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Experimental research on spray and combustion characteristics of the third generation conical spray

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Abstract

A new generation conical spray system for conventional diesel engines or premixed combustion diesel engines is introduced. By means of oriented impingement method, flexible spray penetration in design is realized. High-speed photograph was used to investigate the spatial distribution characteristics of the new spray for cases of different impingement angles and needle valve opening pressures. The results show that, by applying spray impingement orientation, fuel jets spread along the cone surface as shape of sectors, so the dispersion of jets is increased obviously. Changing on impingement angle leads to variation of penetration, which is critical in homogeneous mixture preparation. Due to the flexibility of spray penetration in design, the spray impingement on liner is avoided in a great extent. The results also indicate that higher needle valve opening pressure results in longer penetration and larger spray angle after impingement. Combustion characteristics of the impinged conical spray were studied in the 1135 type diesel engine. The new impinged conical spray system work smoothly in full load range with better fuel economy and lower emissions of NO x and soot than the original test engine.

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Abbreviations

ATDC:

After Top Dead Center

BTDC:

Before Top Dead Center

BMEP:

Break Mean Effective Pressure

BSFC:

Break Specific Fuel Consumption

CAD:

Crank Angle Degree

NO x :

Nitrogen Oxides

PM:

Particulate Mater

TDC:

Top Dead Center

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Authors and Affiliations

  1. Department of Power Engineering, Dalian University of Technology, China, 116023, Dalian, China

    Feng Li-yan, Long Wu-qiang, Du Bao-guo & Tian Hua

  2. Department of Mechanical System Engineering, Gunma University, 376-8515, Kiryu, Japan

    Obokata Tomio

Authors
  1. Feng Li-yan
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  2. Long Wu-qiang
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  3. Du Bao-guo
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  4. Tian Hua
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  5. Obokata Tomio
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Li-yan, F., Wu-qiang, L., Bao-guo, D. et al. Experimental research on spray and combustion characteristics of the third generation conical spray. J Mar. Sc. Appl. 4, 44–49 (2005). https://doi.org/10.1007/s11804-005-0045-9

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  • DOI: https://doi.org/10.1007/s11804-005-0045-9

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