Impact of cold conditions on diesel injection processes of biodiesel blends

In this article, we report experimental results on the impact of cold conditions on diesel and biodiesel blends injection processes. We focus on cold conditions in view of the new Euro VI standards concerning problems related to cold-start. A Bosch CRI 3.1 piezoelectric injector was used on a typica...

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Published in:Renewable energy 2016-10, Vol.96, p.270-280
Main Authors: Tinprabath, P., Hespel, C., Chanchaona, S., Foucher, F.
Format: Article
Language:English
Subjects:
Biodiesel
Biodiesel blend
Blends
Cold conditions
Diesel fuels
Discharge coefficient
Discharge coefficients
Engineering Sciences
Fuels
Reactive fluid environment
Spray angle
Spray penetration
Sprayers
Sprays
Winter
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cited_by cdi_FETCH-LOGICAL-c493t-fc5a55160d7820792f037ec625165e5707b8717d4b90462e0e72301d9d7364573
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container_title Renewable energy
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creator Tinprabath, P.
Hespel, C.
Chanchaona, S.
Foucher, F.
description In this article, we report experimental results on the impact of cold conditions on diesel and biodiesel blends injection processes. We focus on cold conditions in view of the new Euro VI standards concerning problems related to cold-start. A Bosch CRI 3.1 piezoelectric injector was used on a typical diesel engine. Five fuel types were tested: diesel, winter diesel, diesel–biodiesel blends (B50), a winter diesel-biodiesel blend (B50(W)) and pure biodiesel (B100). Injection pressures of 30–60 MPa were tested (during start-up of the engine) in order to study the injection flow characteristics at room temperature and in cold conditions. Under cold conditions, the discharge coefficients for all fuels were lower than at room temperature. When the fraction of biodiesel in the blend increased, the discharge coefficients decreased slightly. Spray penetration increased and spray angle strongly decreased in cold conditions. This behavior was particularly clear for the B100 fuel. Winter diesel despite a higher viscosity than diesel showed most interesting performance in terms of discharge coefficient both at low temperature than at room temperature. These benefits disappear with the blend with biodiesel. New correlation coefficients for estimating the discharge coefficient and the spray angle are presented for cold conditions. •The properties of biodiesel and biodiesel blends were tested in cold conditions.•The discharge coefficients of biodiesel and biodiesel blends in cold conditions were investigated.•The spray penetration and spray angle of biodiesel and biodiesel blends in cold conditions were investigated.
doi_str_mv 10.1016/j.renene.2016.04.062
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1879-0682
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subjects Biodiesel
Biodiesel blend
Blends
Cold conditions
Diesel fuels
Discharge coefficient
Discharge coefficients
Engineering Sciences
Fuels
Reactive fluid environment
Spray angle
Spray penetration
Sprayers
Sprays
Winter
title Impact of cold conditions on diesel injection processes of biodiesel blends
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