EU-SICHERHEITSDATENBLATT Dieselkraftstoff ... - Schmierstoffe

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Vacuum Gas Oils, Hydrocracked Gas Oils, and Distillate Fuels which are likely to lead to substantial aerosol release, e.g. spraying. E4 Bulk transfers (closed No other specific measures identified EI20 systems) CS14, CS107 Bulk transfers (open Wear suitable gloves tested to EN374 PPE15 systems) CS14, CS108 Material transfers CS3 Wear suitable gloves tested to EN374. PPE15 Bulk weighing CS91 Wear suitable gloves tested to EN374.PPE15 No other specific measures identified EI20 Small scale weighing CS90 Wear suitable gloves tested to EN374 PPE15 Additive pre-mixing CS92 Wear suitable gloves tested to EN374.PPE15 Calendaring (including Handle substance within a predominantly closed system provided with Banburys) CS64 extract ventilation E49 Wear suitable gloves tested to EN374 PPE15 Pressing uncured rubber Wear suitable gloves tested to EN374 PPE15 blanks CS73 Tyre build-up CS112 Minimise exposure by extracted full enclosure for the operation or equipment E61 Wear suitable gloves (tested to EN374), coverall and eye protection PPE23 Vulcanisation CS70 Provide extract ventilation to material transfer points and other openings E82 Cooling cured articles CS71 Minimise exposure by partial enclosure of the operation or equipment and provide extract ventilation at openings E60 Production of articles by Wear suitable gloves tested to EN374 PPE15 dipping and pouring CS113 Finishing operations CS102 Wear suitable gloves tested to EN374 PPE15 Laboratory activities CS36 No other specific measures identified EI20 Equipment clean down and Drain or remove substance from equipment prior to break-in or maintenance CS39 maintenance E81 Wear chemically resistant gloves (tested to type EN374) in combination with ‘basic’ employee training PPE16 Storage CS67 Store substance within a closed system. E84 Additional information on the basis for the allocation of the identified OCs and RMMs is contained in Appendices 2 to 3 Section 2.2 Control of environmental exposure Product characteristics Substance is complex UVCB [PrC3]. Predominantly hydrophobic [PrC4a]. Amounts used Fraction of EU tonnage used in region 0.1 Regional use tonnage (tonnes/year) 1.6e4 Fraction of Regional tonnage used locally 1 Annual site tonnage (tonnes/year) 1.6e4 Maximum daily site tonnage (kg/day) 5.2e4 Frequency and duration of use Continuous release [FD2]. Emission days (days/year) 300 Environmental factors not influenced by risk management Local freshwater dilution factor 10 Local marine water dilution factor 100 Other given operational conditions affecting environmental exposure Release fraction to air from process (initial release prior to RMM) 0.01 Release fraction to wastewater from process (initial release prior to 3.0e-5 RMM) Release fraction to soil from process (initial release prior to RMM) 0.0001 Technical conditions and measures at process level (source) to prevent release Common practices vary across sites thus conservative process release estimates used [TCS1]. Technical onsite conditions and measures to reduce or limit discharges, air emissions and releases to soil 2010-07-30 CSR 179

Vacuum Gas Oils, Hydrocracked Gas Oils, and Distillate Fuels Risk from environmental exposure is driven by freshwater sediment [TCR1b]. If discharging to domestic sewage treatment plant, no onsite wastewater treatment required [TCR9]. Treat air emission to provide a typical removal efficiency of (%) 0 Treat onsite wastewater (prior to receiving water discharge) to provide 52.8 the required removal efficiency (%) If discharging to domestic sewage treatment plant, provide the required 0 onsite wastewater removal efficiency of (%) Organisation measures to prevent/limit release from site Prevent discharge of undissolved substance to or recover from wastewater [OMS1]. Do not apply industrial sludge to natural soils [OMS2]. Sludge should be incinerated, contained or reclaimed [OMS3]. Conditions and measures related to municipal sewage treatment plant Estimated substance removal from wastewater via domestic sewage 94.1 treatment (%) Total efficiency of removal from wastewater after onsite and offsite 94.1 (domestic treatment plant) RMMs (%) Maximum allowable site tonnage (M Safe ) based on release following total 4.2e5 wastewater treatment removal (kg/d) Assumed domestic sewage treatment plant flow (m 3 /d) 2000 Conditions and measures related to external treatment of waste for disposal External treatment and disposal of waste should comply with applicable regulations [ETW3]. Conditions and measures related to external recovery of waste External recovery and recycling of waste should comply with applicable regulations [ERW1]. Additional information on the basis for the allocation of the indentified OCs and RMMs is contained in PETRORISK file. Section 3 Exposure Estimation 3.1. Health The ECETOC TRA tool has been used to estimate workplace exposures unless otherwise indicated. G21. 3.2. Environment The Hydrocarbon Block Method has been used to calculate environmental exposure with the Petrorisk model [EE2]. Section 4 Guidance to check compliance with the Exposure Scenario 4.1. Health Predicted exposures are not expected to exceed the DN(M)EL when the Risk Management Measures/Operational Conditions outlined in Section 2 are implemented. G22. Where other Risk Management Measures/Operational Conditions are adopted, then users should ensure that risks are managed to at least equivalent levels. G23. Available hazard data do not enable the derivation of a DNEL for dermal irritant effects. G32. Available hazard data do not support the need for a DNEL to be established for other health effects. G36. Risk Management Measures are based on qualitative risk characterisation. G37. 4.2. Environment Guidance is based on assumed operating conditions which may not be applicable to all sites; thus, scaling may be necessary to define appropriate site-specific risk management measures [DSU1]. Required removal efficiency for wastewater can be achieved using onsite/offsite technologies, either alone or in combination [DSU2]. Required removal efficiency for air can be achieved using onsite technologies, either alone or in combination [DSU3]. Further details on scaling and control technologies are provided in SpERC factsheet (http://cefic.org/en/reach-for-industries-libraries.html) [DSU4]. 2010-07-30 CSR 180

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Page 165 and 166: This tool is provided for informati

Page 167 and 168: An Evaluation of the Persistence, B

Page 169 and 170: Table of Contents Executive Summary

Page 171 and 172: 2.0 Outline of PBT/vPvB Assessment

Page 173 and 174: 3.0 Persistence Assessment of Petro

Page 175 and 176: 100.0 Half-life predicted (days) 10

Page 177 and 178: 2,3-dimethylheptane 9 7.7 6.2 7.4 2

Page 179 and 180: ioHCwin half-life (days) 10000.0 10

Page 181 and 182: criterion. It can be concluded that


Page 185 and 186: Hydrocarbon C nr BioHCwin Predicted

Page 187 and 188: ioHCwin half-life (days) 1000000.0


Page 191 and 192: Hydrocarbon C nr BioHCwin Predicted

Page 193 and 194: enzo[a]pyrene 20 421.6 16.5 Table 1

Page 195 and 196: (see Appendix 2). Since BCF predict

Page 197 and 198: 10000 BCF (Arnot) 1000 100 10 1 n-P

Page 199 and 200: exhibit BMFs near unity (Figure 28)

Page 201 and 202: 2,2,4,4,6,8,8- heptamethyl nonane 1

Page 203 and 204: Hydrocarbon C BMF BCF (Arnot) Dieta

Page 205 and 206: BCF (regression) 100000 10000 1000

Page 207 and 208: 4.5 Polynaphthenic hydrocarbons Reg

Page 209 and 210: Experimental BMF 10 1 Polynaphth. D

Page 211 and 212: enzene n-octylbenzene 14 0.034 403

Page 213 and 214: 10000 1000 BCF (Arnot) 100 10 1 NMA

Page 215 and 216: and appears to be an outlier. This

Page 217 and 218: 4-ethylbiphenyl 14 863 1039 C Yakat

Page 219 and 220: 100000 BCF (regression) 10000 1000

Page 221 and 222: 10 Experimental BMF 1 0.1 NDiAr Die

Page 223 and 224: Hydrocarbon C BMF Arnot BCF Dietary

Page 225 and 226: Hydrocarbon C BMF Arnot BCF Dietary

Page 227 and 228: Acenaphthene Acenaphthylene Benz(a)

Page 229 and 230: 5.0 Summary of Persistence and Bioa

Page 231 and 232: lower water solubility, it is possi

Page 233 and 234: properties of petroleum hydrocarbon

Page 235 and 236: 8.0 References Anonymous (2004). Fi

Page 237 and 238: EMBSI (2007c). Fish, dietary bioacc

Page 239 and 240: Prince RC, Walters CC. (2007). Biod

Page 241 and 242: Appendix 1. Hydrocarbon structures

Page 243 and 244: iP 14 2,4,10-Trimethylundecane CC(C

Page 245 and 246: MN 7 1,2-Dimethylcyclopentane CC1C(

Page 247 and 248: MN 14 n-Nonylcyclopentane CCCCCCCCC

Page 249 and 250: MN 29 MN 29 MN 30 n-Tetracosylcyclo

Page 251 and 252: hexahydroindane DN 20 2,4-dimethylo

Page 253 and 254: PN 27 Phenanthrene 2,6-dimethylhept

Page 255 and 256: MAr 13 1-Methyl-3-hexylbenzene Cc1c

Page 257 and 258: NMAr 12 n-Propylindan c1ccc2CC(CCC)

Page 259 and 260: NMAr 24 c1cc(CC(C)CCCC(C)CCCCC)c2CC

Page 261 and 262: NMAr 29 NMAr 29 NMAr 29 NMAr 29 NMA

Page 263 and 264: DAr 16 2-Hexylnaphthalene CCCCCCc1c

Page 265 and 266: NDAr 16 n-Butylacenaphthene c12cccc

Page 267 and 268: NDAr 26 Dimethyloctyl-1,2,3,6,7,8-

Page 269 and 270: PAr 19 Ethylbenzo(a)fluorene C3c1cc

Page 271 and 272: PAr 22 n-Pentylbenzo(a)fluorene C3c

Page 273 and 274: PAr 28 Isohexyl-octadecahydro-picen

Page 275 and 276: Appendix 3. CONCAWE Position Paper

Page 277 and 278: probabilities are adjusted to best

Page 279 and 280: 1.2.2 OASIS LMC Models: Toxicologic

Page 281 and 282: environmental chemicals (database o

Page 283 and 284: dihydrodiol. These dihydroxylated i

Page 285 and 286: Table 1 : PBT assessment of C15 str

Page 287 and 288: 1: The following structures were pr

Page 289 and 290: Dimitrov SD, Dimitrova N, Mekenyan

Page 291 and 292: hydrocarbons and azaarenes original

Page 293 and 294: Verhaar HJM, van Leeuwen CJ, Hermen

Page 295 and 296: CONCAWE AQUATIC TOXICITY PREDICTION

Page 297 and 298: CONTENTS (Continued) Section Page 1

Page 299 and 300: 1-2 The model predictions include m

Page 301 and 302: 2-1 SECTION 2 2 SUMMARY OF COMPOSIT




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