Combustion Analysis of an Aviation Compression Ignition Engine

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Combustion Analysis of an Aviation Compression Ignition Engine Burning Pentanol-Kerosene Blends under Different Injection Timings Longfei Chen, Mohsin Raza, and Jianhua Xiao Energy Fuels, Just Accepted Manuscript • DOI: 10.1021/acs.energyfuels.7b00813 • Publication Date (Web): 07 Aug 2017 Downloaded from http://pubs.acs.org on August 13, 2017

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Energy & Fuels

1

Combustion Analysis of an Aviation Compression

2

Ignition Engine Burning Pentanol-Kerosene Blends

3

under Different Injection Timings Longfei Chena

4 a

5

School of Energy and Power Engineering, Energy and Environment International Center,

6 7

Beihang University, Beijing, China, 100191 b

State Key Laboratory of Automotive Safety and Energy, Tsinghua University, Beijing 100084,

8

9

, Mohsin Razaa, * , Jianhua Xiaob

China

ABSTRACT

10

The resurgence of aviation heavy fuel engines (HFEs) and the single fuel concept policy make it

11

important to investigate the application of kerosene in aviation compression ignition engines.

12

From the experience of automotive engines, biofuels, in particular higher alcohols may offer

13

better combustion and emission characteristics for HFEs. In this study, the combustion

14

performance was analyzed in a commercial aircraft compression ignition engine burning diesel

15

as a baseline fuel and Chinese aviation kerosene fuel (RP-3) blended with pentanol (so-called

16

second generation biofuel) with different blending ratios. The injection timing as the most

17

critical operational parameter was swept from 17 to 23oCA BTDC under constant engine speed

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(1600 rpm) and fixed injection pressure (60 MPa). The indicated thermal efficiency of kerosene-

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pentanol blend (K60P40) was higher than all other test fuels, and the advancement in injection

20

timing caused increase in combustion temperature which improved the both indicated thermal

21

efficiency and combustion efficiency. The combustion duration was shorter for kerosene-

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pentanol blends (K60P40 and K80P20) than diesel, however, the combustion duration

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considerably increased with advancing injection timings for all the test fuels. Kerosene and its

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pentanol blends showed longer ignition delay compared to baseline diesel due to their lower

25

cetane number. The indicated specific fuel consumption (ISFC) of K80P20 and K60P40 were

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demonstrated lower than baseline diesel. This work demonstrated the great potential of kerosene-

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pentanol fuel blends in aircraft diesel engines without significant modifications.

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1. INTRODUCTION

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Aircraft diesel engines have existed since the late 1920s and 1930s, but never as widely used

30

as gasoline-fueled or turboprop engines. The ever-rising cost, safety concerns and the scarceness

31

in remote area of aviation gasoline have triggered a resurgence in heavy fuel engine (HFE)

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production recently. In addition, automotive diesel technologies have improved significantly,

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enabling high power-to-weight ratios for aviation applications. The North Atlantic Treaty

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Organization (NATO) nations have established a single fuel concept (SFC) policy that unified all

35

petroleum fuels to a single kerosene (JP-8) for military, and many researchers have applied JP-8

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to conventional compression ignition engines.1-4 Yet the literature on aviation internal combustion

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engines are significantly less than that on vehicular internal combustion engines in terms of combustion

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and emissions characteristics.5-21

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Compared to diesel, kerosene has lower cetane number which causes a longer ignition delay22,

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and provides a longer time for air-fuel mixing prior to combustion, and hence could lead to more

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complete combustion. The lower heating value (LHV) of kerosene fuel (LHV=43.34 MJ/kg) is

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greater than those of diesel (LHV=42.68 MJ/kg) and gasoline (LHV=42.7 MJ/kg)23 which leads

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to lower volumetric specific fuel consumption when using kerosene, and the very low cloud

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point of kerosene makes it suitable for cold weather conditions.4 Patil and Thipse compared the

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effects of different kerosene-diesel blends on diesel engine performance and found little change

46

in thermal efficiency with kerosene addition.2 Aydin et al. examined the impact of kerosene and

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biodiesel blends on combustion and engine performance, and found that BK20 (20% kerosene

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and 80% biodiesel) blend exhibited an increase in engine power and a lower fuel consumption

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compared with neat biodiesel.3

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Alternative biofuels have been recognized as a promising means of reducing the dependence

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on petroleum-derived fuels and have thus been promoted greatly.1-3 In particular, alcohols have

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been widely used in internal combustion engines due to their preferable physiochemical

53

properties such as lower viscosity, high evaporative cooling, and high laminar flame propagation

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speed.24-26 Gasoline engines fueled with alcohols have demonstrated these benefits thanks to

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their higher octane number and evaporative cooling effects (particularly in GDI engines).27-30

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However, the application of alcohols in diesel engines have encountered some difficulties due to

57

the lower cetane number, longer ignition delay, and higher latent heat of vaporization of

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alcohols.31 Ongoing research has focused more on the usage of short-chain alcohols (e.g.

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methanol and ethanol) as a blending agent in a diesel fuel32-34 and found some drawbacks such as

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lower heat value and poor miscibility. Among the short-chain alcohols (C1-C3), ethanol is

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studied the most in both SI35-38 and CI engines.39-43 In contrast, long-chain alcohols such as

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butanol (C4) and pentanol (C5) fuels have been investigated to a lesser extent so far. Pentanol

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(C5) is a so-called second generation biofuel which can be manufactured from numerous kinds

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of biomass including non-edible sources and waste matter. It has advantages over butanol (C4)

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and other short-chain alcohols (C1-C3). In particular, the higher energy density, higher cetane

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number of pentanol and its better miscibility with diesel fuel make it a more suitable alcohol

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candidate. A recent investigation has demonstrated that pentanol blends (up to 30% by volume)

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can be used without having stability or solubility issues.44 Other studies of diesel-pentanol blends

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have indicated improved combustion characteristics and better engine performance.45-47

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Although a great number of alcohol-diesel studies (primarily on automotive engines) exist in the

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literature, few studies focused on alcohol-kerosene blends and the literature on pentanol-

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kerosene blends was even scarcer. The ever rising importance of single fuel concept (SFC)

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policy and the significant difference between diesel and kerosene in terms of physiochemical

74

characteristics warrants the investigation of pentanol-kerosene usage on aircraft heavy fuel

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engines (HFE).

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For a diesel engine, fuel injection timing is probably the most critical parameter influencing

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the combustion, engine performance and exhaust emissions.26-32 Varying injection timing

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changes the in-cylinder air motion, which consequently affects ignition delay (ID). Advancing or

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retarding injection timing also changes the in-cylinder temperature, cylinder pressure, indicated

80

thermal efficiency, combustion efficiency, and fuel consumption. Therefore, it is desirable to

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study the effect of injection timing on an aviation diesel engine fueled with diesel, kerosene, and

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pentanol blends to make up for the gaps in the literature. The objective of this study was to

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assess the suitability of pentanol-kerosene blends in an aviation compression ignition engine and

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to explore the effect of injection timing on combustion characteristics for kerosene and higher

85

alcohol blends.

86

2. EXPERIMENTAL SETUP

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2.1. Test engine and measurement instruments. The experiments were conducted on an in-

88

line four-cylinder aircraft diesel engine with direct fuel injection delivered by a common rail.

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The injection parameters, such as injection timing and injection pressure were controlled by an

90

electronic control unit (ECU). Detailed engine specifications are shown in Table 1.

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Table 1. Specifications of the test engine Parameter

Type or value

Injection system

Common rail

Injector

7 holes, 0.136 mm diameter

Injection pressure

40~180 MPa

Compression ratio

16.7

Stroke

92 mm

Number of valves

16

Displacement

1991 cm3

Bore

83 mm

92 93

Figure 1 shows the schematic of the test rig. In this study, an AVL GH14P cylinder pressure

94

transducer recorded the cylinder pressure with a resolution of 0.5oCA. Combustion performance

95

parameters such as combustion duration, ignition delay, and heat release rate were calculated

96

based on ensemble average values of in-cylinder pressure data for 250 consecutive cycles. Fuel

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consumption was measured using a FCM-D digital fuel meter at the resolution of 0.1 g.

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Figure 1. Schematic diagram of the experimental rig.

100

Different types of thermocouples were employed to measure the temperatures of engine oil,

101

intake air and exhaust. An air flow meter, inductive proximity speed sensor, and crankshaft angle

102

sensor were utilized to measure the intake flow rate, engine speed, and crankshaft position

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respectively. The AVL CEB-II exhaust gas analyzer was used to measure the HC and CO

104

emissions. The uncertainties of calculated parameters and accuracies in measurements are

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presented in Table 2.

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Table 2. Uncertainties of calculated parameters and accuracies in measurements Measurements

Accuracy

Engine load (MPa)

±0.5

Engine speed (rpm)

±0.5

Intake temperature (K)

±1.0

In-cylinder pressure (kPa)

±0.5

Crank angle (CAD)

±0.1

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Fuel flow meter (m3/h)

±1.0

Air flow meter (m3/h)

±1.0

Intake pressure (kPa)

±0.1

IMEP

±0.6

Gaseous analyzer

±0.5

Calculated parameters

Uncertainties (%)

Combustion efficiency (%)

±0.2

Indicated thermal efficiency (%)

±0.2

ISFC

±1.0

107 108

2.2. Test conditions. Five different injection timings (17, 19, 20, 21, 23oCA BTDC) were

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tested and fuel injection pressure, engine load, and engine speed remained constant at 60 MPa,

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0.6 MPa, and 1600 rpm, respectively. Pilot injection strategies were implemented in this study.

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The dwell of main and pilot injection remained fixed at 16oCA and the main injection duration

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was varied to achieve the target load. The engine was run fully warm (taken as an oil and coolant

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temperature of 84oC) to ensure steady state conditions and then the measurements were recorded.

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The tests were repeated three times for each condition, and ensemble average values were

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calculated and adopted.

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2.3. Properties of test fuels and its blends. The test was conducted using diesel, kerosene,

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and pentanol as base fuels. The properties of all test fuels are listed in Table 3. Neat diesel was

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used as a baseline fuel. Compared with diesel, kerosene has a lower cetane number, fewer carbon

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atoms per molecule, lower viscosity and a smaller distillation temperature range.48 Furthermore,

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its low viscosity promotes atomization upon injection. Two fuel blends were blended at ratios of

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80% kerosene and 20% pentanol (K80P20), 60% kerosene and 40% pentanol (K60P40) on a

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volumetric basis. It can be clearly observed that higher levels of pentanol increases the viscosity

123

and oxygen content of the kerosene-pentanol blends.

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Due to the difference in LHVs of kerosene, diesel and oxygenated fuel blends, equation 1 and

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2 were used to modified the consumption level of kerosene and oxygenate fuel blends to match

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the LHV of diesel for a fair comparison.

127

m   =   × LHV  /LHV

(1)

128

where m′   is the corrected fuel dosage to reflect the same total energy with diesel,

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mkerosene is actual fuel dosage, LHVkerosene and LHVdiesel are the lower heat value of kerosene and

130

diesel fuel respectively. m′  =  × (V × 

 

× LHV

  (2)

+V$ %  × $ %  × LHV$ %  )/(V × 

 

+V$ %  × $ %  )/LHV 131

where m′  is the corrected fuel usage; mmeasure is the measured fuel usage; Vkerosene and Vpentanol are the

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volume proportions of kerosene and pentanol; ρkerosene and ρpentanol are the densities of kerosene and

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pentanol; LHVkerosene and LHVpentanol are the LHV of kerosene and pure pentanol. All the indicated

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specific fuel consumptions (ISFC) of the fuel blends were modified correspondingly.

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Table 3. Test fuel properties

Test Fuels

Viscosity at 20oC (mm2/s)

Density at 20oC (kg/m3)

Surface tension at 20oC (103 Nm-1)

Latent heating at 25oC (kJ/kg)

Cetane Number

Low heating value (MJ/kg)

Oxygen content (wt.%)

Boiling point (oC)

Diesel

4.127

830

27.50

270

56.50

42.68

0.00

Kerosene (RP3)

1.28

790

23.60

--

42.00

43.43

0.00

IBP=179.8 FBP=359.7 T10=223.4 T50=266.8 T90=321.3 IBP=176.7 FBP=240 T10=172.8 T50=194.9

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T90=224.4

Pentanol

2.89

815

24.7

308

20-25

35.06

18.18

138

K80P20

1.602

803

23.82

--

37.638.6a

41.731

3.636

T10= 358.2b T50= 425.6c T90=456.3d

K60P40

1.924

806

24.04

--

33.235.2a

40.0446

7.272

T10= 333.4e T50= 342.6f T90=381.3g

136

Data are acquired from Reference.47 ; a Estimated by Reference.49, 50;

b-g

137

based evaporation model.51; IBP=Initial boiling point; FBP=Final boiling point

138

3. RESULTS AND DISCUSSION

Predicted by UNIFAC

139

3.1. In-cylinder pressure and heat release rate.

140

Heat release rate (HRR) is defined as the rate at which the chemical energy of the fuel is

141

released by the combustion energy. The heat release rate (HRR) and in-cylinder pressure traces

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for all the test fuels were presented in Figure 2a-d. The curves of all the test fuels show two-

143

phase combustion process at the main combustion period. With increase in pentanol blend, the

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HRR shifts from two stage heat release (HR) to single stage heat release (HR). Heat release rate

145

(HRR) during the second-stage combustion decreased with advancing injection timings and it

146

was calculated using Eq. 3.

147 148

dQ =

k 1 pdV + Vdp k -1 k -1

(3)

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where k denotes the heat ratio; V represents the in-cylinder volume; and p indicates the cylinder

150

pressure.

151

(a)

(b)

152 153

(c)

(d)

154

Figure 2. Comparisons of HRR and the in-cylinder pressure of the diesel, kerosene, K8020 and

155

K60P40 under five different injection timings at 1600 rpm.

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The profile of diesel shows a typical spray-diffusion combustion which is primarily affected by

157

the physiochemical properties of the fuel. The quality of vaporization and atomization of fuel is

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controlled by physical properties such as volatility‚ surface tension and density. However, the

159

chemical reactivity of the fuel mainly subjects to the chemical properties. Compared to diesel,

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kerosene-pentanol blends (K80P20 and K60P40) demonstrated lower in-cylinder pressure and

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higher heat release rate (HHR) on early injection timings. Kerosene displayed longer ignition

162

delay and shorter combustion duration as compared to diesel because of its lower cetane

163

number.48, 52 Bergstrand also reported that the kerosene showed a longer ignition delay due to the

164

lower cetane number which provides longer mixing time for air-fuel mixture prior to the start of

165

combustion.22

166

3.2. Maximum heat release rate. The results of maximum heat release rate (MHRR) can be

167

seen in Figure 3. The baseline diesel exhibited the highest first-stage MHRR, while K60P40

168

showed the lowest first-stage MHRR as injection timing advanced (in line with the fuel cetane

169

number). Furthermore, blending pentanol further reduces the fuel cetane number. Consequently,

170

the kerosene-pentanol blends showed even lower maximum heat release rate (MHRR) and longer

171

ignition delay in the pilot combustion process compared with diesel and kerosene.

172

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Figure 3. Comparison of first-stage (pilot) and second-stage (main) maximum heat release rate

174

(MHRR) for four fuels as injection timing is advanced.

175

Figure 3 also shows the minimal discrepancy of second-stage MHRR with advancing injection

176

timings from 17oCA BTDC to 23oCA BTDC for all the tested fuels. However, K80P20 and

177

K60P40 showed higher second-stage maximum heat release rate (MHRR) in contrast to kerosene

178

and baseline diesel, which is attributed to the larger fraction of premixed combustion of kerosene

179

blended fuels and their longer ignition delay. Besides, kerosene and its pentanol blends had

180

improved atomization due to their lower viscosity and surface tension, which would enhance the

181

pre-mixing of more fuel and led to the higher MHRR.

182 183

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3.3. Combustion duration, ignition delay, and CA50. Combustion duration, ignition delay and angle of 50% mass-fraction burned (CA50) are shown in Figure 4.

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Figure 4. Comparisons of ignition delay, combustion duration, and CA50 between the diesel,

186

kerosene, K80P20 and K60P40 fuel blends at 0.6 MPa IMEP.

187

The combustion duration has been defined as the CA10-CA90 duration. It can clearly be seen

188

that compared to diesel, kerosene shows shorter combustion duration due to its higher volatility

189

of fuel and smaller diffusion combustion phase which caused by the increased burning of premix

190

portion.53 Adding pentanol into kerosene reduces the combustion duration further which can be

191

attributed to the better volatility of these fuel blends. It can be observed that the advancement in

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injection timing increased the combustion duration for all the test fuels which is due to the more

193

consumption amount of fuel at the most advanced injection timing (23oCA BTDC).

194

Ignition delay has been defined as the duration between CA10 and the start of main injection

195

(SOI) (note the pilot-main separation was fixed here). It is well known that the ignition

196

characteristics of the fuel affect the ignition delay. The ignition delay is one of the most

197

influential factors for determining the combustion characteristics.54 The ignition quality of a fuel

198

is defined by its cetane number. It is well established that lower cetane number would lead to

199

shorter combustion duration and longer ignition delay. Diesel showed shorter ignition delay with

200

advancing injection timing which is due to the higher cetane number of diesel. As would be

201

expected, kerosene presented longer ignition delay as a result of its lower cetane number

202

compared with diesel, which caused locally leaner air–fuel mixture formation and burned it with

203

the lower combustion rate.55, 56 Simple surrogate fuels with n-decane being primary component

204

can be used to model the kerosene using validated detailed kinetic reaction mechanisms.57, 58

205

Since diesel has hydrocarbons with higher molecular weights than kerosene, n-hexadecane is

206

used as a primary component for diesel surrogate fuel from the perspective of chemical kinetics

207

and fundamental combustion properties.57, 59 It is well established that longer hydrocarbons tend

208

to have lower activation energy for thermal decomposition reaction, and thus shorter ignition

209

delay. This could explain why kerosene exhibited longer ignition delay than diesel from the

210

perspective of chemical kinetics. In the case of K80P20 and K60P40, pentanol addition extended

211

the ignition delay compared to baseline diesel due to the lower cetane number of pentanol.

212

Mass fraction burned (MFB) of a fuel is also an important constraint to indicate the

213

combustion process in a compression ignition engine. The angle of 50% mass-fraction burned

214

(CA50) is significant because it influences the fuel conversion efficiency of an engine. The

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quicker 50% of energy discharge through the power stroke reduces the chances of heat lost

216

during the engine cycle which contribute to a greater thermal efficiency.60 Ignition delay and

217

CA50 reduced in line with the advancing injection timings for all of the test fuels as shown in

218

Figure 4. Fuel properties including cetane number, atomization, and vaporization are considered

219

to have an impact on mass fraction burned.61 Both kerosene-pentanol blended fuels (K80P20 and

220

K60P40) resulted in lower CA50 than diesel and kerosene, which was attributed to the better

221

mixing of fuel blends prior to the combustion.

222

3.4. Indicated thermal efficiency. Figure 5 displays the indicated thermal efficiency (ITE) for

223

all the test fuels on sweeping injection timings. The value of indicated thermal efficiency (ITE)

224

was calculated using Eq. 4.

225

ηi = Wi / (mf × Huf )

226

(4)

227

where Wi is the indicated work, Huf, the LHV of the fuel, and mf the fuel consumed per cycle.

228

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229 230

Figure 5. Comparison of indicated thermal efficiency between diesel, kerosene, and kerosene-

231

pentanol (K80P20 and K60P40) fuel blends as injection timing is advanced at 1600 rpm, 0.6

232

MPa IMEP.

233

The noise from diesel engines is mainly attributed to the combustion noise, which originates

234

from high pressure rise rates during the initial rapid combustion.62 Higher pressure rise in the

235

cylinder caused oscillation and the amplitude of oscillation varied with the fuel injection rate and

236

injection delay period. The test fuels showed high peak of pressure rise which obviously

237

contribute in the elevated combustion noise (see in Figure 2). Previous studies conducted by

238

Carlucci et al.63 and Bhat et al.64 reported that the advance in injection timing increased the

239

combustion noise which attributed to the increase in combustion pressure level. Compared to

240

baseline diesel, K80P20 and K60P40 blends showed higher heat release rate (HHR) which led to

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241

relatively higher adiabatic temperature in the combustion chamber. During the combustion

242

process, higher HRR increased the noise level, pressure rise rate, and structural vibration as

243

well.65 At the same time, however, a higher thermal efficiency and a lower specific fuel

244

consumption were observed (see in Figure 5 and Figure 7). In other words, there is a trade-off

245

relationship between combustion noise and fuel economy. Previous studies suggest an inverse

246

relationship between combustion noise and fuel consumption, and found that the combustion

247

noise could be controlled by avoiding too much fuel being burnt at the end of the ignition delay

248

period.66

249

Indicated thermal efficiency (ITE) increased with advancing injection timings for diesel,

250

kerosene, and kerosene-pentanol blends then decreased at 23oCA BTDC (the most advanced

251

injection timing) because of longer combustion duration (see Figure 4). Furthermore, 23 BTDC

252

exhibited the least ignition delay and thus the relative poor mixture preparation and protracted

253

combustion result in a slight drop in thermal efficiency. Compared to diesel, K80P20 and

254

K60P40 showed higher thermal efficiency which attributed to the more efficient combustion

255

owing to advance combustion phase and shorter combustion duration.47 The ITE is basically the

256

inverse of the product of ISFC and LHV of the fuel, and the reduction in ISFC implies an

257

increase in overall engine efficiency.48, 67

258

The advance in injection timing increased the combustion temperature which improved the

259

both indicated thermal efficiency and combustion efficiency (see Figure 5 and Figure 6).

260

Kerosene showed higher thermal efficiency than diesel. The primary reason is that the

261

combustion efficiency of kerosene is higher than that of diesel due to its longer combustion

262

duration which can be seen in Figure 6. Overall, K60P40 showed the highest ITEs among all the

263

test fuels, which can be attributed to its longer combustion duration and higher heat release rate.

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264

These findings are similar with the results of Bayindir, which reported that engine efficiency

265

increased with the kerosene addition.68

266

3.5. Combustion efficiency. Combustion efficiency is the ability of the fuel to burn

267

completely in the combustion process. The combustion efficiency (ηc) was calculated using eq 5.

268

ηc =1− (mco× Huco + mHC × HuHC ) / (mf × Huf )

(5)

269

where mCO and mTHC are the mass of the CO & HC respectively; HuCO & HuHC are the LHVs of

270

CO and HC respectively; mf represents the fuel consumed per cycle and Huf denotes the LHV of

271

the fuel.

272 273

Figure 6. Comparison of combustion efficiency between diesel, kerosene, and kerosene-pentanol

274

(K80P20 and K60P40) fuel blends as injection timing is advanced at 1600 rpm, 0.6 MPa IMEP.

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275

Figure 6 illustrates the comparison of kerosene, kerosene-pentanol fuel blends (K80P20 and

276

K60P40) to a baseline diesel fuel on sweeping injection timings from 17oCA BTDC to 23oCA

277

BTDC. On advancing injection timings, the baseline diesel, kerosene, K80P20, and K60P40

278

show increasing combustion efficiency. However, at 23oCA BTDC a slight decline is observed

279

for all of the test fuels because of protracted combustion duration which reduces the in-cylinder

280

combustion temperature. The combustion efficiency is greatly dependent on the in-cylinder

281

combustion temperature.69 Kerosene showed a higher combustion efficiency compared to neat

282

diesel, in line with its shorter combustion duration. Kerosene has a smaller surface tension, lower

283

viscosity and smaller density compared to diesel which will lead to faster spray breakup and

284

hence an increase in combustion efficiency.47,

285

combustion initiation point, and the variation of combustion phase has a great impact on the

286

work capacity of the test fuels, leading to a great change of combustion efficiency. The

287

difference of burning velocity and constant volume combustion degree between kerosene and

288

diesel might cause the difference of combustion efficiency as well55.

289 290

70, 71

The injection timing determines the

3.6. Indicated specific fuel consumption. Figure 7 shows the indicated specific fuel consumption (ISFC) as injection timing is advanced for diesel, kerosene, K80P20, and K60P40.

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291 292

Figure 7. Comparison of indicated fuel consumption between diesel, kerosene, and kerosene-

293

pentanol (K80P20 and K60P40) fuel blends as injection timing is advanced at 1600 rpm, 0.6

294

MPa IMEP.

295

As would be expected, diesel, kerosene, K80P20, and K60P40 follow the reverse trends as

296

shown in Figure 5. The lowest ISFC was found at 21oCA BTDC for all the test fuels as

297

compared to the other injection timings. It may be attributed to more complete combustion of all

298

the test fuels at the specific injection timing (Figure 6). In particular, the ISFC was 200, 197.7,

299

198.2 and 193 g/kWh for diesel, kerosene, K80P20 and K60P40, respectively, at 21oCA BTDC.

300

In general, compared to diesel, kerosene-pentanol blends showed a lower ISFC that could be

301

associated to the higher ITE which also increased with advancement in injection timings.61

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Energy & Fuels

302

Kerosene shows a lower ISFC than diesel because of the higher LHV of kerosene. K80P20 leads

303

to a higher ISFC than kerosene, due to the smaller energy content of pentanol and K60P40 had

304

the lowest ISFC amongst all of the test fuels, which shows that the advantage of advanced

305

injection timing dominates compared to the effect of pentanol addition.

306

4. CONCLUSION

307

Kerosene and pentanol fuels are potential alternatives to aircraft compression ignition engines.

308

A four-cylinder aircraft diesel engine was run on diesel, kerosene, and kerosene-pentanol blends

309

prepared on a volume basis with 80% kerosene and 20% pentanol (K80P20) and 60% kerosene

310

and 40% pentanol (K60P40). The combustion characteristics and engine performance of all the

311

test fuel were compared to a baseline diesel under varying injection timings. Overall, kerosene

312

can be considered as a suitable drop-in fuel for a compression-ignition engine without any

313

significant modifications due to its preferable physiochemical properties, such as cetane number,

314

surface tension, and viscosity. Pentanol addition prolonged the ignition delay of kerosene-

315

pentanol fuel blends and reduced the combustion duration compared to the baseline diesel.

316

Kerosene-pentanol fuel blends exhibited better indicated thermal efficiency (ITE) and reduced

317

fuel consumption under all the test injection timings compared with diesel. In general, advancing

318

injection timing reduced the ignition delay, yet increased the total combustion duration.

319

AUTHOR INFORMATION

320

Corresponding Author

321

*E-mail: [email protected]; [email protected]

322

ORCID

323

Longfei Chen: 0000-0002-0787-6967

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324

Mohsin Raza: 0000-0001-7384-3015

325

Notes

326

The authors declare no competing financial interest.

327

ACKNOWLEDGEMENT

328

This study was funded by National Natural Science Foundation of China (91641119 and

329

51306011).

330

NOMENCLATURE

331

Abbreviations

332

SOI = start of injection

333

MPRR = maximum pressure rise rate

334

CO = carbon monoxide

335

THC = total hydrocarbon

336

CA BTDC = crank angle before top dead center

337

IMEP = indicated mean effective pressure

338

ITE = indicated thermal efficiency

339

HRR = heat release rate

340

NOx = nitrogen oxides

341

ECU = electronic control unit

342

ISFC = indicated specific fuel consumption

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Energy & Fuels

343

LHV = latent heat of vaporization

344

GDI = gasoline direct injection

345

ICEs = internal combustion engines

346

IBP=Initial boiling point

347

FBP=Final boiling point

348

HR=Heat Release

349

MFB =Mass fraction burned

350 351 352 353 354 355 356 357 358 359 360 361 362 363 364 365 366 367 368 369 370 371 372 373 374

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