Effect of steam addition on the combustion, performance and emissions characteristics of an HCCI diesel engine

Yıl 2024, Cilt: 10 Sayı: 3, 710 - 721, 21.05.2024

Mushtaq Rather M. M. Wani

Öz

Although homogeneous charge compression ignition (HCCI) diesel engines are the favored source of power with near zero oxides of nitrogen (NOx) and particulate matter emissions owing to a higher degree of homogeneity and elimination of diffusion phase combustion, the main drawback is the uncontrolled start of combustion along with high CO and unburned hydrocarbon emissions. In the present work, experimental investigations were carried out on a single cylinder diesel engine operating in HCCI combustion mode using external air-fuel mixture preparation. The regulated percentage of steam is added inside the mixing chamber and the effects on the combustion, performance and emission characteristics were reported for various steam injection rates at different brake mean effective pressures. The results obtained show that the brake thermal efficiency was improved to 21.048% with the addition of 20% steam addition and the NOx emissions were also reduced significantly.The emissions of CO and unburned hydrocarbon were found 0.7% and 93 ppmrespectively at the steam addition rate of 20%, however a rapid increase was observed if the steam injection rate was increased further. Overall, the present work shows that by the addition of steam, the CO and unburned hydrocarbon emissions can be reduced significantly along with NOx emissions and also there is a greater potential to control the start of combustion.

Anahtar Kelimeler

Diesel Engine, HCCI, NOx Emissions, Steam Addition, Thermal Characteristics, Unburned Hydrocarbons

Kaynakça

• [1] Pandey S, Chintala V, Ranjit PS. Technical barriers and their solutions for deployment of HCCI engine technologies—a review. Int J Ambient Energy 2021;42:1922–1935. [CrossRef]
• [2] Minh TN, Minh HP, Duy VN. A review of internal combustion engines powered by renewable energy based on ethanol fuel and HCCI technology. AIMS Energy 2022;10:1005–1025. [CrossRef]
• [3] Gowthaman S, Sathiyagnanam AP. Effects of charge temperature and fuel injection on pressure on HCCI engine. Alexandria Engineer J 2016;55:119125. [CrossRef]
• [4] Ithnin AM, Noge H, Abdul Kadir H, Jazair W. An overview of utilizing water-in-diesel emulsion fuel in diesel engine and its potential research study. J Energy Inst 2014;87:273288. [CrossRef]
• [5] Sahin Z, Tuti M, Durgun O. Experimental investigation of the effects of water adding to the intake air on the engine performance and exhaust emissions in a DI automotive diesel engine. Fuel 2014;115:884–895. [CrossRef]
• [6] Tesfa B, Mishra R, Gu F, Ball AD. Water injection effects on the performance and emission characteristics of a CI engine operating with biodiesel. Renew Energy 2012;37:333–344. [CrossRef]
• [7] Mingrui W, Sa NT, Turkson RF, Jinping L, Guanlun G. Water injection for higher engine performance and lower emissions. J Energy Inst 2017;90:285–299. [CrossRef]
• [8] Tauzia X, Maiboom A, Shah SR. Experimental study of inlet manifold water injection on combustion and emissions of an automotive direct injection diesel engine. Energy 2010;35:3628–3639. [CrossRef]
• [9] Gonca G. Investigation of the effects of steam injection on performance and NO emissions of a diesel engine running with ethanol-diesel blend. Energy Conver Manage 2014;77:450–457. [CrossRef]
• [10] Parlak A, Ayhan V, Ust Y, Sahin B, Cesur I, Boru B, et al. New method to reduce NOx emissions of diesel engines: electronically controlled steam injection system. J Energy Inst 2012;16:135–139. [CrossRef]
• [11] Cesur I, Parlak A, Ayhan A, Gonca G, Boru B. The effects of electronic controlled steam injection on spark ignition engine. Appl Therm Engineer 2013;55:61–68. [CrossRef]
• [12] Kokkulunk G, Gonca G, Ayhan V, Cesur I, Parlak A. Theoretical and experimental investigation of diesel engine with steam injection system on performance and emission parameters. Appl Therm Engineer 2013;54:161–170. [CrossRef]
• [13] Goncva G, Sahin B, Ust Y, Parlak A. Determination of the optimum temperatures and mass ratios of steam injected into turbocharged internal combustion engines. J Renew Sustain Energy 2013;5:1–13. [CrossRef]
• [14] Bishnoi D, Kumar KS. Pressure exertion and heat dissipation analysis on uncoated and ceramic (Al2O3, TiO2, and ZrO2) coated braking pads. Mater Today Proc 2023;74:774787. [CrossRef]
• [15] Murthy YVVS, Sastry GYK, Satyanaryana MRS. Experimental investigation of performance and emissions on low-speed diesel engine with dual injection of solar generated steam and pongamia methyl ester. Indian J Sci Technol 2011;4:29–33. [CrossRef]
• [16] Armas O, Ballesteros R, Martos FJ, Agudelo JR. Characterization of light duty diesel engine pollutant emissions using water-emulsified fuel. Fuel 2005;84:1011–1018. [CrossRef]
• [17] Gonca G, Sahin B, Ust Y, Parlak A, Safa A. A comparison of steam injected diesel engine and miller cycled diesel engine by using two zone combustion model. 12th Int Combust Symp 2012;16:115–125.
• [18] Gonca G. Investigation of the effects of steam injection into the supercharged diesel engine with running miller cycle on performance and emissions, PhD Thesis Progress Report; 2012.
• [19] Kumar SK, Muniamuthu S, Mohan A, Amirthalingam P, Anbu Muthuraja M. Effect of charging and discharging process of PCM with paraffin and Al2O3 additive subjected to three point temperature locations. J Ecol Engineer 2022;23:3442. [CrossRef]
• [20] Kumar S, Muniamuthu S, Tharanisrisakthi BT. An investigation to estimate the maximum yielding capability of power for mini venturi wind turbine. Ecol Engineer Environ Technol 2022;23:72–78. [CrossRef]
• [21] Muniamuthu S, Kumar KS, Raja K, Rupesh PL. Dynamic characterization of hybrid composite based on flax/E-glass epoxy composite plates. Mater Today Proc 2022;59:1786–1791. [CrossRef]
• [22] Ferguson CR, Kirkpatrick AT. Internal Combustion Engines Applied Thermosciences. 2nd ed. New York: John Wiley & Sons Inc; 2001.
• [23] Hohenberg G. Advanced approaches for heat transfer calculations. SAE Technical Paper 790825; 1979. [CrossRef]
• [24] Sitkei G. Kraftstoffaufbereitung und Verbrennung bei Dieselmotoren. Berlin: Springer Verlag; 1964. [CrossRef]
• [25] Heywood JB. Internal Combustion Engine Fundamentals. New York: McGraw-Hill Inc.; 1998.
• [26] Olinkara C, Borman G. A computer program for calculating properties of equilibrium combustion products with some applications to engines. SAE Technical Paper 750468; 1975. [CrossRef]
• [27] Lin CY, Wang KH. Effects of diesel engine speed and water content on emission characteristics of three-phase emulsions. J Environ Sci Health A 2004;39:1345–1359. [CrossRef]
• [28] Hadia F, Wadhah S, Ammar H, Ahmed O. Investigation of combined effects of compression ratio and steam injection on performance, combustion and emission characteristics of HCCI engine. Case Stud Therm Engineer 2017;10:262–271. [CrossRef]
• [29] Park JW, Huh KY, Park KH. Experimental study on the combustion characteristics of emulsified diesel in a rapid compression and expansion machine. Proc Inst Mech Engineer Part D J Automob Engineer 2000;214:579–586. [CrossRef]
• [30] Kumar S, Babu JM, Venu H. Performance, combustion and emission characteristics of a single-cylinder DI diesel engine fuelled with lotus biodiesel-diesel-n-butanol blends. Int J Ambient Energy 2022;43:79417951.
• [31] Kumar S, Babu JM, Venu H, Muthuraja A. Waste plastic as a source of biofuel for stationary diesel engine: A critical review. Int J Ambient Energy 2022;43:85778591.
• [32] Babu JM, Chandra MS, Ganesh RC, Jayaprakash P, Kumar S, Nagappan M. Experimental evaluation of direct injection diesel engine performance and emissions with acacia biodiesel. Int J Ambient Energy 2022;43:70387045. [CrossRef]
• [33] Karthickeyan NK, Arun S, Mohan GS, Kumar S. Structural analysis of exhaust manifold for 1500 Hp engine. Int J Mech Engineer Technol 2017;8:379–387.
• [34] Gong JS, Fu WB. A study on the effect of more volatile fuel on evaporation and ignition for emulsified oil. Fuel 2001;80:437–445. [CrossRef]
• [35] Rupesh PL, Raja K, Kumar KS, Vijaydharan S, Reddy AMM, Kumar PD. Experimental evaluation of thermal stress on the surface of butterfly specimen through irreversible colour change of thermal paint. Mater Today Proc 2022;59:1768–1775. [CrossRef]
• [36] Vivekananthan V, Vignesh R, Vasanthaseelan S, Joel E, Kumar KS. Concrete bridge crack detection by image processing technique using the improved OTSU method. Mater Today Proc 2022;74:10021007. [CrossRef]
• [37] Arun S, Nagoorvali SK, Kumar KS, Mohan GS. Automation of main bearing bolt and cap loosening machine for automobile crankshaft. Int J Mech Engineer Technol 2017;8:41–49.
• [38] Kumar KS, Palanisamy R, Aravindh S, Mohan GS. Design and analysis of windmill blades for domestic applications. Int J Mech Engineer Technol 2017;8:25–36.
• [39] Kumar KS, Raju DBN, Arulmani J, Amirthalingam P. Design and structural analysis of liquefied cryogenic tank under seismic and operating loading. Int J Mech Engineer Technol 2016;7:345–366.
• [40] Kumar KS, Muniamuthu DS, Arun S, Mohan A. Identification experimental analysis of noise and vibration reduction in windmill gearbox for 5MW wind turbine. Int J Mech Engineer Technol 2016;7:76–85.
• [41] Muniamuthu S, Raju NL, Sathishkumar S, Kumar KS. Investigation on mechanical properties of Al 7075-Al2O3 metal matrix composite. Int J Mech Engineer Technol 2016;7:474–482.