Integrating spent coffee grounds and silver skin as biofuels using torrefaction

Journal Pre-proof Integrating spent coffee grounds and silver skin as biofuels using torrefaction Chao-Heng Tseng, Sih-Yu Jhou, Ying-Chu Chen PII:

S0960-1481(19)31875-0

DOI:

https://doi.org/10.1016/j.renene.2019.12.005

Reference:

RENE 12714

To appear in:

Renewable Energy

Received Date: 11 July 2019 Revised Date:

19 November 2019

Accepted Date: 2 December 2019

Please cite this article as: Tseng C-H, Jhou S-Y, Chen Y-C, Integrating spent coffee grounds and silver skin as biofuels using torrefaction, Renewable Energy (2020), doi: https://doi.org/10.1016/ j.renene.2019.12.005. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.

Author Contribution Statement Chao-Heng Tseng: Resources Sih-Yu Jhou: Formal Analysis, Data Curation. Ying-Chu Chen: Methodology, Writing- Original Draft, WritingReview & Editing, Funding Qcquisition.

1

Integrating Spent Coffee Grounds and Silver Skin as Biofuels Using

2

Torrefaction

3 Chao-Heng Tsenga, Sih-Yu Jhoub, Ying-Chu Chenc,*

4 5

a

6

University of Technology, Taipei City, 106, Taiwan (R.O.C.)

7

b

8

National Taipei University of Technology, Taipei City, 106, Taiwan (R.O.C.)

9

c

10

Professor, Institute of Environmental Engineering and Management, National Taipei

Master of Science, Institute of Environmental Engineering and Management,

Assistant Professor, Department of Civil Engineering, National Taipei University of

Technology, Taipei City, 106, Taiwan (R.O.C.)

11 12

*Corresponding author: Ying-Chu Chen

13 14

E-mail: [email protected]

15

Phone: +886-2-2771-2171#2634

16

Postal address: Department of Civil Engineering, National Taipei University of

17

Technology, 1, Sec. 3, Zhongxiao E. Rd., Taipei 10608 Taiwan, R.O.C.

18 19

Abstract

20

This study used the torrefaction method to innovatively integrate spent coffee

21

grounds (SCG) and silver skin into biofuels. The biofuels were dried, pelletized, and

22

torrefied at 300°C for 3 h. The mass yields and energy yields of the biofuels ranged 1

23

from 41% to 43% and from 52% to 58%, respectively. The high heat value (HHV)

24

range of the biofuels (24.23–27.28 MJ/kg) was higher than that reported in previous

25

studies. The results revealed that an increase in the percentage of silver skin increased

26

the hygroscopicity of the biofuels, which was unfavorable for storage. On average, the

27

weight increased by 0.24 to 0.57 wt% with a 10 wt% increase of silver skin in the

28

biofuels. The biofuels had zero sulfur and chlorine content and thus would be cleaner

29

energy sources than coal. The elemental compositions of the biofuels were similar to

30

that of lignite with 0.063–0.070 H/C and 0.34–0.44 O/C ratios. The sample most

31

similar to coal, based on heating value, element content, proximate analysis results,

32

and combustion characteristics, exhibited 62% similarity. Integrating silver skin with

33

other materials may be unsuitable for biofuels, but it is helpful for reducing the

34

environmental burden of landfilling or incineration.

35 36

Keywords: biofuel; coffee; pelletization; silver skin; spent coffee grounds;

37

torrefaction

38 39 40 41 2

42

1. Introduction

43

Coffee is one of the most popular beverages in the world [1] and the second most

44

traded product after petroleum [2]. More than 9 million tons of coffee beans were

45

produced worldwide in 2016, mostly in the EU, U.S., Brazil, and Japan [3]. In Taiwan,

46

29,248 tons of coffee beans were imported in 2018, an annual increase of 3.7% [4].

47

The coffee brewing process produces a dark brown solid residue with high moisture

48

content known as spent coffee grounds (SCG) [5,6]. In general, processing one ton of

49

unroasted coffee produces 650 kg of SCG [7]. The U.S. Department of Agriculture

50

(USDA) estimated that approximately 4 million tons of SCG were produced globally

51

in 2011 [8]. SCG is a highly potent pollutant, as the caffeine, tannins, and polyphenols

52

are toxic and require large quantities of oxygen to degrade [2,9]. Coffee and the

53

by-products of its production are mostly discharged into the environment without

54

proper management. Specifically, coffee companies produce more than 2 billion tons

55

of by-products annually, including SCG and silver skin, and most of it is sent to

56

landfill [10]. Growing environmental awareness has triggered an interest in using

57

waste products, such as SCG or silver skin, in the fabrication of environmentally

58

friendly materials.

59

Incineration and composting are the two traditional treatments for SCG [11],

60

although studies have also investigated using recycled SCG for animal feed [12], for 3

61

organic compost [13], as an adsorbent [14], as fuel pellets [15], as biodiesel and

62

ethanol [16], and in the production of active carbon [17]. Among these treatments,

63

recycling into fuel – known as second generation fuel – has been recognized as a

64

feasible technology given its compatibility with current incineration technologies. The

65

use of biofuels has been proposed for increasing the sustainability of fuels derived

66

from renewable sources [9], and SCG has the potential to become a raw material for

67

biofuels [16]. The highest heating value (HHV) of SCG is approximately 25 kJ/kg,

68

which is similar to that of coal [18]; the oil content of SCG ranges in mass fraction

69

from 11% to 20% depending on the type of coffee [16]. Moreover, the high calorific

70

value of SCG makes it a feasible renewable energy resource for incineration purposes

71

[14]. Silver skin is part of the structure of the fruit of the coffee tree, and is produced

72

when the coffee bean is roasted [19]. A few studies have examined whether silver

73

skin has the potential to be used as a sustainable material in the building construction

74

industry [19]. Ronix et al. (2017) successfully used hydrothermally carbonized coffee

75

husks to adsorb methylene blue dye [20]. Considerable research is still needed to

76

make energy and material recovery from coffee residues a technically viable option

77

[21]. To the best of our knowledge, no study has tried to integrate silver skin and SCG

78

into biofuels.

4

79

The energy efficiency of biomass can be improved via physical processes such as

80

compression and pelletization [22]. The pelletized biomass is characterized by lower

81

moisture content, higher bulk density, and higher volumetric energy density (GJ/m3)

82

[23] than the original biomass. Kondamudi et al. (2008) proposed reusing SCG after

83

oil extraction and pelletization [15]. Allesina et al. (2017) pelletized SCG with a

84

thermal efficiency of 41.2%, which is higher than the 37.7% obtained from wood

85

pellets [11]. Pelletized biomass residues are easier to transport and store than

86

unpelletized biomass residues.

87

Heating and drying technologies have been developed to increase the low

88

heating value of wet SCG (ca. 8.4 MJ/kg [24]). Torrefaction is viewed as a

89

technology with a low environmental impact that is useful for the sustainable

90

management of both energy and biomass [25, 26]. During the mild pyrolysis process

91

of torrefaction, which takes place at low operating temperatures of 200–300°C,

92

biomass undergoes dehydration, devolatilization, depolymerization, and carbonization

93

[27]. The process can efficiently destroy stubborn fibers and enhance energy density

94

[28]. Around 70% of the initial mass and a maximum of 90% of the initial energy

95

content is retained in the torrefied biomass [29]. Torrefied products have

96

thermo-technical characteristics that are comparable to coal [30]. Numerous studies

97

have been conducted on the torrefaction of different biomasses, such as bamboo, 5

98

willow, coconut shell [31], eucalyptus [32], reed canary grass [33], sawdust, rice husk

99

[34], and SCG [27]. The torrefaction of solid residues is limited due to the high

100

heterogeneity of biomass residues [26].

101

Given the benefits of biomass torrefaction and pelletization, this pilot study

102

combined both treatments to produce samples of integrated SCG and silver skin

103

biofuels. The composite morphology and mechanical and thermal properties of the

104

biofuels were analyzed using scanning electron microscopy, Fourier transform

105

infrared spectroscopy, element analysis, and thermogravimetric analysis. The effects

106

on the biofuel mass and energy yields of changing the blending ratio of the raw

107

materials (SCG, silver skin, and pine sawdust) were also investigated. Previous

108

studies have shown that the operating parameters of torrefaction should be carefully

109

considered and the interactions between these parameters should be taken into

110

account [35]. The results of this study provide new methods of fabricating

111

environmentally friendly biofuels by integrating SCG and silver skin, which is

112

important with regards to the need to reduce environmental burdens and the

113

dependence on fossil fuels.

114 115

2. Materials and Methods

116

2.1. Preparation of material 6

117

SCG was the main feedstock for the production of biofuels in this study. The

118

SCG samples (SCG-A and SCG-B) were acquired from two major convenience stores,

119

where they had originally been treated as waste. The wet feedstock samples had a

120

55% moisture content, which was eliminated by drying at 105 ± 2°C for 24 h. The

121

dehydrated SCG was then sealed in plastic bags and stored in a desiccator at room

122

temperature until required for analysis.

123

However, a preliminary test showed that it was difficult to compress dehydrated

124

SCG into stable pellets. A mixture of ≥50% pine sawdust with a 10% moisture

125

content was used to increase the stability of the pelletized products. Table 1 shows the

126

ratios, by weight percentages, of the SCG, silver skin, and pine sawdust in the

127

different samples.

128 129

Table 1 here. 2.2. Experimental apparatus

130

A schematic of the experimental setup and the mass and energy flows is shown

131

in Fig. 1. The torrefaction reactor (TF55030A, Thermo) consisted of a quartz tube, a

132

tube furnace, a mass flow meter, and a product gas treatment unit. The quartz tube had

133

a 23 mm outer diameter and was 900 mm long (Thermo, USA). In each test, 10 ± 1 g

134

of pelletized material was loaded into the tube in a sample container, to measure the

135

torrefaction temperature. The temperature was increased at a constant rate of 7

136

10°C/min until it reached the desired temperature. The sample was torrefied for 3 h at

137

300°C to maximize the efficiency of torrefaction. After this time, the temperature was

138

decreased at a rate of 4.5°C/min; when the temperature fell below 120°C, the samples

139

were weighed and characterized. On average, 57.7% of the mass of the pellets was

140

lost during torrefaction (Fig. 1). Nitrogen (99.99 vol%) stored in a steel cylinder was

141

used as a carrier gas to purge the tube so that the torrefaction occurred in an

142

oxygen-free environment. The volumetric flow rate of the carrier gas was fixed at 100

143

mL/min by a mass flow meter, which was connected to a readout device. A

144

customized heated single-pellet die system was used in this study. A load force of 4

145

kgf/cm2 was applied by a piston for 3 min to compress the SCG into pellets that were

146

8.5 ± 1 mm in diameter and 20 ± 3 mm in height. A die temperature of 150°C was

147

sufficient to make control pellets. The energy of the pellets before torrefaction ranged

148

from 20.22 to 20.38 MJ/kg, depending on the ratios of the SCG, silver skin, and pine

149

sawdust. The measured and controlled variables are shown in Table 2.

150

Post-torrefaction gas and oil analyses will be performed in future studies.

151

Figure 1 here.

152

Table 2 here.

153

2.3. Properties of the SCG

8

154

For each experiment, the moisture content, HHV, volatile fraction, ash content,

155

and hygroscopicity of the sample were measured. Moisture content was measure

156

using the variating weights of the samples dried at 105°C for 24 h in a circular heating

157

oven (Model OVP-30, Hong-Siang Co., Taiwan). The calorific value obtained from

158

the bomb calorimeter (Model 1341, Parr Instrument Co., USA) was the HHV, which

159

included the latent heat of the vapor emitted from the specimen. Proximate analysis

160

was performed in accordance with the standard procedure of the American Society for

161

Testing and Materials (ASTM) for obtaining volatile fraction and ash content. The

162

average temperature and relative humidity of Taiwan in 2018 were 29.55 °C and

163

80.79%; these values were used as the basis of the hygroscopicity test [36]. About 1 g

164

of each sample was placed in the humidity simulator at 29.08±2°C and 79.83±3%

165

humidity. A fog generator with the supersonic frequency of 68 W and a fog producing

166

rate of 20 mL/min was installed. Both 1-h and 5-h hygroscopicity samples were

167

weighed to evaluate the preservation of the torrefied products. The mass and energy

168

yields are defined by Eqs. (1) and (2), as used by Bridgeman et al. (2008) [33].

169



170

!"





= #

$% &



=



× 100%



×

''(

)

''(

9



* *

(1) × 100% .

(2)

171

The experiment was repeated at least three times under each given condition. The data

172

shown in the tables are average values and the relative error between repetitions was

173

less than 5%.

174

2.4.Characterization of SCG

175

The SCG samples were characterized using thermogravimetric analysis (TGA),

176

Fourier transform infrared spectroscopy (FTIR), an element analyzer (EA), and a

177

scanning electron microscope equipped with an EDX spectrometers (SEM/EDX).

178

2.4.1. Thermogravimetric analyses

179

The pyrolysis characteristics of the samples were examined using a thermogravimetric

180

analyzer (Model Q500, TA Instruments, Inc., New Castle, USA). The samples were

181

loaded into a crucible that was placed inside the analyzer and the weight of the sample

182

was constantly measured. The analyzer measured and recorded the sample weight loss

183

as the temperature increased. For each test, a sample of around 5 mg with a particle

184

size of 100–200 mesh was used. The temperature increased from 25°C to 900°C, and

185

the heating rate was controlled at 10°C/min. Nitrogen gas was used as the carrier gas

186

in the analyzer and the flow rate was fixed at 40 mL/min. The relative error between

187

the TGA measurements was controlled to less than 5%. Two comprehensive indexes

188

(+ and , ) representing the combustion characteristics [37] were evaluated and

189

calculated as follows: 10

-./012 ×-./0314

190

+=

191

, = 8* ln -./

192

@8A

193

respectively. 8 , 8C , 8* , and 8

194

corresponding temperature, and peak temperature, which reflected the samples’

195

thermal behavior during the combustion process. These parameters can be derived

196

from TG and DTG curves. ∆8D/E is the temperature range of

197

2.4.2. Fourier transform infrared spectroscopy (FTIR) analyses

198

The chemical groups and constituents bonding arrangements found in the SCG were

199

determined by Fourier transform infrared spectroscopy (FTIR) using an FTIR

200

spectrophotometer (NICOLETiS5, Thermo, USA) equipped with a single reflection

201

diamond crystal ATR module. The spectra were recorded from the 400 to 4000 cm-1

202

spectral range, at a rate of 32 scans and a spectral resolution of 44 cm-1. The pelletized

203

samples were not favorable for FTIR analysis due to low transmission and

204

reflectance.

205

2.4.3. Element analyses

206

The elemental analysis was performed using an elemental analyzer (FlashEA 1112

207

HT, Thermo, USA) to measure the weight percentages of C, H, N, S, and Cl in the

208

SCG, whereas the weight percentage of O was obtained by considering difference.

(3)

.5 6 ×.7

∆.
B

10>? .

and @8A

(4)

are the maximum and average combustion rates (mg/min), B

are the ignition temperature, burnout temperature,

11

-./ -./012

= 0.5.

209

2.4.4. Scanning electron microscopy analyses

210

The particle shapes and surface textures were evaluated using scanning electron

211

microscopy (SEM) equipped with an EDX spectrometers using a model JSM-7610F

212

(JEOL, Japan), operating at 0.1 kV. The samples were mounted on aluminum stubs

213

using carbon tape. All of the specimens were sputter-coated with gold.

214

2.5. Similarity measurement

215

For fabricated biofuels that are designed to replace coal, the similarity of the

216

fabricated material’s characteristics to coal’s characteristics can be evaluated using

217

Eqs. (5) and (6) as follows:

218

H=

219

H = 1−

220

where ℎ, N, O, and P represent heating value, element content, proximate analysis

221

results, and combustion characteristics. T and U are the characteristics of the

222

biofuel and coal, respectively.

∑J K

, H = ℎ, N, O, P R5 >S5 S5

(5)

,

(6)

223 224

3. Results and Discussion

225

3.1. Properties of the biofuels

226

The properties of the biofuels are shown in Table 3. Samples 1 to 3 were

227

fabricated from SCG-A and Samples 4 to 6 were fabricated from SCG-B. Their mass 12

228

yields ranged from 41% to 43%; however, their energy yields were higher, at 52% to

229

58%. To increase the stability of the pellets, pine sawdust had to make up at least 50

230

wt% of the material. As the proportion of silver skin increased, both the mass and

231

energy yields decreased due to the HHV and fix carbon content of silver skin were

232

lower than SCGs. Poudel et al. (2015) found that a lower mass yield results in a lower

233

energy yield [38]. Also, the mass yield was decreased with an increase in temperature

234

or oxygen concentration [39]. The biofuels fabricated from SCG-A had higher mass

235

and energy yields than those fabricated from SCG-B. Previous studies found the mass

236

yield and energy of pine chips, logging residues, rice husk, and peanut husk fell in the

237

ranges of 52–89%, 71–94%, 41–79%, and 55–98% [28,40]. The yields are dependent

238

on the raw biomass, torrefaction temperature, residence time and reactor type [41].

239

The HHV of Sample 1 reached the same level as the HHV of coal (27.28 MJ/kg),

240

as shown in Table 3. The experimental set up and blended materials achieved higher

241

HHV values (ranging from 24.23 to 27.28 MJ/kg, shown in Fig. 1) than reported in

242

previous studies. Limousy et al. (2013) and Jeguirim et al. (2014) blended SCG and

243

pine sawdust into pellets [42,43]. They used the pyrolysis method to fabricate biofuels

244

and their HHVs were 18–20 MJ/kg at 11.78% moisture content. This study confirmed

245

that torrefaction has higher energy efficiency of training the initial energy content of

246

the biomass. Lower moisture content of the samples (1.77–3.32%) was also favorable 13

247

for increasing their energy properties. Previous study discovered that when SCG was

248

incorporated into wood chip logs, the HHV decreased to 17.39 MJ/kg at 10%

249

moisture content in a residential stove [44]. The comparison of the combustion

250

characteristics shows that the blended material had a higher reactivity than pure SCG

251

or sawdust.

252

Table 3 here.

253

The SCG had better heating values after drying. The moisture content of the

254

samples in this study ranged from 1.77% to 3.32%, as shown in Table 3. The original

255

moisture content of SCG-A and SCG-B was about 50%. The oven drying process

256

reduced the moisture content and made the pellets more suitable for longer storage.

257

When the proportion of fixed carbon increased, the HHV of the sample increased. In

258

this study, the volatile fraction of the samples was higher than that of coal. Some

259

harmful emissions, particularly nitrogen oxides in flue gas, were discovered by Kang

260

et al. (2017) [24]. There were about 2.79 g of nitrogen in 100 g of dry SCG [31]. The

261

ash content of the samples was about 1 to 3%, which is lower than coal. Thus, the

262

biofuels fabricated in this study have the potential to reduce the environmental burden

263

caused by landfilling.

264

Figure 2 shows the hygroscopicity of the samples. The increase in weight (wt%)

265

over a 5-h period was limited. Exposure of the samples to atmospheric conditions for 14

266

1 h allowed the samples to absorb water molecules and reach saturation. When the

267

proportion of silver skin increased, the hygroscopicity of the sample increased. The

268

composition of the biofuels with silver skin was unstable in the atmospheric

269

environment. On average, the weight increased by 0.24 to 0.57 wt% with a 10 wt%

270

increase of silver skin in the biofuels. Sample 1, which had 50% SCG-A and 50%

271

pine sawdust, was favorable for storage and had high hydrophobic ability.

272 273

Figure 2 here. 3.2.Characterization of the biofuels

274

As noted above, the biofuels were characterized using element analysis, FTIR,

275

SEM/EDX, and TGA. The carbon, hydrogen, oxygen, nitrogen, sulfur, and chlorine

276

contents of the samples were measured by elemental and EDX analysis, as shown in

277

Table S1. Consistent with previous studies, carbon sources were the primary

278

substances in the biofuels, including glucose and lignin, which is a single unit of

279

cellulose and hemicellulose [45]. The results of elemental and EDX were consisted

280

and the carbon content in the biofuels was 65–71 wt% in this study. SCG also

281

contains protein, which was measured using the nitrogen and sulfur sources in the

282

samples [46]. Neither sulfur nor chlorine were detected in the analysis by the

283

elemental analysis. None of the samples emitted dioxin or sulfur, which are air

15

284

pollutants, when heated. The fabricated biofuels were cleaner energy resources than

285

coal.

286

The element composition of the samples was similar to that of lignite, as shown

287

in the Van Krevelen diagram in Fig. 3. The benefits of torrefaction included lower

288

atomic oxygen-to-carbon (O/C) and hydrogen-to-carbon (H/C) ratios. The decrease in

289

the O/C ratio during torrefaction is attributed to the generation of volatiles rich in

290

oxygen, such as CO2 and H2O [47,48]. A reduced O/C ratio increases the HHV of the

291

torrefied biomass [38]. These changes in O/C and H/C ratios are mainly due to water

292

release and to the partial elimination of oxygen by decarboxylation, decarbonylation,

293

and dehydration reactions as well as in the form of volatile oxygenated compounds

294

such as acetic acid or methanol [49]. Lignite provides environmentally friendly power

295

generation with an energy content of 10 to 20 MJ/kg [50]. The biofuels made in this

296

study also had an energy content in a range of 18–20 MJ/kg, as shown in Table 3.

297

Figure 3 here.

298

Figure 4 shows the FTIR results for the SCG, silver skin, and pine sawdust. A

299

typical lignocellulosic material is composed of polysaccharides and aromatic

300

polymers. The broad peak between 3600 and 3200 cm-1 is related to the hydroxyl

301

group O-H stretching vibration [45]. The peaks at both 2920 cm-1 and 2850 cm-1 were

302

attributed to asymmetric and symmetric stretching of the C-H bonds of the methyl 16

303

group in the caffeine molecule along with sugars [51]. The C-H bonds decreased after

304

torrefaction, as shown in Figs. 4(a) and (b). A band at 1742 cm-1, which was attributed

305

to carbonyl vibration (C=O) in the aliphatic ester or triglycerides that originated in the

306

lipids [52], remained after torrefaction. Several peaks, 1245 cm-1 and 1032 cm-1 (C-O

307

stretching) verified that SCG contains a great variety of monosaccharides together

308

with diverse acid molecules, such as chlorogenic acid, caffeic acid, and coumaric acid

309

[53]. The band between 1700 and 1600 cm-1 was highly associated with chlorogenic

310

acids and caffeine [54]. The broad band between 1135 and 952 cm-1 was the result of

311

the stretching vibration of C-O in C-O-H bonds such as glycosidic bonds in

312

galactomannan polysaccharide sugars [55].

313

Figure 4 here.

314

Consistent with previous studies, the TGA curves for biofuels showed three

315

defined weight loss stages (Fig. 5). The first one occurred in the 105–360°C

316

temperature

317

low-molecule-mass volatile compounds [56]. During this state, there was about 5%

318

weight loss. The higher weight loss (35%) in the second range (360–490 °C)

319

corresponds to polysaccharide depolymerization and decomposition. Hemicellulose

320

and cellulose mainly decompose at 220–315°C and 315–400°C [57]. In the third

321

phase (490–800 °C), the formation of carbonaceous materials resulted in a further

range,

reflecting

the

water

17

evaporation

and

the

release

of

322

weight loss of around 10%. The residue at 800°C for biofuels was around 30%. Thus,

323

weight loss increased with temperature until burnout was reached.

324

Figure 5 here.

325

The combustion characteristics of the biofuels are listed in Table S2. The peak

326

temperature (8* ) of the biofuels was in the 409–419°C range, which is lower than that

327

of coal (about 441°C). Therefore, the whole combustion process of biofuels occurs

328

earlier than that of coal. The ignition temperatures (8 ) of Samples 1 and 4 were lower

329

than those of the other samples due to their higher volatile content, as shown in Table

330

3. The volatile content was increased when percentage of the silver skin in the

331

samples increased. The faster devolatilization and oxidation rates of the volatile

332

matter caused lower particle ignition temperatures [58]. The comprehensive +

333

indexes of Samples 1 and 4 were greater than those of the other samples, indicating

334

that their combustion performance was superior. The results of the comprehensive ,

335

index were the inverse of the results of the + index. A high ash content may have

336

inhibited the combustion reaction of the samples, leading to a decrease in combustion

337

performance [37].

338

Fig. 6 shows the SEM images of the raw materials’ morphologies. In addition to

339

its caloric value, SCG has a unique microporous structure with a high surface area of

340

about 300–1,000 m2/g [59]. SCG has been proven to be an effective adsorbent for a 18

341

wide range of contaminants [60]. The SCG particles mainly have a diameter range of

342

20–75 μm. Previous studies have suggested that particles of random size showed a

343

good response in electrorheology performance [46]. The torrefaction process may

344

have increased porosity, and similar results were noted by Mendes et al. (2019) [56].

345 346

Figure 6 here. 3.3. Similarity results

347

The study explored the creation of biofuels that were similar to coal with the aim

348

of reducing dependence on fossil fuels. The new biofuels’ similarity to coal was

349

evaluated by comparing their heating value, element content, proximate analysis

350

results, and combustion characteristics. Figure 7 shows the results of the comparison:

351

there was a similarity of at least 55%. The most similar sample was Sample 4, which

352

was 62% the same as coal. As the percentage of silver skin increased, the similarity to

353

coal decreased. The characteristics of the fabricated biofuels that were most similar to

354

coal were heating value (83–94%), followed by combustion characteristics (80–84%),

355

proximate analysis results (24–38%), and element content (27–42%). Previous studies

356

have shown that the heating value of SCG is similar to coal and higher than wood and

357

other biomass residues [61]. Future studies should consider other indicators.

358

Figure 7 here.

359 19

360

4. Conclusions

361

This study used the torrefaction method to fabricate biofuels that integrated SCG

362

and silver skin. The biofuels were dried, pelletized, and combusted at 300°C for 3 h.

363

To test whether the fabricated biofuels could replace coal, the similarity of their

364

characteristics was evaluated based on the parameters of heating value, element

365

content, proximate analysis results, and combustion characteristics. The mass yields

366

ranged from 41% to 43%; however, their energy yields were higher at 52% to 58%.

367

As the percentage of silver skin in the biofuels increased, both the mass and energy

368

yields decreased. The HHV of the biofuels ranged from 24.23 to 27.28 MJ/kg, which

369

are higher values than reported in previous studies. The results showed that increasing

370

the percentage of silver skin increased the hygroscopicity of the biofuels. On average,

371

there was a 0.24 to 0.57 wt% increase with an increase of 10 wt% of silver skin. The

372

carbon content in the samples ranged from 65 to 71 wt% and the sulfur and chlorine

373

contents were 0. These results demonstrate that these biofuels are cleaner energy

374

resources than coal. The element contents in the biofuels were similar to lignite, as

375

shown in the Van Krevelen diagram. The sample most similar to coal, Sample 4, was

376

62% similar. Integrating silver skin may reduce the quality of the biofuels, but it helps

377

reduce the environmental burden of landfilling or incineration.

378 20

379 380

Acknowledgments The authors would like to thank the Ministry of Science and Technology,

381

Republic

of

China,

for

financial

support

under

Contract

No.

MOST

382

106-2627-M-002-028. They also acknowledge the Taiwan EPA and Ministry of

383

Economic Affairs, and other governmental agencies for assisting with data collection.

384

The authors further thank the anonymous reviewers for their invaluable comments

385

and suggestions.

386 387

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562 563 564 565 566 567 568 569 570 571 572 573 574 575 30

576

Table 1

Sample composition Pine

Content

SCG-A

SCG-B

Silver skin

(%)

(%)

(%)

sawdust Sample

Weight (g)

(%) 1

50.00

0.00

0.00

50.00

3.0026

2

40.00

0.00

10.00

50.00

3.0273

3

30.00

0.00

20.00

50.00

3.0110

4

0.00

50.00

0.00

50.00

3.3830

5

0.00

40.00

10.00

50.00

3.0596

6

0.00

30.00

20.00

50.00

2.9985

577 578 579 580 581 582 583 584 585 586 587

31

588

Table 2

Variables used in this study

Variable

Unit

Value

Controlled variable pelletized load force

kgf/cm3

4

pellet size

mm

8.5±1 (diameter) and 20±3 (height)

heating rate

o

10

torrefied temperature

o

300

torrefied time

h

3

C/min C

Measured variable moisture content

wt%

HHV

MJ/kg

volatile fraction

wt%

ash content

wt%

fix carbon

wt%

hygroscopicity

wt%

mass yield

%

energy yield

%

similarity

%

589 32

590

Table 3 Sample properties moisture Content

mass yield

energy yield HHV (MJ/kg)

Sample

(%)

volatile content

fix carbon

(wt%)

(wt%)

ash content content

(%)

(wt%) (wt%)

591

a

SCG-A

－

－

22.12

9.49

1.36

81.58

17.06

SCG-B

－

－

21.81

9.46

1.40

82.37

16.23

Silver skin

－

－

17.82

7.48

3.24

80.69

16.07

1

42.72

58.33

27.28

3.32

3.0026

60.59

34.54

2

41.94

54.51

25.52

2.29

3.0273

63.78

32.30

3

41.68

53.45

24.73

2.84

3.0110

68.66

25.91

4

42.51

56.94

26.55

2.41

3.3830

64.15

32.21

5

41.73

52.91

24.73

1.77

3.0596

66.80

28.42

6

41.57

52.50

24.23

3.18

2.9985

68.26

27.14

Coal

－

－

27.28b

1.28-21.62 a

2.93-16.73 a

22.38-46.42 a

24.26-70.05 a

[62]

33

592

b

[63]

34

593 594

Fig. 1. The experimental setup and mass and energy flow.

595 596 597 598 599

35

6 1-h 5-h

5

weight (wt%)

4

3

2

1

0 1

2

4

5

sample

600 601

3

Fig. 2

Hygroscopicity of the biofuels.

602 603

36

6

0.18 0.16 0.14

H/C ratio

0.12

anthracite bituminous coal lignite peat biomass sample

0.10 0.08 0.06 0.04 0.02 0.00 0.0

0.4

0.6

0.8

1.0

1.2

O/C ratio

604 605

0.2

Fig. 3

Van Krevelen diagram of the biofuels and coal.

606 607 608 609 610 611

37

1.4

102

(a)

103

(b)

100 102

98

transmittance (%)

101

2882 cm C-H 2920 cm C-H

94

transmittance (%)

-1

3600~3200 cm C-O

96

-1

-1

92

-1

1245 cm C-O 1032 cm-1 C-O

90 SCG-A torrefied SCG-A

88

3600~3200 cm-1 C-O

99 98

SCG-B torrefied SCG-B 2882 cm-1 C-H

97 96

-1

1742 cm C=O

86

100

2920 cm-1 C-H

95

4000

3000

612

2000

1000

4000

3000

-1

1245 cm-1 C-O 1742 cm-1 C=O 1032 cm-1 C-O

2000

1000 -1

wavenumber (cm )

wavenumber (cm )

700

(d)

500

(c)

500

300

3600~3200 cm-1 C-O

-1

2829 cm C-H

2882 cm-1 C-H

200

1245 cm-1 C-O 1742 cm C=O

100 2920 cm C-H

transmittance (%)

transmittance (%)

400

3600~3200 cm-1 C-O 2882 cm-1 C-H

300

1245 cm-1 C-O

-1

100

-1

2920 cm-1 C-H

silver skin torrefied silver skin

1742 cm-1 C=O

0 4000

613

615

400

200

0

614

pine sawdust torrefied pine sawdust

600

3000

2000

4000

1000

Fig. 4

3000

2000

1000

wavenumber (cm-1)

wavenumber (cm-1)

FTIR spectra for of (a) SCG-A, (b) SCG-B, (c) silver skin, and (d) pine sawdust.

38

100

weight (%)

90

80

70 sample 1 sample 2 sample 3 sample 4 sample 5 sample 6

60

50 200

400

temperature (oC)

616 617

600

Fig. 5

TGA curves of the biofuels.

39

800

618 619

Fig. 6

SEM images of (a) SCG-A, (b) torrefied SCG-A, (c) SCG, (d) torrefied

620

SCG-B, (e) pine sawdust, (f) torrefied pine sawdust, (g) silver skin, and (h)

621

torrefied silver skin. 40

100

0.63 0.62

80

0.60

60

0.59 40

20

0.58 0.57

SCG (%) silver skin (%) pine sawdust (%) similarity result

0.56

0

0.55 1

2

4

5

6

sample

622 623

3

Fig. 7

Similarity analysis of the biofuels and coal.

624

41

similarity results

composition (%)

0.61

Research Highlights Spent coffee grounds (SCG) and silver skin were integrated into biofuels. The high heat value (HHV) was in range of the biofuels (24.23–27.28 MJ/kg). An increase in silver skin increased the hygroscopicity of the biofuels. The sample most similar to coal exhibited 62% similarity.