supported by Metro Transit, Western Petroleum Company , and their technical and financial support is gratefully acknowledged. The authors thank the support of members of the Center for Filtration Research: 3M Corporation, Boeing Commercial Airplanes, Cummins Filtration Inc., Donaldson Company, Inc., Entegris, Inc., Ford Research and Innovation Center, Hollingsworth &Vose Company, MANN + HUMMEL GMBH, MSP Corporation, Samsung Electronics Co., Ltd, Shigematsu Works Co., Ltd, TSI Inc., and W. L. Gore & Associates, Inc., and the affiliate member National Institute for Occupational Safety and Health (NIOSH) . The authors would like to thank Dr. Winthrop Watts at the University of Minnesota for his valuable comments and discussion.

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N2 - Filter plugging is one of the main cold flow problems associated with the use of biodiesel blends in cold climates. We developed a new fuel screening test to analyze the cold flow properties of the biodiesel and its blends with ULSD based on pressure drop measurements across a test filter. The fuel is pumped through a test filter under controlled temperature and flow conditions and the pressure drop is measured. As temperature is reduced at a constant flow rate, the pressure drop increases and the rate of the pressure drop increase goes up sharply as a plugging condition is approached. Biodiesel blends in general exhibit higher pressure drops than ULSD and the pressure drop increases with the biodiesel fraction. When fuels are cooled to -30 C and then reheated, the pressure drop at each temperature is higher than that measured when the fuels are being cooled. The difference between the cooling and heating curves decreases as the fuel isheated but is still present at 20 C. Both ULSD and biodiesel blends exhibit this hysteresis effect, but the effect is much larger with biodiesel blends. This means that exposure of biodiesel blends to low temperatures predisposes them to filter plugging even if they are dispensed and used at higher temperatures. In addition, the pressure drop hysteresis will remain unless fuel properties return to their original state when reheated to 40 C or higher.

AB - Filter plugging is one of the main cold flow problems associated with the use of biodiesel blends in cold climates. We developed a new fuel screening test to analyze the cold flow properties of the biodiesel and its blends with ULSD based on pressure drop measurements across a test filter. The fuel is pumped through a test filter under controlled temperature and flow conditions and the pressure drop is measured. As temperature is reduced at a constant flow rate, the pressure drop increases and the rate of the pressure drop increase goes up sharply as a plugging condition is approached. Biodiesel blends in general exhibit higher pressure drops than ULSD and the pressure drop increases with the biodiesel fraction. When fuels are cooled to -30 C and then reheated, the pressure drop at each temperature is higher than that measured when the fuels are being cooled. The difference between the cooling and heating curves decreases as the fuel isheated but is still present at 20 C. Both ULSD and biodiesel blends exhibit this hysteresis effect, but the effect is much larger with biodiesel blends. This means that exposure of biodiesel blends to low temperatures predisposes them to filter plugging even if they are dispensed and used at higher temperatures. In addition, the pressure drop hysteresis will remain unless fuel properties return to their original state when reheated to 40 C or higher.

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KW - Cold flow properties

KW - Filter plugging

KW - Hysteresis effect

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VL - 115

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JF - Fuel

ER -

Pressure drop hysteresis effect on biodiesel filtration

Abstract

Bibliographical note

Keywords

UN SDGs

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