Velocity Field Measurements with High Speed Structural Image Velocimetry in the Primary Atomization Region of Future Diesel Fuels

Publikation: Beitrag in FachzeitschriftKonferenzaufsatz in FachzeitschriftForschungPeer-Review

Autoren

  • Toni Dageförde
  • Karsten Gröger
  • Noritsune Kawaharada
  • Friedrich Dinkelacker

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Details

OriginalspracheEnglisch
Seiten (von - bis)378-386
FachzeitschriftSAE Technical Papers
Jahrgang3
Ausgabenummer1
Frühes Online-Datum14 Apr. 2020
PublikationsstatusVeröffentlicht - 15 Sept. 2020
VeranstaltungSAE 2020 International Powertrains, Fuels and Lubricants Meeting, PFL 2020 - Virtual, Online, Polen
Dauer: 22 Sept. 202024 Sept. 2020

Abstract

Fuel spray breakup in combustion engines and hence all following processes are determined by the primary atomization. Due to high optical densities as well as high velocities and structures in the µm-range, the measurement of sprays in the near nozzle region is extremely challenging. Therefore, the processes of the primary breakup are not fully understood yet, although these processes are very important for simulation of spray atomization. One important property of a spray is the velocity distribution close to the nozzle outlet. With the newly developed Structural Image Velocimetry (SIV) technique it is possible to visualize spray structures in the near nozzle region and track them via cross-correlation algorithms, so that two-dimensional velocity fields of the spray can be derived. The initial SIV technique is improved with a new high-speed setup, allowing to observe also the temporal behavior of the spray velocities during the injection. Within this work, velocities of potential future diesel fuels were measured under engine relevant conditions with a variation of fuel pressure, fuel temperature and gas pressure based on the ECN Spray A conditions. Velocity fields of Oxymethlyenether 3-5 (OME) as an E-Fuel and Hydrogenated Vegetable Oil (HVO) as a Bio-Fuel were measured and compared with Gas-To-Liquid Diesel (GTL) as a reference fuel. For constant fuel pressures, the velocity distribution for OME shows significantly different values than for GTL and HVO, having about 15 % lower values and much lower deceleration behavior in downstream direction. Obviously the OME spray has a weaker air-fuel interaction. This can be attributed to a lower density leading to reduced nozzle outlet velocities and a lower Weber number.

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Velocity Field Measurements with High Speed Structural Image Velocimetry in the Primary Atomization Region of Future Diesel Fuels. / Dageförde, Toni; Gröger, Karsten; Kawaharada, Noritsune et al.
in: SAE Technical Papers, Jahrgang 3, Nr. 1, 15.09.2020, S. 378-386.

Publikation: Beitrag in FachzeitschriftKonferenzaufsatz in FachzeitschriftForschungPeer-Review

Dageförde, T, Gröger, K, Kawaharada, N & Dinkelacker, F 2020, 'Velocity Field Measurements with High Speed Structural Image Velocimetry in the Primary Atomization Region of Future Diesel Fuels', SAE Technical Papers, Jg. 3, Nr. 1, S. 378-386. https://doi.org/10.4271/2020-01-2112
Dageförde, T., Gröger, K., Kawaharada, N., & Dinkelacker, F. (2020). Velocity Field Measurements with High Speed Structural Image Velocimetry in the Primary Atomization Region of Future Diesel Fuels. SAE Technical Papers, 3(1), 378-386. https://doi.org/10.4271/2020-01-2112
Dageförde T, Gröger K, Kawaharada N, Dinkelacker F. Velocity Field Measurements with High Speed Structural Image Velocimetry in the Primary Atomization Region of Future Diesel Fuels. SAE Technical Papers. 2020 Sep 15;3(1):378-386. Epub 2020 Apr 14. doi: 10.4271/2020-01-2112
Dageförde, Toni ; Gröger, Karsten ; Kawaharada, Noritsune et al. / Velocity Field Measurements with High Speed Structural Image Velocimetry in the Primary Atomization Region of Future Diesel Fuels. in: SAE Technical Papers. 2020 ; Jahrgang 3, Nr. 1. S. 378-386.
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title = "Velocity Field Measurements with High Speed Structural Image Velocimetry in the Primary Atomization Region of Future Diesel Fuels",
abstract = "Fuel spray breakup in combustion engines and hence all following processes are determined by the primary atomization. Due to high optical densities as well as high velocities and structures in the µm-range, the measurement of sprays in the near nozzle region is extremely challenging. Therefore, the processes of the primary breakup are not fully understood yet, although these processes are very important for simulation of spray atomization. One important property of a spray is the velocity distribution close to the nozzle outlet. With the newly developed Structural Image Velocimetry (SIV) technique it is possible to visualize spray structures in the near nozzle region and track them via cross-correlation algorithms, so that two-dimensional velocity fields of the spray can be derived. The initial SIV technique is improved with a new high-speed setup, allowing to observe also the temporal behavior of the spray velocities during the injection. Within this work, velocities of potential future diesel fuels were measured under engine relevant conditions with a variation of fuel pressure, fuel temperature and gas pressure based on the ECN Spray A conditions. Velocity fields of Oxymethlyenether 3-5 (OME) as an E-Fuel and Hydrogenated Vegetable Oil (HVO) as a Bio-Fuel were measured and compared with Gas-To-Liquid Diesel (GTL) as a reference fuel. For constant fuel pressures, the velocity distribution for OME shows significantly different values than for GTL and HVO, having about 15 % lower values and much lower deceleration behavior in downstream direction. Obviously the OME spray has a weaker air-fuel interaction. This can be attributed to a lower density leading to reduced nozzle outlet velocities and a lower Weber number.",
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Download

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T1 - Velocity Field Measurements with High Speed Structural Image Velocimetry in the Primary Atomization Region of Future Diesel Fuels

AU - Dageförde, Toni

AU - Gröger, Karsten

AU - Kawaharada, Noritsune

AU - Dinkelacker, Friedrich

N1 - Funding Information: This work is financed by the German Research Association for Combustion Engines (Forschungsvereinigung Verbrennungskraftmaschinen, FVV) within the project “Spray Diagnostics of Future Diesel Fuels” (FVV No. 6013201). We thank the members of the FVV working group for supporting the research and the publication.

PY - 2020/9/15

Y1 - 2020/9/15

N2 - Fuel spray breakup in combustion engines and hence all following processes are determined by the primary atomization. Due to high optical densities as well as high velocities and structures in the µm-range, the measurement of sprays in the near nozzle region is extremely challenging. Therefore, the processes of the primary breakup are not fully understood yet, although these processes are very important for simulation of spray atomization. One important property of a spray is the velocity distribution close to the nozzle outlet. With the newly developed Structural Image Velocimetry (SIV) technique it is possible to visualize spray structures in the near nozzle region and track them via cross-correlation algorithms, so that two-dimensional velocity fields of the spray can be derived. The initial SIV technique is improved with a new high-speed setup, allowing to observe also the temporal behavior of the spray velocities during the injection. Within this work, velocities of potential future diesel fuels were measured under engine relevant conditions with a variation of fuel pressure, fuel temperature and gas pressure based on the ECN Spray A conditions. Velocity fields of Oxymethlyenether 3-5 (OME) as an E-Fuel and Hydrogenated Vegetable Oil (HVO) as a Bio-Fuel were measured and compared with Gas-To-Liquid Diesel (GTL) as a reference fuel. For constant fuel pressures, the velocity distribution for OME shows significantly different values than for GTL and HVO, having about 15 % lower values and much lower deceleration behavior in downstream direction. Obviously the OME spray has a weaker air-fuel interaction. This can be attributed to a lower density leading to reduced nozzle outlet velocities and a lower Weber number.

AB - Fuel spray breakup in combustion engines and hence all following processes are determined by the primary atomization. Due to high optical densities as well as high velocities and structures in the µm-range, the measurement of sprays in the near nozzle region is extremely challenging. Therefore, the processes of the primary breakup are not fully understood yet, although these processes are very important for simulation of spray atomization. One important property of a spray is the velocity distribution close to the nozzle outlet. With the newly developed Structural Image Velocimetry (SIV) technique it is possible to visualize spray structures in the near nozzle region and track them via cross-correlation algorithms, so that two-dimensional velocity fields of the spray can be derived. The initial SIV technique is improved with a new high-speed setup, allowing to observe also the temporal behavior of the spray velocities during the injection. Within this work, velocities of potential future diesel fuels were measured under engine relevant conditions with a variation of fuel pressure, fuel temperature and gas pressure based on the ECN Spray A conditions. Velocity fields of Oxymethlyenether 3-5 (OME) as an E-Fuel and Hydrogenated Vegetable Oil (HVO) as a Bio-Fuel were measured and compared with Gas-To-Liquid Diesel (GTL) as a reference fuel. For constant fuel pressures, the velocity distribution for OME shows significantly different values than for GTL and HVO, having about 15 % lower values and much lower deceleration behavior in downstream direction. Obviously the OME spray has a weaker air-fuel interaction. This can be attributed to a lower density leading to reduced nozzle outlet velocities and a lower Weber number.

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VL - 3

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JO - SAE Technical Papers

JF - SAE Technical Papers

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T2 - SAE 2020 International Powertrains, Fuels and Lubricants Meeting, PFL 2020

Y2 - 22 September 2020 through 24 September 2020

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