Sage Journals: Discover world-class research

Abstract

The effective density and mixing state of particles emitted from a natural gas–diesel dual fuel engine are investigated. Measurements were conducted at three different fuel compositions including 100% diesel fuel (0% NG), 75% diesel–25% natural gas (25% NG) and 50% diesel–50% NG (50% NG). The particle effective density was measured using a differential mobility analyzer in series with a centrifugal particle mass analyzer. A catalytic stripper at 350 °C was employed upstream of the centrifugal particle mass analyzer in order to remove the semi-volatile material from the solid particles to measure the effective density of non-volatile particles as well as the particle mixing state. A scanning mobility particle sizer was used to measure the particle size distribution. The particle mass concentration was also measured using several techniques including cavity-attenuated phase-shift particulate matter single-scattering albedo, laser-induced incandescence, thermal-optical analysis, photoacoustic spectroscopy, and integrated particle size distribution. The semi-volatile number and mass fractions are found to be lower than 15%. The effective density functions of particles at 0% and 25% NG are within 6% of each other; however, the effective density values of particles at 50% NG are lower than those of the 0% NG by up to 35%. The mass-mobility exponent varies in the range of 2.42–2.51 and 2.38–2.54 for undenuded and denuded particles, respectively. For the mass concentration measurements, photoacoustic spectroscopy agrees with thermal-optical analysis within 5%, while all the other techniques measure up to 50% deviations relative to thermal-optical analysis.

Keywords

Effective density function dual fuel engine laser-induced incandescence cavity extinction with total scattering photoacoustic spectroscopy thermal-optical analysis

Get full access to this article

View all access options for this article.

References

Oberdörster

Sharp

Atudorei

Elder

Gelein

Kreyling

, et al. Translocation of inhaled ultrafine particles to the brain. Inhal Toxicol 2004; 16(6–7): 437–445.

Jacobson

MZ.

Strong radiative heating due to the mixing state of black carbon in atmospheric aerosols. Nature 2001; 409: 695–697.

Bond

Doherty

Fahey

Forster

Berntsen

DeAngelo

, et al. Bounding the role of black carbon in the climate system: a scientific assessment. J Geophys Res 2013; 118: 5380–5552.

Weaver

Turner

SH.

Dual fuel natural gas/diesel engines: technology, performance, and emissions. SAE paper 940548, 1994.

Thipse

Kavathekar

Rairikar

Tyagi

Marathe

NV.

Development of environment friendly diesel-CNG dual fuel engine for heavy duty vehicle application in India. SAE paper 2013-26-0015, 2013.

Karim

GA.

Dual-fuel diesel engines. Boca Raton, FL: CRC Press, Taylor & Francis Group, 2015.

Kulkarni

Measurement of transport properties of aerosolized nanomaterials. J Aerosol Sci 2015; 90: 169–181.

Scheckman

McMurry

PH.

Deposition of silica agglomerates in a cast of human lung airways: enhancement relative to spheres of equal mobility and aerodynamic diameter. J Aerosol Sci 2011; 42: 508–516.

Eggersdorfer

Gröhn

Sorensen

McMurry

Pratsinis

SE.

Mass-mobility characterization of flame-made ZrO2 aerosols: primary particle diameter and extent of aggregation. J Colloid Interf Sci 2012; 387(1): 12–23.

10.

Sorensen

CM.

The mobility of fractal aggregates: a review. Aerosol Sci Tech 2011; 45(7): 765–779.

11.

McMurray

Wang

Park

Ehara

The relationship between mass and mobility for atmospheric particles: a new technique for measuring particle density. Aerosol Sci Tech 2002; 36(2): 227–238.

12.

Park

Cao

Kittelson

McMurry

PH.

Relationship between particle mass and mobility for diesel exhaust particles. Environ Sci Technol 2003; 37(3): 577–583.

13.

Liu

Vasys

Dettmann

Schauer

Kittelson

Swanson

Comparison of strategies for the measurement of mass emissions from diesel engines emitting ultra-low levels of particulate matter. Aerosol Sci Tech 2009; 43(11): 1142–1152.

14.

Quiros

Lee

Sardar

Wang

, et al. Particle effective density and mass during steady-state operation of GDI, PFI, and diesel passenger cars. J Aerosol Sci 2015; 83: 39–54.

15.

Code of Federal Regulations. Title 40, Part 86. Washington, DC: U.S. Government Printing Office, 2011.

16.

Code of Federal Regulations. Title 40, Part1066. Washington, DC: U.S. Government Printing Office, 2012.

17.

Zhang

Sardar

Chen

Dzhema

Huang

S-M

, et al. Evaluation of gravimetric method to measure light-duty vehicle particulate matter emissions at levels below one milligram per mile (1 mg/mile). SAE paper 2014-01-1571, 2014.

18.

Xue

Johnson

Durbin

Villela

Pham

, et al. Determination of suspended exhaust PM mass for light-duty vehicles. SAE paper 2014-01-1594, 2014.

19.

Swanson

Kittelson

Pui

Watts

Alternatives to the gravimetric method for quantification of diesel particulate matter near the lower level of detection. J Air Waste Manage 2010; 60(10): 1177–1191.

20.

Maricq

The effective density and fractal dimension of soot particles from premixed flames and motor vehicle exhaust. J Aerosol Sci 2004; 35(10): 1251–1274.

21.

Olfert

Symonds

JPR

Collings

The effective density and fractal dimension of particles emitted from a light-duty diesel vehicle with a diesel oxidation catalyst. J Aerosol Sci 2007; 38(1): 69–82.

22.

Graves

Olfert

Patychuk

Dastanpour

Rogak

Characterization of particulate matter morphology and volatility from a compression-ignition natural-gas direct-injection engine. Aerosol Sci Tech 2015; 49(8): 589–598.

23.

Guo

Neill

Liko

. An experimental investigation on the combustion and emissions performance of a natural gas—diesel dual fuel engine at low and medium loads. In: Proceedings of the ASME 2015 Internal Combustion Engine Division Fall technical conference, Houston, TX, 8–11 November 2015, paper no. ICEF2015–1041, pp. V001T03A005. New York: ASME.

24.

Chase

Duszkiewicz

Richert

JFO

Lewis

Maricq

PM measurement artifact: organic vapor deposition on different filter media. SAE paper 2004-01-0967, 2004.

25.

Maricq

Chase

RE.

Measuring particulate mass emissions with the electrical low pressure impactor. Aerosol Sci Tech 2006; 40(1): 68–79.

26.

Retama

Baumgardner

Raga

McMeeking

Walker

JW.

Seasonal and diurnal trends in black carbon properties and co-pollutants in Mexico City. Atmos Chem Phys 2015; 15: 9693–9709.

27.

Giechaskiel

Maricq

Ntziachristos

Dardiotis

Wang

Axmann

, et al. Review of motor vehicle particulate emissions sampling and measurement: from smoke and filter mass to particle number. J Aerosol Sci 2014; 67: 48–86.

28.

Bond

Bergstrom

RW.

Light absorption by carbonaceous particles: an investigative review. Aerosol Sci Tech 2006; 40(1): 27–67.

29.

Snelling

Smallwood

Liu

Gülder

Bachalo

WD.

A calibration-independent laser-induced incandescence technique for soot measurement by detecting absolute light intensity. Appl Optics 2005; 44(31): 6773–6785.

30.

Michelsen

Schulz

Smallwood

Will

Laser-induced incandescence: particulate diagnostics for combustion, atmospheric, and industrial applications. Prog Energ Combust 2015; 51: 2–48.

31.

Viskup

Alberer

Oppenauer

LD.

Measurement of transient PM emissions in diesel engine. SAE paper 2011-24-0197, 2011.

32.

Onasch

Massoli

Kebabian

Hills

Bacon

Freedman

Single scattering Albedo monitor for airborne particulates, Aerosol Sci Tech 2015; 49(4): 267–279.

33.

Liu

Swanson

Kittelson

Pui

DYH

. Comparison of methods for online measurement of diesel particulate matter. Environ Sci Technol 2012; 46(11): 6127–6133.

34.

Olfert

Collings

New method for particle mass classification—the Couette centrifugal particle mass analyzer. J Aerosol Sci 2005; 36(11): 1338–1352.

35.

Dickau

Olfert

Stettler

Boies

Momenimovahed

Thomson

, et al. Methodology for quantifying the volatile mixing state of an aerosol. Aerosol Sci Tech 2016; 50(8): 759–772.

36.

Turpin

Lim

Species contributions to PM2.5 mass concentrations: revisiting common assumptions for estimating organic mass. Aerosol Sci Tech 2001; 35(1): 602–610.

37.

Lounici

Loubar

Tarabet

Balistrou

Niculescu

Tazerout

Towards improvement of natural gas-diesel dual fuel mode: an experimental investigation on performance and exhaust emissions. Energy 2014; 64(1): 200–211.

38.

Symonds

JPR

Reavell

KSJ

Olfert

Campbell

Swift

SJ.

Diesel soot mass calculation in real-time with a differential mobility spectrometer. J Aerosol Sci 2007; 38(1): 52–68.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.46 MB

Effect of fuel composition on properties of particles emitted from a diesel–natural gas dual fuel engine

Abstract

Keywords

Get full access to this article

References

Supplementary Material