Fs emissions from secondary nonferrous smelting plants and towards to their source emission reduction

Journal Pre-proof Variations of PCDD/Fs emissions from secondary nonferrous smelting plants and towards to their source emission reduction Yuanping Yang, Guanglong Wu, Cheng Jiang, Minghui Zheng, Lili Yang, Jiahong Xie, Qingjie Wang, Minxiang Wang, Cui Li, Guorui Liu PII:

S0269-7491(19)35315-1

DOI:

https://doi.org/10.1016/j.envpol.2020.113946

Reference:

ENPO 113946

To appear in:

Environmental Pollution

Received Date: 16 September 2019 Revised Date:

25 November 2019

Accepted Date: 7 January 2020

Please cite this article as: Yang, Y., Wu, G., Jiang, C., Zheng, M., Yang, L., Xie, J., Wang, Q., Wang, M., Li, C., Liu, G., Variations of PCDD/Fs emissions from secondary nonferrous smelting plants and towards to their source emission reduction, Environmental Pollution (2020), doi: https://doi.org/10.1016/ j.envpol.2020.113946. 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. © 2020 Published by Elsevier Ltd.

1

Variations of PCDD/Fs emissions from secondary nonferrous

2

smelting plants and towards to their source emission reduction

3

Yuanping Yang a,b, Guanglong Wu c, Cheng Jiang c, Minghui Zheng

4

Jiahong Xie c, Qingjie Wang a, Minxiang Wang a, Cui Li a,b, Guorui Liu a,b,*

5

a

（

Center for Eco-Environmental Sciences, Chinese Academy of Sciences, P.O. Box

7

2871, Beijing, 100085, China

8

b

9

c

10

a,b

, Lili Yang

a,b

,

State Key Laboratory of Environmental Chemistry and Ecotoxicology, Research

University of Chinese Academy of Sciences, Beijing, 100049, China International Environmental Cooperation Center, Ministry of Ecology and

Environment of People’s Republic of China, Beijing, China, 100035

11 12

*

13

E-mail: [email protected]

14

Co-authors’

15

[email protected] (G.L.Wu); Cheng Jiang: [email protected]

1（

(C.Jiang); Minghui Zheng: [email protected] (M.H.Zheng); Lili Yang:

17

[email protected] (L.L.Yang); Jiahong Xie: [email protected] (J.H.Xie);

18

Qingjie

19

[email protected] (M.X. Wang); Cui Li: [email protected] (C.Li).

Corresponding author: Tel: +86-10-6284-9356; Fax: +86-10-6284-9356

email:

Wang:

Yuanping

Yang:

[email protected]

20 21 22

Declarations of interest: none

1

[email protected]

(Q.J.Wang);

(Y.P.Yang);

Minxiang

Wang:

23 24

Abstract Polychlorinated

dibenzo-p-dioxins

and

dibenzofurans

(PCDD/Fs)

are

25

cancerogenic organic pollutants that priority controlled by Stockholm Convention

2（

with globally 182 signatories now. Secondary nonferrous smelting plants are

27

confirmed to be important sources in China due to its large industrial activities and

28

high emissions of PCDD/Fs. It is important to prioritize source to achieve source

29

emission reduction by conducting field monitoring on typical case plants. Here, the

30

emission profiles and levels of PCDD/Fs were investigated in 25 stack gas samples

31

collected from three secondary copper production (SeCu), two secondary zinc

32

production (SeZn) and two secondary lead production (SePb). Both average mass

33

concentration and toxic equivalency quantity (TEQ) concentrations of PCDD/Fs all

34

generally decreased in the order: SeCu >SeZn > SePb. It is noteworthy that the mean

35

TEQ concentration in stack gas from SeCu with oxygen-enrich melting furnace

3（

technology, at 2.7 ng I-TEQ/Nm3, was much higher than the concentrations of other

37

smelting processes. The average emission factors and annual release amounts of

38

PCDD/Fs from SeCu, SePb and SeZn investigated were 28.4, 1.5, 10.4 µg I-TEQ/t

39

and 1.03, 0.023, 0.17 g I-TEQ/year, respectively. The ratios of 2,3,7,8-TCDF to

40

1,2,3,7,8-PeCDF and OCDD to 1,2,3,7,8,9-HxCDD varied to large extent for three

41

metal smelting, which could be used as diagnostic ratios of tracing specific

42

PCDD/Fs sources. Addition of copper-containing sludge into the raw materials might

43

lead to higher PCDD/Fs emissions. It is important to emphasize and reduce the

44

PCDD/Fs emissions from oxygen-enrich melting furnace from secondary copper 2

45

productions.

4（ 47

Capsule abstract

48

Copper smelting with oxygen-enrich melting furnace had the highest PCDD/F

49

emissions. Diagnostic ratios of specific congeners were suggested for smelters to

50

tracing PCDD/F sources.

51 52

Keywords: PCDD/Fs; secondary metallurgy industry; persistent organic pollutants;

53

oxygen-enrich melting furnace; copper sludge

54

3

55 5（

1. Introduction Polychlorinated dibenzo-p-dioxins and polychlorinated dibenzofurans (PCDD/Fs)

57

are classified as persistent organic pollutants (POPs) which have acute and chronic

58

effects may pose enormous possible risks to the environment and human health

59

(Knutsen et al., 2018; Van den Berg et al., 1998; Van den Berg et al., 2006). PCDD/Fs

（0

are unintentionally formed and released from many thermal industrial sources such as

（1

waste incineration (Kanan and Samara, 2018; UNEP, 2013; Zhu et al., 2018) and

（2

secondary metallurgy production (Lv et al., 2011), which can result in the

（3

contamination of the environment with long term contamination of soils (Weber et al.,

（4

2018) and food producing animals in the surrounding with associated human exposure

（5

(Weber et al., 2019). The secondary metallurgy manufacture including secondary

（（

copper (SeCu), zinc (SeZn) and lead production (SePb) have been addressed to be

（7

major sources of PCDD/Fs in environment (Ba et al., 2009a; Ba et al., 2009b),

（8

especially secondary zinc smelters can have extreme high releases of PCDD/Fs above

（9

100 ng TEQ/Nm3 (Chi et al., 2007). Tracing the PCDD/Fs emissions from secondary

70

metallurgy manufacture is an activity of great importance to metallurgy plants

71

management and plays an important role in our country's implementation of the

72

Stockholm Convention.

73

Several researchers focused on the emission factors and homolog and congener

74

profiles of PCDD/Fs from secondary metallurgy industry (Altarawneh et al., 2009;

75

Chin et al., 2011; Wang et al., 2016; Wu et al., 2018). Yu et al., (2006) reported the

7（

release levels of PCDD/Fs from various secondary metal smelting industries in Korea. 4

77

It was reported that the emission concentration of PCDD/Fs in flue gas of different

78

secondary metal smelting industries varied greatly. The emission factor of PCDD/Fs

79

during the process of secondary copper smelting was 24.4 µg TEQ/t, which was much

80

higher than that of secondary lead and zinc industries (Yu et al., 2006). Ba et al.,

81

(2009) investigated the emission levels of PCDD/Fs in stack gas of several secondary

82

copper smelters in China (Ba et al., 2009b). The concentrations of PCDD/Fs releases

83

varied from 0.043 to 15.8 ng TEQ/Nm3. At the same time, the total PCDD/Fs

84

emissions of China's secondary copper smelting industry in 2009 were estimated at

85

37.5 g TEQ/year, which was higher than that of PCDD/Fs in the recycled lead and

8（

zinc smelting industries (Ba et al., 2009a). Besides, Nie et al., (2011) studied the

87

effects of different raw materials, pretreatment technology and production scale on

88

PCDD/Fs emissions in the process of secondary copper smelting, indicating that the

89

pretreatment of raw materials can effectively reduce PCDD/Fs emissions in the

90

process of reclaimed copper smelting (Nie et al., 2011). Subsequently, Hu et al., (2013)

91

surveyed the stack gas levels of PCDD/Fs from different smelting stages of secondary

92

copper (feeding-fusion stage, oxidation stage and deoxidization stage). It was found

93

that feeding-fusion stage was the dominate discharge stage of PCDD/Fs in the process

94

of reclaimed copper smelting (Hu et al., 2013).

95

Many secondary copper smelting enterprises currently use oxygen-enriched

9（

smelting furnace to process copper-containing sludge, low-grade waste copper and

97

other raw materials to produce crude copper, which is used as raw material for copper

98

production in converter, thereby improving the grade of copper (Ministry of ecology 5

99

and environment of the people's Republic of China, 2017). To the best of our

100

knowledge, the data about the release of PCDD/Fs in oxygen-enrich smelting furnaces

101

is scarce. In the other hand, the emission limits and regulations of PCDD/Fs in stack

102

gases from secondary metallurgy industry continued to be more and more stringent in

103

the recent years (Ministry of Industry and Information Technology of the People's

104

Republic of China, 2006). Nevertheless, there is no survey on PCDD/Fs emissions

105

from oxygen-enriched smelting furnace, leading to the absence of data about release

10（

concentration and profile of PCDD/Fs in this facility of secondary copper smelting

107

processes. Such a gap indicated urgently need for case studies with the aim of better

108

recognizing and evaluating the major emission stages and source emission control of

109

PCDD/Fs for secondary nonferrous smelting industries. This is significant for towards

110

to the source emission control of secondary copper smelting industries. Moreover,

111

much more data about PCDD/Fs levels and profiles from secondary zinc and lead

112

production is also needed for accurately evaluating their emissions on national scale.

113

In this study, 25 stack gas samples from secondary nonferrous productions including

114

SeCu, SeZn and SePb were isokinetic collected and quantified for seventeen toxic

115

PCDD/Fs congeners. The congener profiles of PCDD/Fs from the investigated

11（

facilities were evaluated for exploring potential formation mechanisms. Additionally,

117

the emission factors and annual release amounts of PCDD/Fs expressed in the toxic

118

equivalency (TEQ) were also calculated for comprehensively evaluating the PCDD/Fs

119

emission from secondary metallurgy industries in China.

120 （

121

2. Materials and methods

122

2.1. Basic information on the investigated plants and stack gas sample collection

123

Seven typical secondary metallurgy plants were investigated, including three

124

SeCu, two SePb, and two SeZn (basic information of these plants are provided in

125

Table 1). In order to understand the release of PCDD/Fs from different smelting

12（

furnaces of secondary copper smelting industry, the flue gas samples from converter

127

furnace (SeCu(1), SeCu(2)-A) and oxygen-enriched smelter furnace (SeCu(2)-B,

128

SeCu(3)) were collected. 25 stack gas samples were collected from investigated

129

plants by an automatic isokinetic sampling system, Isostack Basic (TCR TECORA,

130

Milan, Italy), in accordance with the European Standard EN-1948-1 which was the

131

sampling procedure. Before sampling the stack gas samples, 13C12-labelled PCDD/Fs

132

was spiked into the XAD-2 resin as surrogate sampling standards.

133

2.2. Stack gas sample preparation and instrumental analysis of PCDD/Fs

134

The extraction and purification, identification and quantification of PCDD/Fs

135

congeners were accomplished in accordance with EN-1948-2 and EN-1948-3,

13（

respectively. Briefly,

137

spiked into stack gas samples. The stack gas samples were then Soxhlet extracted for

138

about 24 hours by using 250 mL of toluene. The extracts were evaporated to

139

approximately 1-2 mL using the rotary evaporator. After concentration, the extracts

140

were sequentially purified by a series of adsorption columns, including acidified

141

silica gel, a multilayer silica gel, and activated-charcoal columns. Finally,

13

C12-labelled PCDD/Fs internal quantification standards were

7

142

13

143

chromatography/high resolution mass spectrometry (HRGC/HRMS) analysis.

144

Congener specific analysis of PCDD/Fs were performed by using a gas

145

chromatograph coupled to a DFS mass spectrometer (Thermo Fisher Scientific,

14（

Waltham, MA, USA), and a DB-5 capillary column (60 m × 0.25 mm × 0.25 µm)

147

was selected to separate the analytes. The HRMS was equipped with a positive

148

electron impact source and HRMS was tuned and operated at a mass resolution of

149

around 10,000. The ion source was specified at 250

150

to be 37 eV.

151

2.3. Quality assurance and quality control (QA/QC)

152

C-labelled recovery standards were added to the extracts before high resolution gas

The recoveries of

13

and the electron energy is set

C12-labelled PCDD/Fs internal standards in the stack gas

153

samples were range 58 to 120%, meeting the analytical method requirements. Three

154

QC criteria were employed in the determination of the target compounds: (a) the GC

155

retention time matched to the available corresponding

15（

the signal-to-noise ratio was >3:1; and (c) the isotopic ratios of two monitored ions

157

for the analyte should be within ±15% of the theoretical values. Furthermore, there

158

was a blank in each batch of samples, and no obvious interference was detected in

159

the blank samples. When calculating the concentration of PCDD/Fs in stack gas, the

1（0

collection volume will be converted to the standard state (0

13

C12-labelled standards; (b)

and 1 atm).

1（1

Statistical analysis was employed by SPSS version 25 software (IBM, USA). In

1（2

order to minimize the influence of total concentrations, the congener concentrations

1（3

were normalized to the percentage of total concentrations. Pearson correlation 8

1（4

analysis was conducted by SPSS to explore possible relationships between the target

1（5

compounds and total TEQs. Statistical significance of p < 0.05 was set for correlation

1（（

analysis.

1（7 1（8

3. Results and Discussion

1（9

3.1. Emission levels and variations of PCDD/Fs from different secondary

170

metallurgy facilities and different smelting stages

171

The mass concentrations and I-TEQ of PCDD/Fs were determined in stack gas

172

samples sampled from the seven secondary nonferrous smelting plants investigated

173

are presented in Fig.1. Obviously, there was a large concentrations variations of

174

PCDD/Fs among the different metallurgy smelting industries (SeCu, SeZn and

175

SePb) and among different plants in the same nonferrous smelting category. In

17（

general, the average concentrations of PCDD/Fs in stack gas samples of three

177

category of sources ranged from high to low as follow: SeCu > SeZn > SePb, the

178

corresponding mass concentrations were 53.35, 24.47, 1.53 ng/Nm3 and the

179

corresponding I-TEQ concentrations were 0.84, 0.48, 0.05 ng TEQ/Nm3,

180

respectively. As seen in Fig. 1, the tendencies of mass concentrations of PCDD/Fs

181

from different plants were generally consistent with those of PCDD/Fs TEQ

182

concentrations. The TEQ concentrations of PCDD/Fs in this study were

183

significantly lower than that reported by Ba et al. in 2009, where corresponding

184

concentration were 2.84, 98.02, 0.35 ng TEQ/Nm3 for SeCu, SeZn, and SePb,

9

185

respectively (Ba et al., 2009a; Ba et al., 2009b), indicating that the metal smelting

18（

techniques and stack gas removal technology have been obviously upgraded or

187

improved and achieved remarkable achievements in recent years in China.

188

There are multiple process stages and different types of furnaces for secondary

189

copper smelting. In order to recognize the dominant stages of PCDD/Fs emissions

190

from secondary copper smelting sources, we aim to compare the PCDD/Fs

191

concentrations in the stack gas collected from different smelting furnaces in the

192

secondary copper smelting industry. Firstly, the flue gas samples from converter

193

furnace and oxygen-enriched smelter were collected and analyzed. The converter

194

furnace usually had three main smelting stages: feeding-fusion (FF), oxidation

195

(OX) and deoxidization (DO), and the corresponding dioxin concentrations in the

19（

flue gas were sequentially reduced, which were in the range of 0.11-0.80, 0.07-0.19,

197

0.06-0.07 ng I-TEQ/Nm3, respectively. These trends were similar to the previous

198

report in the stack gas of different stages of secondary copper production (Hu et al.,

199

2013) . However, it was noteworthy that the mean TEQ in stack gas from

200

SeCu(2)-B (oxygen-enrich melting furnace) was 2.7 ng TEQ/Nm3. This value is far

201

higher than the concentrations of PCDD/Fs released from the converter furnace in

202

the same plant, which suggested that PCDD/Fs emissions from oxygen-enrich

203

melting furnace should be emphasized. This is the first measurement of PCDD/Fs

204

released from oxygen-enrich melting furnace and the results are significant for

205

further control and reduction of PCDD/Fs from secondary copper smelting sources.

10

20（

The mean TEQ concentration in stack gas from SeCu(2)-B was approximately

207

21 times higher than that in SeCu(3) using the same type of furnace. After

208

comparing the raw materials, smelting processes and pollution control facilities of

209

the above two secondary copper smelters, it might be attributable to the difference

210

in raw materials: SeCu(2)-B were 30% copper-containing sludge and 70% scrap

211

copper, while SeCu(3) was 100% scrap copper. The carbon source, chlorine source,

212

and catalytically metal elements are widely recognized as important factors in the

213

formation of PCDD/Fs (Heeb et al., 2013; Kakuta et al., 2007; Kuzuhara et al.,

214

2003; Vallejo et al., 2013; Wu et al., 2018). It is widely recognized that ash from

215

secondary copper smelters have the high PCDD/Fs formation potential (Cagnetta et

21（

al., 2016; Liu et al., 2015), since copper is more likely to catalyze the formation of

217

PCDD/Fs during thermal processes (Hung et al., 2015; Stieglitz et al., 1989).

218

Therefore, the TOC contents (3.3%), Cu element (25.1%) and chlorine (4.3%) in

219

the copper-containing sludge from electroplating industry may explicate that the

220

PCDD/Fs concentration of SeCu(2)-B was higher than that of SeCu(3). It was

221

obvious that different raw material compositions can affect the formation amounts

222

of the PCDD/Fs in the secondary metal smelting processes.

223

3.2. Congener profiles and homolog distributions of PCDD/Fs from different

224

industries

225

Homolog patterns and congener profiles of PCDD/Fs were compared for

22（

understanding their emission characteristics in stack gas from different

11

227

metallurgical industries. Fig. 2 presents the congener profiles of 2,3,7,8-substitude

228

PCDD/Fs in the stack gas samples from various industries. In most of stack gas

229

samples, OCDD and 1,2,3,4,6,7,8-HpCDD were the major congeners. The

230

contributions of PCDDs to total PCDD/Fs increased with chlorination degree

231

elevation. Those general patterns were consistent with those for incinerators (Abad

232

et al., 2006; Li et al., 2017), cement kilns (Ames et al., 2012; Zou et al., 2018), and

233

coke plants (Liu et al., 2009). The congener 1,2,3,4,6,7,8-HpCDF was dominant in

234

the PCDFs in the samples and this is similar to that in previous studies (Li et al.,

235

2015; Liu et al., 2009). Meanwhile, the proportion of OCDD increases with the

23（

process of smelting in the samples collected from secondary copper production

237

converter furnace, with the ratio in FF, OX and DO stages was 9.5-13.9%,

238

16.7-20.7% and 25.4-27.5%, respectively (Fig. 2a). The ratios of specific PCDD/Fs

239

congeners can provide important information on source apportioning of PCDD/Fs

240

in the environment (Liu et al., 2015). To further assess the differences in congener

241

profiles of different secondary metallurgy industries, we calculated the

242

concentration ratios of the specific congeners with clear discrepancy. The average

243

ratios of 2,3,7,8-TCDF to 1,2,3,7,8-PeCDF were 0.82, 3.2 and 0.39 for SeCu

244

oxygen-enrich melting furnace, SeZn and SePb, respectively. The average ratios of

245

OCDD to 1,2,3,4,6,7,8-HpCDD were 1.8, 1.1 and 0.41 for SeCu oxygen-enrich

24（

melting furnace, SeZn and SePb, respectively. Those ratios could be used as

247

diagnostic values of tracing the sources of PCDD/Fs in the environment. Moreover,

248

to obtain comprehensive fingerprinting of PCDD/Fs, a more detailed assessment of 12

249

congener patterns including the non-2,3,7,8-substituted congeners should be done in

250

future (Hagenmaier et al., 1994; Ooi et al., 2018).

251

Pearson correlation analysis was conducted to study the correlations among

252

the congener concentrations of PCDD/Fs and total TEQ (Fig. 3). Positive

253

correlations (R2>0.9, p < 0.05) between 2,3,4,6,7,8-HxCDF, 1,2,3,4,6,7,8-HpCDF,

254

1,2,3,4,7,8,9-HpCDF, OCDF, 1,2,3,4,6,7,8-HpCDD, OCDD and TEQ were

255

observed.

25（

1,2,3,4,6,7,8-HpCDD, display much significant correlation with TEQ, with R2 of

257

0.975 and 0.972, respectively, which can act as indicators for estimating PCDD/Fs

258

emissions in TEQ from secondary metal smelting processes.

Two

congeners

comprised

of

1,2,3,4,7,8,9-HpCDF

and

259

The homolog contributions to PCDD/Fs TEQ in the stack gases from the 7

2（0

plants investigated are presented in Fig. 4. For PCDD/Fs homolog profiles, lower

2（1

chlorinated PCDD/Fs homologs (tetra-, and penta-) were dominant in the stack gas

2（2

from SeCu converter furnace and SePb, while higher chlorinated PCDD/Fs

2（3

homologs were dominant in SeCu oxygen-enrich melting furnace and SeZn. The

2（4

different homolog pattern may arise from the different formation mechanisms of

2（5

PCDD/Fs homologs under different metal catalysts (Liu et al., 2015; Oh et al.,

2（（

2004).

2（7

3.3. Emission factors, annual emission amounts and implication for source

2（8

emission reduction

2（9

Derivation of the emission factors (EFs) is significant for compiling emission 13

270

inventories and estimating PCDD/Fs emission amounts from whole industries on

271

national scale based on available monitoring data from studies on case plants. It is

272

also important to recognize the priority sources and assist regulatory agencies to

273

develop best control technique and strategy for reducing overall emissions. The

274

following formula was used for deriving emission factors and calculating the total

275

release of unintentional POPs (UNEP, 2013).

27（


    

   
 ( 
/) =

277

  / ( /!"# ) × %& '()* ( +, %('- (!"# /. )

278

 =
 > ( 
/?@ ) = Emission

279

activity level of reference year (t/year)

1

/0123 4567891:6; (1/<)

factor

(ng

TEQ/t) × 2

280

The emission factors varied among different categories of metallurgy industries

281

and also among different smelting plants for a given metal category. The derived

282

emission factors and evaluated annual emission amounts of PCDD/Fs from flue gas of

283

the secondary nonferrous metal smelters are presented in Table 2. The emission

284

factors ranged from 0.79 to 106.8 µg TEQ/t. The emission factors derived in our study

285

were consistent with those previous publications for metallurgical plants (Antunes et

28（

al., 2012; Ba et al., 2009a; Ba et al., 2009b; Lv et al., 2011). For secondary copper

287

smelters, the emission factors of SeCu(1), SeCu(2)-A and SeCu(3) were all lower than

288

the emission factor of UNEP toolkit’s (5 µg TEQ/t for classification with optimized

289

for PCDD/PCDF control), indicating that the optimization control was carried out for

290

the PCDD/Fs emissions, such as the pretreatment of raw materials or the treatment of

291

flue gas with activated carbon (UNEP, 2013). However, the highest EFs were 14

292

estimated for a secondary copper production plant with oxygen-enrich melting

293

furnace technology (SeCu(2)-B; 106.8 µg TEQ/t), which located between the

294

classification of the well controlled (50 µg TEQ/t) and the basic technology (800 µg

295

TEQ/t) in the UNEP Toolkit. The secondary lead smelter's emission factors were

29（

lower than the UNEP toolkit’s emission factor (8 µg TEQ/t for removing PVC plants

297

and 80 µg TEQ/t for scrap containing PVC). For the investigated secondary zinc

298

smelters, bag filters or electrostatic precipitators were adopted for control dioxins

299

emissions into air, the emission factors were lower than the UNEP toolkit’s emission

300

factor (100 ug TEQ/t for classification of hot briquetting/rotary furnaces, basic dust

301

control; e.g., fabric filters/electrostatic precipitation) (UNEP, 2013). The emission

302

amounts represented the emission level and activity intensity of the specific industries.

303

In this study, the estimated total annual stack gas emissions of the 7 investigated

304

plants ranged from 11.9 to 3847.2 mg TEQ/year.

305

There are about a thousand secondary nonferrous smelting plants being operation

30（

in China. Due to the high emission factors and total emission amounts, it is important

307

to pay attention to the PCDD/Fs emissions from secondary nonferrous productions.

308

This field study on the case plants found that the PCDD/Fs emissions from

309

oxygen-enrich melting furnace were much higher than that in the three stages of

310

converter furnaces. Thus, it is important to optimize the operation parameters in this

311

stage and reduce PCDD/Fs formation and emissions from the oxygen-enrich melting

312

furnace, which was scarcely recognized before this study. We also found that the

313

addition of copper sludge into the raw materials could increase the PCDD/Fs 15

314

emissions. These findings in this study might provide important knowledge for the

315

considerations of PCDD/Fs control, reduction and regulations by the enterprise or

31（

policy makers, which could contribute to the reduction of human exposure in China.

317

Our results also pointed out that the estimated PCDD/Fs emission amount decreased

318

compared to that evaluated in 2009.

319 320

4. Conclusions

321

In this study, the emission characteristics of PCDD/Fs in 25 stack gas samples

322

collected from secondary nonferrous productions were investigated. The results

323

indicated that PCDD/Fs concentrations in stack gas were in the order of SeCu >SeZn

324

> SePb. The average TEQ concentration in stack gas from SeCu with oxygen-enrich

325

melting furnace technology was higher than the concentrations of other smelting

32（

processes. The highest EFs and EAs were also estimated for SeCu(2)-B, at 106.8 µg

327

TEQ/t and 3847.20 mg TEQ/year, respectively. It was found that addition of

328

copper-containing sludge into the raw materials might result in higher PCDD/Fs

329

formation and emissions. Ratios of specific congeners could be used for the

330

diagnostic ratios for identifying their specific sources in the environment. These

331

results might provide important knowledge for the considerations of PCDD/Fs

332

control, reduction and regulations in secondary nonferrous smelting plants, and also

333

emphasize that high emissions of PCDD/Fs from the secondary metal industries and

334

the potential long-term risk to the surrounding areas should attract more attention.

335

Besides, a more comprehensive fingerprinting is available including the 1（

33（

non-2,3,7,8-substituted congeners and need to be applied for source assessment in

337

future.

338 339 340

Acknowledgments

341

This work was supported by the National Natural Science Foundation of China

342

(21936007; 21777172), Beijing Natural Science Foundation (8182052), Youth

343

Innovation Promotion Association of the Chinese Academy of Sciences (2016038).

344 345

Competing financial interest

34（

The authors declare no competing financial interest.

347 348

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Captions of Figures and Tables: Fig. 1. Mass concentrations of PCDDs and PCDFs, I-TEQ concentration of PCDD/Fs in stack gas from different secondary metallurgy industries. Fig 2. Contributions of PCDD/Fs congeners to the total PCDD/Fs concentrations in the stack gas samples from different smelting stages of secondary copper (SeCu) converter furnace (a), SeCu oxygen-enrich melting furnace (b), secondary lead production (c) and secondary zinc production (d). Fig 3. Pearson correlation of PCDD/Fs congeners and I-TEQ. Fig 4. PCDD/Fs homologue distribution for the stack gas samples from the 7 plants investigated.

Table 1. Basic information on the investigated plants. Table 2. Derivation of emission factors and estimation of annual emission amounts of PCDD/Fs form the investigated plants.

24

Fig. 1. Mass concentrations of PCDDs and PCDFs, I-TEQ concentration of PCDD/Fs in stack gas from different secondary metallurgy industries.

25

Fig. 2. Contributions of PCDD/Fs congeners to the total PCDD/Fs concentrations in the stack gas samples from different smelting stages of secondary copper production (SeCu) converter furnace (a), SeCu oxygen-enrich melting furnace (b), secondary lead production(c) and secondary zinc production (d).

2（

Fig. 3. Pearson correlation of PCDD/Fs congeners and I-TEQ.

27

Fig. 4. PCDD/Fs homologue distribution for the stack gas samples from the 7 plants investigated.

28

Table 1. Basic information on the investigated plants. Abbreviation of investigated plants

SeCu(1)

SeCu(2)-A

SeCu(2)-B

SeCu(3)

SePb(1)

SePb(2)

SeZn(1)

SeZn(2)

category of metallurgical

Furnace type

plants secondary copper production

secondary copper production

production secondary zinc production

crude copper + copper

converter furnace

120

activated carbon + bag filter

3

55

bag filter

2

140

bag filter

3

copper scrap

3

lead scrap

lead slag + lead scrap

oxygen-enrich melting

furnace

secondary zinc

Raw material

5

production

production

samples

activated carbon + bag filter

oxygen-enrich melting

secondary lead

Number of

110

secondary copper

production

(t/day)

Air Pollution Control Devices

converter furnace

furnace

secondary lead

Capacity

electrostatic precipitation + gravity

rotary furnace

50

rotary furnace

20

bag fliter

3

rotary furnace

60

gravity settling + bag fliter

3

rotary furnace

64

29

settling + bag filter

electrostatic precipitation + bag fliter

3

scrap crude copper + copper scrap copper sludge + copper scrap

dust of steel mill + zinc dross zinc ore + zinc dross

Table 2. Derivation of emission factors and estimation of annual emission amounts of PCDD/Fs form the investigated plants. Abbreviation of

Emission factors

Annual emission amounts

investigated plants

(ug TEQ/t )

(mg TEQ/year)

SeCu(1)

2.57

92.56

SeCu(2)-A

3.42

171.11

SeCu(2)-B

106.86

3847.20

SeCu(3)

0.79

11.93

SePb(1)

2.18

30.59

SePb(2)

0.89

17.55

SeZn(1)

9.54

177.61

SeZn(2)

11.22

168.33

30

Highlights


PCDD/Fs emitted from seven secondary metallurgical plants were investigated




Copper smelting with oxygen-enrich melting furnace had the highest PCDD/F emissions




Copper-containing sludge in raw materials might cause higher PCDD/F formation




Diagnostic ratios of specific congeners were suggested for different metal smelters

Author Contribution Statement Yuanping Yang: Formal analysis, Investigation, Writing - Original Draft. Guorui Liu: Conceptualization, Investigation, Writing - Review & Editing. Minghui Zheng: Resources, Writing - Review & Editing, Supervision. Guanglong Wu: Investigation, Project administration. Cheng Jiang: Project administration. Jiahong Xie: Investigation. Minxiang Wang: Investigation, Methodology. Cui Li: Investigation, Methodology. Lili Yang: Data Curation, Formal analysis. Qingjie Wang: Data Curation, Methodology.

Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: