Environmental and Occupational Health Practice
Online ISSN : 2434-4931
Recommendation of occupational exposure limits (2020-2021)
Recommendation of occupational exposure limits (2020–2021)
The Japan Society for Occupational Health May 25, 2020
Author information
JOURNAL FREE ACCESS FULL-TEXT HTML

2020 Volume 2 Issue 1 Article ID: ROEL2020

Browse “Advance online publication” version
J-STAGE : eohp 3 1 3.E1
Details
Download PDF (783K)
Download citation RIS

(compatible with EndNote, Reference Manager, ProCite, RefWorks)

BIB TEX

(compatible with BibDesk, LaTeX)

Text
How to download citation
Contact us
Abstract

The Japan Society for Occupational Health (JSOH) recommends the Occupational Exposure Limits (OELs) as reference values for preventing adverse health effects on workers caused by occupational exposure to chemical substances, continuous or intermittent noise, impulsive or impact noise, heat stress, cold stress, whole-body vibration, hand-arm vibration and time-varying electric, magnetic and electromagnetic fields and ultraviolet and ionizing radiation.

Characteristics of OELs and Instructions for Users

1. OELs should be applied by individuals well-trained and experienced in occupational health.

2. OELs cannot be applied in cases where exposure duration or work intensity exceeds the prerequisite conditions for setting an OEL.

3. OELs are set based on various information obtained from experiences in industries and experiments on humans and animals. However, the quantity and quality of information used in setting OELs is not always the same.

4. Types of health effects considered in setting OELs depend on the substances involved; an explicit health impairment provides the basis for OELs in certain substances, while health effects such as discomfort, irritation or CNS suppressive effects afford the basis in others. Thus, OELs cannot be used simply as a relative scale of toxicity.

5. Due to the variance in individual susceptibilities, discomfort, deterioration of pre-existing ill health or occupational disease may be induced at levels of exposure below the OELs, even though the chances of this should be remote.

6. Because OELs do not represent a definitive borderline between safe and hazardous conditions, it is not correct to conclude that working environments above OEL are the direct and sole cause of health impairment in workers, or vice versa.

7. OELs cannot be applied as reference values in non-occupational environments.

8. OELs will be revised when JSOH considers it necessary.

9. JSOH welcomes the submission, by concerned parties or individuals, of opinions based on scientific aspects of OELs.

10. In the reproduction of any Tables and/or Figures of OELs, JSOH requires that the full text of OELs be quoted to prevent misunderstanding and misuse.

I. Occupational Exposure Limits for Chemical Substances

1. Definitions

Exposure concentration is defined as the concentration of a chemical substance in air which will be inhaled by a worker during a job without the use of protective respiratory equipment.

Occupational Exposure Limit-Mean (OEL-M) for mean concentration of a chemical substance is defined as the reference value to the mean exposure concentration at or below which adverse health effects caused by the substance do not appear in most workers working for 8 hours a day, 40 hours a week under a moderate work-load. Exposure above OEL-M should be avoided even where duration is short or work intensity is light. If mean levels and duration of exposure corresponding to segments of various jobs can be measured or estimated, then an overall exposure concentration can be determined as the time-weighted average concentration.

Occupational Exposure Limit-Ceiling (OEL-C) of occupational exposure to a chemical substance is defined as the reference value to the maximal exposure concentration of the substance during a working day at or below which adverse health effects do not appear in most workers. The main reason why OEL-C is recommended for some substances is that the toxicity in question can induce immediate adverse effects such as irritation or CNS suppressive effects. However, it is quite difficult in practice to measure the momentary maximal exposure concentration. Short-term measurement lasting for 5 minutes or less at the time when the highest exposure concentration is expected may be used as a substitute for the measurement of maximal exposure concentration.

2. Variability of exposure concentration

Exposure concentration fluctuates around the mean value. OEL-M should be referred to only when the fluctu-ation is not large. Allowable range of fluctuation depends on the substance. In practical terms, the mean exposure concentration for a period of 15 minutes during which maximum exposure concentration is expected should not exceed 1.5 times OEL-M, unless otherwise notified.

3. Skin absorption

“S” marks in Tables I-1 and I-2 show that a significant dose from the view of systemic health effects or absorption of the substance concerned may be absorbed through the skin when the substance is in contact with the skin. OELs are set at conditions under which no skin absorption will take place.

Table I-1. Occupational exposure limits for chemical substances
Substance [CAS No.]OELSkin
absorption		Class of
carcino-
genicity		Class of
sensitizing
potential		Reproductive ToxicantsYear of proposal
ppmmg/m3AirwaySkin
Acetaldehyde [75-07-0]50*90*2Bʼ90
Acetic acid [64-19-7]1025ʼ78
Acetic anhydride [108-24-7]5*21*ʼ90
Acetone [67-64-1]200470ʼ72
Acrylaldehyde [107-02-8]0.10.23ʼ73
Acrylamide [79-06-1]0.1S2A22ʼ04
Acrylonitrile [107-13-1]24.3S2Aψʼ88
Allyl alcohol [107-18-6]12.4Sʼ78
2-Aminoethanol [141-43-5]37.5ʼ65
Ammonia [7664-41-7]2517ʼ79
Aniline [62-53-3]13.8S1ʼ88
o-Anisidine [90-04-0]0.10.5S2Bʼ96
p-Anisidine [104-94-9]0.10.5Sʼ96
Antimony and compounds (as Sb except stibine) [7440-36-0]0.1(ʼ13)
Arsenic and compounds (as As) [7440-38-2](Table III-2)11ʼ00
Arsine [7784-42-1]0.010.032ʼ92
0.1*0.32*
Atrazine [1912-24-9]23ʼ15
Benomyl [17804-35-2]122#ʼ18
Benzene [71-43-2](Table III-2)S1ʼ97
Benzyl alcohol [100-51-6]25*2’19
Beryllium and compounds (as Be) [7440-41-7]0.0021ψ12ʼ63
Boron trifluoride [7637-07-2]0.30.83ʼ79
Bromine [7726-95-6]0.10.65ʼ64
Bromoform [75-25-2]110.3ʼ97
1-Bromopropane [106-94-5]0.52.52B2ʼ12
2-Bromopropane [75-26-3]15S1ʼ99
Buprofezin [69327-76-0]2ʼ90
Butane (all isomers) [106-97-8]5001,200ʼ88
1-Butanol [71-36-3]50*150*Sʼ87
2-Butanol [78-92-2]100300ʼ87
Butyl acetate [123-86-4]100475ʼ94
t-Butyl alcohol [75-65-0]50150ʼ87
Butylamine [109-73-9]5*15*S(ʼ94)
n-butyl-2,3-epoxy-propyl ether [2426-08-6]0.251.32B23ʼ16
Cadmium and compounds (as Cd) [7440-43-9]0.051ψ1ʼ76
Calcium cyanide (as CN) [592-01-8]5*Sʼ01
Carbaryl [63-25-2]5Sʼ89
Carbon dioxide [124-38-9]5,0009,000ʼ74
Carbon disulfide [75-15-0]13.13S1#ʼ15
Carbon monoxide [630-08-0]50571ʼ71
Carbon tetrachloride [56-23-5]531S2Bʼ91
Chlorine [7782-50-5]0.5*1.5*ʼ99
Chlorobenzene [108-90-7]1046ʼ93
Chlorodifluoromethane [75-45-6]1,0003,5002ʼ87
Chloroethane [75-00-3]100260ʼ93
Chloroform [67-66-3]314.7S2Bʼ05
Chloromethane [74-87-3]501002ʼ84
Chloromethyl methyl ether (technical grade) [107-30-2]2Aʼ92
Chloropicrin [76-06-2]0.10.67ʼ68
Chromium and compounds (as Cr) [7440-47-3]213ʼ89
 Chromium metal0.5
 Chromium (III) compounds0.5
 Chromium (VI) compounds0.05
 Certain chromium (VI) compounds0.011
Cobalt and compounds (without tungsten carbide) [7440-48-4]0.052B11ʼ92
Cresol (all isomers)522Sʼ86
Cumene [98-82-8]1050S2Bʼ19
Cyclohexane [110-82-7]150520ʼ70
Cyclohexanol [108-93-0]25102ʼ70
Cyclohexanone [108-94-1]25100ʼ70
Diazinon [333-41-5]0.1S2Bʼ89
Diborane [19287-45-7]0.010.012ʼ96
Dibutyl phthalate [84-74-2]52ʼ96
o-Dichlorobenzene [95-50-1]25150ʼ94
p-Dichlorobenzene [106-46-7]10602B3ʼ98
1,4-Dichloro-2-butene [764-41-0]0.0022Bʼ15
3,3’-Dichloro-4,4’-diaminodiphenylmethane (MBOCA) [101-14-4]0.005S2Aψʼ12
Dichlorodifluoromethane [75-71-8]5002,500ʼ87
1,1-Dichloroethane [75-34-3]100400ʼ93
1,2-Dichloroethane [107-06-2]10402Bʼ84
2,2’-Dichloroethyl ether [111-44-4]1588Sʼ67
1,2-Dichloroethylene [540-59-0]150590ʼ70
Dichloromethane [75-09-2]50170S2Aʼ99
100*340*
2,4-Dichlorophenoxyacetic acid (2,4-D) [94-75-7]2S2’19
1,2-Dichloropropane [78-87-5]14.612ʼ13
2,2-Dichloro-1,1,1-trifluoroethane [306-83-2]1062ʼ00
Diethylamine [109-89-7]1030ʼ89
Di(2-ethylhexyl) phthalate [117-81-7]52B1#ʼ95
Diethyl phthalate [84-66-2]5ʼ95
N,N-Dimethyl acetamide [127-19-5]1036S2B2ʼ90
Dimethylamine [124-40-3]23.73ʼ16
N,N-Dimethylaniline [121-69-7]525Sʼ93
N,N-Dimethylformamide (DMF) [68-12-2]1030S2B2ʼ74
Dimethyl sulfate [77-78-1]0.10.52S2Aψʼ80
Dimethyl terephthalate [120-61-6](Table I-2)ʼ20
1,2-Dinitrobenzene [528-29-0]0.151Sʼ94
1,3-Dinitrobenzene [99-65-0]0.151Sʼ94
1,4-Dinitrobenzene [100-25-4]0.151Sʼ94
1,4-Dioxane [123-91-1]13.6S2Bʼ15
Diphenylmethane-4,4’-diiso-cyanate (MDI) [101-68-8]0.051ʼ93
Dusts(Table I-3)
2,3-Epoxypropyl methacrylate (Glycidyl methacrylate, GMA) [106-91-2]0.010.06S2A23ʼ18
Ethyl acetate [141-78-6]200720ʼ95
Ethylamine [75-04-7]1018ʼ79
Ethylbenzene [100-41-4](Table I-2)S2B2ʼ20
Ethylenediamine [107-15-3]1025S22ʼ91
Ethylene glycol monobutyl ether [111-76-2]20*97*S2ʼ17
Ethylene glycol monoethyl ether [110-80-5]518S2ʼ85
Ethylene glycol monoethyl ether acetate [111-15-9]527S2ʼ85
Ethylene glycol monomethyl ether [109-86-4]0.10.31S1ʼ09
Ethylene glycol monomethyl ether acetate [110-49-6]0.10.48S1ʼ09
Ethylene oxide [75-21-8]11.81ψ21ʼ90
Ethylenimine [151-56-4]0.050.09S2B3ʼ18
Ethyl ether [60-29-7]4001,200(ʼ97)
2-Ethy1-1-hexanol [104-76-7]15.33ʼ16
Ethylidene norbornene [16219-75-3]2103ʼ18
Etofenprox [80844-07-1]3ʼ95
Fenitrothion [122-14-5]1Sʼ81
Fenobucarb [3766-81-2]5Sʼ89
Fenthion [55-38-9]0.2Sʼ89
Flutolanil [66332-96-5]10ʼ90
Formaldehyde [50-00-0]0.10.122A21ʼ07
0.2*0.24*
Formic acid [64-18-6]59.4ʼ78
Fthalide [27355-22-2]10ʼ90
Furfural [98-01-1]2.59.8S(ʼ89)
Furfuryl alcohol [98-00-0]5202Bʼ78
Gasoline [8006-61-9]100b300b2Bʼ85
Glutaraldehyde [111-30-8]0.03*11ʼ06
Heptane [142-82-5]200820ʼ88
Hexachlorobutadiene [87-68-3]0.010.12Sʼ13
Hexane [110-54-3]40140Sʼ85
Hexane-1,6-diisocyanate (HDI) [822-06-0]0.0050.0341ʼ95
Hydrazine (anhydrous) and Hydrazine hydrate [302-01-2/7803-57-8]0.10.13
and 0.21		S2A1ʼ98
Hydrogen chloride [7647-01-0]2*3.0*ʼ14
Hydrogen cyanide [74-90-8]55.5Sʼ90
Hydrogen fluoride [7664-39-3](Table I-2)S(ʼ20)
Hydrogen selenide [7783-07-5]0.050.17ʼ63
Hydrogen sulfide [7783-06-4]57ʼ01
Indium and compounds [7440-74-6](Table II-1)2Aʼ07
Iodine [7553-56-2]0.112ʼ68
Isobutyl alcohol [78-83-1]50150ʼ87
Isopentyl alcohol [123-51-3]100360ʼ66
Isoprene [78-79-5]38.42Bʼ17
Isopropyl acetate [108-21-4]100ʼ17
Isopropyl alcohol [67-63-0]400*980*ʼ87
Isoprothiolane [50512-35-1]5ʼ93
Lead and compounds (as Pb except alkyl lead compounds) [7439-92-1]0.032B1#ʼ16
Lithium hydroxide [1310-65-2]1ʼ95
Malathion [121-75-5]10S2Bʼ89
Maleic anhydride [108-31-6]0.10.422(ʼ15)
0.2*0.8*
Manganese and compounds (as Mn except organic compounds) [7439-96-5]0.22ʼ08
Man-made mineral fibers**ʼ03
 Ceramic fibers, Micro glass fibers2B
 Continuous filament glass fibers,1 (fiber/ml)
 Glass wool fibers, Rock wool fibers, Slag wool fibers
Mepronil [55814-41-0]5ʼ90
Mercury vapor [7439-97-6]0.0252ʼ98
Methacrylic acid [79-41-4]27.0ʼ12
Methanol [67-56-1]200260S2ʼ63
Methyl acetate [79-20-9]200610ʼ63
Methyl acrylate [96-33-3]272B2ʼ04
Methylamine [74-89-5]56.5ʼ19
Methyl bromide [74-83-9]13.89Sʼ03
Methyl n-butyl ketone [591-78-6]520Sʼ84
Methylcyclohexane [108-87-2]4001,600ʼ86
Methylcyclohexanol [25639-42-3]50230ʼ80
Methylcyclohexanone [1331-22-2]50230Sʼ87
Methyl methacrylate [80-62-6]8.322ʼ12
4,4’-Methylenedianiline [101-77-9]0.4S2Bʼ95
Methyl ethyl ketone [78-93-3]200590ʼ64
Methyl isobutyl ketone [108-10-1]502002Bʼ84
N-Methyl-2-pyrrolidone [872-50-4]14Sʼ02
Methyltetrahydrophthalic anhydride [11070-44-3]0.0070.051ʼ02
0.015*0.1*
Nickel [7440-02-0]1213ʼ11
Nickel carbonyl [13463-39-3]0.0010.007ʼ66
Nickel compounds (total dusts) (as Ni) [7440-02-0],2B3ʼ11
 Nickel compounds, soluble0.01ʼ11
 Nickel compounds, not soluble0.1ʼ11
Nickel smelting dusts [7440-02-0](Table III-2)1ʼ11
Nitric acid [7697-37-2]25.2ʼ82
p-Nitroaniline [100-01-6]3Sʼ95
Nitrobenzene [98-95-3]15S2B(ʼ88)
p-Nitrochlorobenzene [100-00-5]0.10.64Sʼ89
Nitrogen dioxide [10102-44-0](pending)ʼ61
Nitroglycerin [55-63-0]0.05*0.46*Sʼ86
Nitroglycol [628-96-6]0.050.31Sʼ86
Nonane [111-84-2]2001,050ʼ89
Octane [111-65-9]3001,400ʼ89
Oil mist, mineral31ψʼ77
Ozone [10028-15-6]0.10.2ʼ63
Parathion [56-38-2]0.1S(ʼ80)
Pentachlorophenol [87-86-5]0.5S2(ʼ89)
Pentane [109-66-0]300880ʼ87
Pentyl acetate, all isomers [628-63-7; 123-92-2; 626-38-0; 620-11-1; 625-16-1; 624-41-9; 926-41-0]50266.3ʼ08
100*532.5*
Perfluorooctanoic acid [335-67-1]0.005c2B1#ʼ08
Phenol [108-95-2]519S3ʼ78
m-Phenylenediamine [108-45-2]0.13ʼ99
o-Phenylenediamine [95-54-5]0.12B3ʼ99
p-Phenylenediamine [106-50-3]0.11ʼ97
Phosgene [75-44-5]0.10.4ʼ69
Phosphine [7803-51-2]0.3*0.42*ʼ98
Phosphoric acid [7664-38-2]1(ʼ90)
Phosphorus (yellow) [7723-14-0]0.1(ʼ88)
Phosphorus pentachloride [10026-13-8]0.10.85ʼ89
Phosphorus trichloride [7719-12-2]0.21.1ʼ89
Phthalic anhydride [85-44-9]0.33*2*1ʼ98
o-Phthalodinitrile [91-15-6]0.01Sʼ09
Picric acid2ʼ14
Platinum, soluble salts (as Pt) [7440-06-4]0.00111ʼ00
Polychlorobiphenyls0.01S1ψ1ʼ06
Potassium cyanide (as CN) [151-50-8]5*Sʼ01
Potassium hydroxide [1310-58-3]2*ʼ78
Propyl acetate [109-60-4]200830ʼ70
Propyleneimine (2-Methylaziridine)0.20.45S2Bʼ17
Pyridaphenthion [119-12-0]0.2Sʼ89
Rhodium (soluble compounds, as Rh) [7440-16-6]0.0012ʼ07
Selenium and compounds (as Se, except SeH2 and SeF6) [7782-49-2]0.1ʼ00
Silane [7803-62-5]100*130*ʼ93
Silicon carbide whisker [409-21-2; 308076-74-6]0.1
(fiber/ml)		2A’19
Silver and compounds (as Ag) [7440-22-4]0.01ʼ91
Sodium cyanide (as CN) [143-33-9]5*Sʼ01
Sodium hydroxide [1310-73-2]2*ʼ78
Styrene [100-42-5]2085S2B2ʼ99
Sulfur dioxide [7446-09-5](pending)ʼ61
Sulfuric acid [7664-93-9]1*ʼ00
Sulfur monochloride [10025-67-9]1*5.5*ʼ76
1,1,2,2-Tetrachloroethane [79-34-5]16.9S2Bʼ84
Tetrachloroethylene [127-18-4](pending)S2B3ʼ72
Tetraethoxysilane [78-10-4]1085ʼ91
Tetraethyl lead (as Pb) [78-00-2]0.075Sʼ65
Tetrahydrofuran [109-99-9]501482BSʼ15
Tetramethoxysilane [681-84-5]16ʼ91
Thiuram [137-26-8]0.11ʼ08
Titanium dioxide (nanoparticle, as Ti) [13463-67-7]0.32Bʼ13
Toluene [108-88-3]50188S1(ʼ13)
Toluene diisocyanates [26471-62-5]0.0050.0352B12ʼ92
0.02*0.14*
Trichlorhon [52-68-6]0.2Sʼ10
o-Toluidine [95-53-4]14.4S1ψʼ91
1,1,1-Trichloroethane [71-55-6]2001,100ʼ74
1,1,2-Trichloroethane [79-00-5]1055S(ʼ78)
Trichloroethylene [79-01-6]251351ψ13ʼ15
Trichlorofluoromethane [75-69-4]1,000*5,600*ʼ87
1,1,2-Trichloro-1,2,2-trifluoroethane [76-13-1]5003,800ʼ87
Tricyclazole [41814-78-2]3ʼ90
Trimellitic anhydride [552-30-7]0.00051Sʼ15
0.004*
1,2,3-Trimethylbenzene [526-73-8]25120ʼ84
1,2,4-Trimethylbenzene [95-63-6]25120ʼ84
1,3,5-Trimethylbenzene [108-67-8]25120ʼ84
Trinitrotoluene (all isomers)0.1Sʼ93
Turpentine502801ʼ91
Vanadium compounds2
 Ferrovanadium dust [12604-58-9]1ʼ68
 Vanadium pentoxide [1314-62-1]0.052Bʼ03
Vinyl chloride [75-01-4](Table III-2)1ψʼ17
Xylene (all isomers and their mixture)50217ʼ01
 Xylene for industrial use2
 Xylene (ortho-, meta-, para-xylene and their mixture)3
Zinc oxide fume [1314-13-2](pending)ʼ69

1. ppm: parts of vapors and gases per million of substance in air by volume at 25°C and atmospheric pressure (760 torr, 1,013 hPa); OELs in ppm are converted to those in mg/m3, in which the values are rounded off to 2 significant digits.

2. ( ) in the year of proposal column indicates that revision was done in the year without change of the OEL value.

3. *: Occupational Exposure Limit-Ceiling; exposure concentration must be kept below this level.

 **: Fibers longer than 5 μm and with an aspect ratio equal to or greater than 3:1 as determined by the membrane filter method at 400×magnification phase contrast illumination.

ψ: Substance whose OEL is set based on non-carcinogenic health effects; see III.

a: Exposure concentration should be kept below a detectable limit though OEL is set at 2.5 ppm provisionally.

b: OEL for gasoline is 300 mg/m3, and an average molecular weight is assumed to be 72.5 for conversion to ppm units.

c: Not applicable to women of child bearing potential.

#: Precaution should be taken for exposure lower than the OEL-M or OEL-B. As for reproductive toxicity, it is generally known that there is a sensitive period, during pregnancy for example, and such effects of this substance have been identified.

: Provisional.

Table I-2. Occupational exposure limits for chemical substances (Provisional)
Substance [CAS No.]OELSkin absorptionClass of
carcinogenicity		Class of sensitizing potentialReproductive ToxicantsYear of proposal
ppmmg/m3AirwaySkin
Dimethyl terephthalate [120-61-6]8’20
Ethylbenzene [100-41-4]2087S2B2’20
Hydrogen fluoride [7664-39-3]3*2.5*S(’20)

See the JSOH’S web site for a brief summary of OEL documentation at http://sanei.or.jp

*: Occupational Exposure Limit-Ceiling; exposure concentration must be kept below this level.

Table I-3. Occupational exposure limits for dustsa
I. Respirable crystalline silicaψ, *
 OEL-C 0.03 mg/m3
II. Dusts other than I
DustsOEL (mg/m3)
Respirable dust*Total dust**
Class 1Activated charcoal, Alumina, Aluminum, Bentonite, Diatomite, Graphite, Kaolinite, Pagodite, Pyrites, Pyrite cinder, Talc0.52
Class 2Dusts containing less than 3% cry stalline silica, Bakelite, Carbon black, Coal, Cork dust, Cotton dust, Iron oxide, Grain dust, Joss stick material dust, Marble, Portland cement, Titanium oxide, Zinc oxide14
Class 3Limestone, Inorganic and organic dusts other than Classes 1 and 2b28
Asbestos***(Table III-2)

1. a, OELs for dusts are set to prevent from Class 2 pneumoconiosis, while no other toxicities are considered

 b, OEL for ‘inorganic and organic dusts other than Classes 1 and 2’ is a reference value assigned for dusts that are insoluble or poorly soluble in water to prevent from pneumoconiosis caused by inhaling large amount of those; thus, be aware that unknown toxocity may be developed even below this value

2.*: Respirable crystalline silica and respirable dust consist of particles captured by the following collection efficiency, R (dae).

R (dae)=0.5[1+exp (–0.06dae)] [1–F (x)]

 dae: aerodynamic diameter of particle (μm), F (x): cumulative distribution function of the standardized normal variable

   x=ln(dae/Γ)/ln(Σ), ln natural logarithm, Γ=4.25 μm, Σ=1.5

 **: Total dust comprises particles with a flow speed of 50 to 80 cm/sec at the entry of a particle sampler.

 ***: Fibers longer than 5 μm and with an aspect ratio equal to or greater than 3:1 as determined by the membrane filter method at 400×magnification (4 mm objective) phase contrast illumination.

3. : Do not include asbestos nor ≥1% crystalline silica.

4. ψ: Substance whose OEL is set based on non-carcinogenic health effects; see III.

5. OEL for wood dust is under consideration.

4. Interaction with other working conditions

Other working conditions, such as work intensity, heat stress and abnormal atmospheric pressure, must be considered, since their co-existence could cause an increase in the inhaled dose of a chemical substance, thereby intensifying its effects on workers’ health.

5. OEL for exposure to mixture of chemical substances

OEL-M values listed in Table I-1 and I-2 are applicable in cases where the substance exists alone. When workers are exposed to a mixture of chemical substances and there is no reliable evidence to the contrary that the effects of the chemicals are assumed to be additive, the effects should be assumed as additive.

The users should refer not to each OEL-M value, but rather to the following equation:

I=C1/T1+C2/T2+...+Ci/Ti+...+Cn/Tn

Ci=mean exposure concentration for each component i

Ti=OEL-M for each component i

Any value of I exceeding 1 indicates an exposure that is above OEL.

II. Occupational Exposure Limits Based on Biological Monitoring

1. Definition

Biological monitoring in the occupational setting consists of (1) measuring the concentration of a chemical substance or its metabolite (s) in biological specimens, and/or (2) determining early health effects by using biological specimens which are predictors or warning signs of the occurrence of adverse health effects.

Occupational Exposure Limit Based on Biological Monitoring (OEL-B) is defined as the reference values to the data obtained by biological monitoring at or below (depending on agents, above) which the adverse health effects do not appear in most workers who are exposed to the chemical substances.

2. Characteristics of OEL-B

(1) In setting OEL-B, consideration is given to the exposure-effect and/or exposure-response relationships between biological monitoring values and health effects, or to the relationship between biological monitoring values and OEL-Ms.

(2) There is a possibility that exposure concentration of chemical substances in the workplace will not closely associate with biological monitoring values due to various factors, e.g., intra- and inter-individual variation in metabolism, social habits such as smoking and alcohol consumption, working conditions, working time, skin absorption, use of personal protective equipment, and possible exposure to the substances outside the workplace. Biological monitoring values could exceed OEL-B even though exposure to the chemical substances is below OEL-M, and vice versa. Both OEL-M and OEL-B must be satisfied at the workplace.

(3) Biological specimens should be collected at the time that is most likely to represent the particular exposure to the substances concerned, or at the time most likely to predict occurrence of the particular adverse health effects. Only biological monitoring values measured under this condition can be referred to OEL-B.

(4) OEL-B is applied to cases of single-substance absorption. For exposure to a mixture of substances, interactions in terms of absorption, metabolism, accumulation, excretion and health effects must also be considered.

Table II-1. Occupational exposure limits based on biological monitoring
SubstanceAssay materialParameterOEL-BSampling timeYear of proposal
AcetoneurineAcetone40 mg/lWithin 2 h prior to end of shiftʼ01
2-Butoxyethanol and 2-Butoxyethyl acetateurineButoxyacetic acid200 mg/g·CrEnd of shiftʼ08
Carbon disulfideurine2-thiothiazolidine-4-carboxylic acid0.5 mg/g·CrEnd of shift (Avoid sizable intake of brassica vegetables)ʼ15
Cobalt and inorganic compounds (except cobalt oxides)bloodCobalt3 μg/lWithin 2 h prior to end of shift at end of work weekʼ05
urineCobalt35 μg/lWithin 2 h prior to end of shift at end of work weekʼ05
Chlorobenzeneurine4-Chlorocatechol (hydrolysis)120 mg/g·CrEnd of shiftʼ08
3,3’-Dichloro-4,4’-diaminodiphenyl-methane (MBOCA)urinetotal MBOCA50 μg/g·CrEnd of shift at end of workweekʼ94
DichloromethaneurineDichloromethane0.2 mg/lEnd of shiftʼ05
Hexaneurine2,5-Hexanedione3 mg/g·Cr
(after acid hydrolysis)		End of shift at end of workweekʼ94
urine2,5-Hexanedione0.3 mg/g·Cr
(without acid hydrolysis)		End of shift at end of workweekʼ94
Indium and compoundsserumIndium3 μg/lNot criticalʼ07
Lead and compounds (except alkyl lead compounds)bloodLead15 μg/100 mlNot criticalʼ13
bloodProtoporphyrin200 μg/100 ml·RBCNot criticalʼ94
80 μg/100 ml·blood(After one month or more since consecutive exposure)ʼ94
urineδ-Aminolevulinic acid5 mg/lNot criticalʼ94
(After one month or more since consecutive exposure)
Mercury and compounds (except alkyl mercury compounds)urinetotal inorganic mercury35 μg/g·CrNot criticalʼ93
MethanolurineMethanol20 mg/lEnd of shiftʼ10
MethylethylketoneurineMethylethylketone5 mg/lEnd of shift or A few hours after high exposureʼ06
Methyl isobutyl ketoneurineMethyl isobutyl ketone1.7 mg/lEnd of shiftʼ07
PhenolurinePhenol250 mg/g·CrEnd of shiftʼ08
Polychlorobiphenyls (PCBs)bloodtotal PCB25 μg/lNot criticalʼ06
StyreneurineMandelic acid + Phenylglyoxylic acid430 mg/lEnd of shift at end of work weekʼ07
bloodStyrene0.2 mg/lEnd of shift at end of work weekʼ07
TetrahydrofuranurineTetrahydrofuran2 mg/lEnd of shift(ʼ15)
ToluenebloodToluene0.6 mg/lWithin 2 h prior to end of shift at end of work weekʼ99
urineToluene0.06 mg/lʼ99
Trichloroethyleneurinetotal trichloro-compounds150 mg/lWithin 2 h prior to end of shift at end of work weekʼ99
urineTrichloroethanol100 mg/lʼ99
urineTrichloroacetic acid50 mg/l
Xyleneurinetotal (o-, m-, p-) methylhippuric acid800 mg/lEnd of shift at end of work weekʼ06

: Provisional

See the JSOH website for brief summary of OEL documentation at http://sanei.or.jp/oel-eng

III. Occupational Carcinogens

JSOH classifies the occupational carcinogens based primarily on the epidemiological evidences*, but the results of the animal experiments and their extrapolation to human are also considered. The classification is made by strength of the evidence, but does not reflect the carcinogenic potency.

JSOH considers that the classification of occupational carcinogens proposed by the International Agency for Research on Cancer (IARC) is appropriate in principle. JSOH also discussed the classification of several agents based on other information sources and finalized the list of occupational carcinogens in Table III-1a, b, and c. Group 1 includes agents that are carcinogenic to humans. Group 2 indicates the agents which are probably or possibly carcinogenic to humans, classifying them into two sub-groups on the basis of degree of evidence: Group 2A is assigned to the agents with more sufficient evidence (probably carcinogenic to humans), Group 2B to those with less (possibly carcinogenic to humans).

Table III-1a. Group 1 carcinogens
SubstanceCAS No.Year of proposal
4-Aminobiphenyl92-67-1ʼ81, ʼ86
Arsenic and inorganic arsenic compounds*7440-38-2ʼ81, ʼ86, (ʼ00)
Asbestos1332-21-4ʼ81, ʼ86, (ʼ00)
Benzene71-43-2ʼ81, ʼ86, (ʼ97), (ʼ19)
Benzidine92-87-5ʼ81, ʼ86
Benzo [a] pyrene50-32-8ʼ86, ʼ17
Benzotrichloride98-07-7ʼ81, ʼ86, (ʼ01)
Beryllium and compounds*7440-41-7ʼ86, ʼ16
Bis (chloromethyl) ether542-88-1ʼ81, ʼ86
1,3-Butadiene106-99-0ʼ91, ʼ95, ʼ01
Cadmium and compounds*7440-43-9ʼ86, ʼ91, ʼ96
Chromium (VI) compounds18540-29-9ʼ81, ʼ86
Coal-tar pitch volatilesʼ81, ʼ86, (ʼ04)
Coal-tars8007-45-2ʼ81, ʼ86, (ʼ04)
1,2-Dichloropropane78-87-5ʼ13, ʼ14
Erionite12510-42-8ʼ91
Ethylene oxide75-21-8ʼ86, ʼ90, ʼ96
Ionizing radiationʼ12
Mineral oils (untreated and mildly treated)ʼ81, ʼ86, ʼ91
2-Naphthylamine91-59-8ʼ81, ʼ86
Nickel smelting dusts*7440-02-0ʼ81, ʼ86, ʼ91, (ʼ09)
Polychlorinated biphenyls (PCB)1336-36-3, 53469-21-9, 11097-69-1ʼ86, ʼ91, ʼ16
Shale oils68308-34-9ʼ95
Silica (crystalline)14808-60-7ʼ91, ʼ01
Sootsʼ81, ʼ86
Sulphur dichlorodiethyl505-60-2ʼ86
Talc containing asbestiform fibers14807-96-6ʼ91
2,3,7,8-Tetrachlorodibenzo-p-dioxin1746-01-6ʼ86, ʼ00
Tobacco smokeʼ10
o-Toluidine95-53-4ʼ86, ʼ95, ʼ01, ʼ16
Trichloroethylene79-01-6ʼ96, ʼ15
Vinyl chloride75-01-4ʼ81, ʼ86
Wood dustʼ98

*Evaluation does not necessarily apply to all individual chemicals within the group.

( ) in the year of proposal indicates year of reconsideration resulting in no classification change.

Table III-1b. Group 2A carcinogens
SubstanceCAS No.Year of proposal
Acrylamide79-06-1ʼ91, ʼ95, (ʼ04)
Acrylonitrile107-13-1ʼ86
Benzal chloride98-87-3ʼ91, ʼ01
Benzyl chloride100-44-7ʼ91, ʼ01
Chloromethyl methyl ether (technical grade)107-30-2ʼ92, (ʼ01)
4-Chloro-o-toluidine95-69-2ʼ91, ʼ01
CI Direct Black 38**1937-37-7ʼ86, ʼ91, ʼ95, ʼ01, (ʼ15)
CI Direct Blue 6**2602-46-2ʼ86, ʼ91, ʼ95, ʼ01, (ʼ15)
CI Direct Brown 95**16071-86-6ʼ86, ʼ91, ʼ95, ʼ01, (ʼ15)
Cobalt metal with tungsten carbide7440-48-4, 12070-12-1ʼ16
Creosotes8001-58-9ʼ91
1,2-Dibromoethane106-93-4ʼ86, ʼ95, ʼ01
3,3’-Dichloro-4,4’-diaminodiphenylmethane (MBOCA)101-14-4ʼ93, (ʼ12)
Dichloromethane75-09-2ʼ91, ʼ14, ʼ15
Diethyl sulphate64-67-5ʼ86
N,N-Dimethylformamide68-12-2ʼ91, ʼ20
Dimethyl sulphate77-78-1ʼ86
Dimethylcarbamoyl chloride79-44-7ʼ86, ʼ91
Epichlorohydrin106-89-8ʼ86, ʼ91
2,3-Epoxypropyl methacrylate (Glycidyl
methacrylate, GMA)		106-91-2ʼ18
Formaldehyde50-00-0ʼ86, ʼ91, (ʼ07), (ʼ17)
Glycidol556-52-5ʼ01
Hydrazine (Hydrazine anhydrous and Hydrazine hydrate)302-01-2, 7803-57-8’86, (ʼ98), ʼ19
Indium and compounds (inorganic, hardly, soluble)7440-74-6ʼ13, (ʼ17)
2-Nitrotoluene88-72-2ʼ18
PAHs (Cyclopenta [c,d] pyrene,
Dibenz [a,h] anthracene, Dibenz [a,j] acridine, Dibenzo [a,l] pyrene,
1-Nitropyrene, 6-Nitrochrysene)		27208-37-3, 53-70-3, 224-42-0, 191-30-0, 5522-43-0, 7496-02-8ʼ16
1,3-Propane sultone1120-71-4ʼ91, ʼ17
Silicon carbide whisker409-21-2, 308076-74-6ʼ19
Styrene oxide96-09-3ʼ92, (ʼ18)
1,2,3-Trichloropropane96-18-4ʼ01
Tris (2,3-dibromopropyl) phosphate126-72-7ʼ91
Vinyl bromide593-60-2ʼ91
Vinyl fluoride75-02-5ʼ98

**Dyes metabolized to benzidine.

Provisional

( ) in the year of proposal indicates year of reconsideration resulting in no classification change.

Table III-1c. Group 2B carcinogens
SubstanceCAS No.Year of proposal
Acetamide60-35-5ʼ91
Acetoaldehyde75-07-0ʼ91
Acrylic acid methyl96-33-3ʼ19
o-Aminoazotoluene97-56-3ʼ91
p-Aminoazobenzene60-09-3ʼ91
2-Amino-4-chlorophenol95-85-2ʼ19
Amitrole61-82-5ʼ86
Antimony trioxide1309-64-4ʼ91, (ʼ13)
o-Anisidine90-04-0ʼ91, (ʼ96)
Anthraquinone84-65-1ʼ15
Auramine (technical grade)492-80-8ʼ86
Benzofuran271-89-6ʼ15
Benzophenone119-61-9ʼ15
Benzoyl chloride98-88-4ʼ16
Benzyl violet 4B1694-09-3ʼ91
2,2-Bis (bromomethyl) propane-1,3-diol3296-90-0ʼ01
Bitumens8052-42-4ʼ91
1-Bromo-3-chloropropane109-70-6ʼ20
Bromodichloromethane75-27-4ʼ95
1-Bromopropane106-94-5ʼ17
1-tert-Butoxy-2-propanol57018-52-7ʼ18
n-Butyl-2,3-epoxypropyl ether2426-08-6ʼ16
β-Butyrolactone3068-88-0ʼ95
Carbon black1333-86-4ʼ91
Carbon tetrachloride56-23-5ʼ86
Catechol120-80-9ʼ01
Chlordane57-74-9ʼ01
Chlordecone (Kepone)143-50-0ʼ01
Chlorendic acid115-28-6ʼ91
Chlorinated paraffinsʼ91
p-Chloroaniline106-47-8ʼ95
4-Chlorobenzotrifluoride98-56-6ʼ20
Chloroform67-66-3ʼ86, (ʼ05)
1-Chloro-2-methylpropene513-37-1ʼ01
3-Chloro-2-methylpropene563-47-3ʼ01, (ʼ17)
Chlorophenoxy acetic acid herbicides*ʼ86
p-Chloro-o-phenylenediamine95-83-0ʼ91
Chloroprene126-99-8ʼ01
Chlorothalonil1897-45-6ʼ01
CI acid red 1146459-94-5ʼ95
CI basic red 9569-61-9ʼ95
CI direct blue 152429-74-5ʼ95
Citrus red No.26358-53-8ʼ91
Cobalt and compounds (without tungsten carbide)*7440-48-4ʼ95, (ʼ16)
p-Cresidine120-71-8ʼ91
Cumene98-82-8ʼ15, (ʼ19)
Dantron117-10-2ʼ15
N,N’-Diacetyl benzidine613-35-4ʼ91
2,4-Diaminoanisole615-05-4ʼ91
4,4’-Diaminodiphenyl ether101-80-4ʼ91
2,4-Diaminotoluene95-80-7ʼ91
Diazinon333-41-5ʼ18
1,2-Dibromo-3-chloropropane96-12-8ʼ91
2,3-Dibromopropan-1-ol96-13-9ʼ01
p-Dichlorobenzene106-46-7ʼ91, (ʼ98)
3,3’-Dichlorobenzidine91-94-1ʼ86
1,4-Dichloro-2-butene764-41-0ʼ15
3,3’-Dichloro-4,4’-diaminodiphenyl ether28434-86-8ʼ91
1,2-Dichloroethane107-06-2ʼ91
1,4-Dichloro-2-nitrobenzene89-61-2ʼ19
2,4-Dichloro-1-nitrobenzene611-06-3ʼ19
1,3-Dichloropropene (technical grade)542-75-6ʼ91
1,3-Dichloro-2-propanol96-23-1ʼ15
Dichlorvos62-73-7ʼ01
Diepoxybutane1464-53-5ʼ91
Diethanolamine111-42-2ʼ15
Di (2-ethylhexyl) phthalate117-81-7ʼ91
1,2-Diethylhydrazine1615-80-1ʼ91
Diglycidyl resorcinol ether101-90-6ʼ91
Diisopropyl sulfate2973-10-6ʼ95
N,N-Dimethylacetamide127-19-5ʼ19
p-Dimethylaminoazobenzene60-11-7ʼ91
2,6-Dimethylaniline87-62-7ʼ95
3,3’-Dimethylbenzidine (o-Tolidine)119-93-7ʼ91
1,1-Dimethylhydrazine57-14-7ʼ91
N,N-Dimethyl-p-toluidine99-97-8ʼ17
3,3’-Dimethoxybenzidine (o-Dianisidine)119-90-4ʼ86
2,4-(or 2,6-) Dinitrotoluene121-14-2ʼ98
1,4-Dioxane123-91-1ʼ86, (ʼ15)
Disperseblue 12475-45-8ʼ91
DDT50-29-3ʼ86, (ʼ17)
1,2-Epoxybutane106-88-7ʼ01
Ethyl acrylate140-88-5ʼ91, (ʼ19)
Ethylbenzene100-41-4ʼ01, (ʼ20)
2-Ethylhexyl acrylate103-11-7ʼ19
Ethyl methanesulphonate62-50-0ʼ91
Ethylene thiourea96-45-7ʼ86
Ethylenimine151-56-4ʼ01, (ʼ18)
(2-Formylhydrazino)-4-(5-nitro-2-furyl) thiazole3570-75-0ʼ91
Furan110-00-9ʼ01
Furfuryl alcohol98-00-0ʼ19
Gasoline8006-61-9ʼ01
Glycidaldehyde765-34-4ʼ91
Hexachlorocyclohexanes319-84-6ʼ91
HC blue No. 12784-94-3ʼ95
Heptachlor76-44-8ʼ01
Hexamethylphosphoramide680-31-9ʼ01
Isoprene78-79-5ʼ95, (ʼ17)
Lead and compounds (except alkyl lead)*7439-92-1ʼ91, (ʼ16)
Magenta (containing CI basic red 9)632-99-5ʼ95
Magnetic fields, extremely low-frequencyʼ15
Malathion121-75-5ʼ18
Man-made mineral fibers
(Ceramic fibers, Micro glass fibers)		ʼ91, ʼ03
Melamine108-78-1ʼ19
2-Mercaptobenzothiazole149-30-4ʼ19
4,4’-Methylene bis (2-methylaniline)838-88-0ʼ91
4,4’-Methylenedianiline101-77-9ʼ91, (ʼ95)
Methyl isobutyl ketone108-10-1ʼ15
Methyl mercuries7439-97-6ʼ95
2-Methyl-1-nitroanthraquinone129-15-7ʼ91
N-Methyl-N-nitrosourethane615-53-2ʼ91
α-Methylstyrene98-83-9ʼ15
Mirex2385-85-5ʼ01
Molybdenum trioxide1313-27-5ʼ17
β-Myrcene123-35-3ʼ18
Naphthalene91-20-3ʼ15
Nickel compounds (except nickel carbonyl and nickel smelting dusts)*7440-02-0ʼ81, ʼ86, ʼ91, (ʼ09)
2-Nitroanisole91-23-6ʼ98
4-Nitroanisole100-17-4ʼ19
Nitrobenzene98-95-3ʼ98
o-Nitrochlorobenzene88-73-3ʼ19
p-Nitrochlorobenzene100-00-5ʼ19
Nitrilotriacetic acid and its salts139-13-9ʼ91
Nitrogen mustard-N-oxide126-85-2ʼ91
5-Nitroacenaphtene602-87-9ʼ91
Nitromethane75-52-5ʼ01
2-Nitropropane79-46-9ʼ91
N-Nitrosodiethanolamine1116-54-7ʼ01
N-Nitrosomorpholine59-89-2ʼ91
Oil orange SS2646-17-5ʼ91
PAHs (Benz[a]anthracene, Benz[j]aceanthrylene, Benzo[b]fluoranthene, Benzo[c]phenanthrene, Benzo[j]fluoranthene, Benzo[k]fluoranthene, Chrysene, Dibenz[a, h]acridine, Dibenz[c, h]acridine, Dibenzo[a, h]pyrene, Dibenzo[a, i]pyrene, 7H-Dibenzo[c, g]carbazole, 1,3-Dinitropyrene, 1, 6- Dinitropyrene, 1,8-Dinitropyrene, 5-Methylchrysene, 3-Nitrobenzanthrone, 4-Nitropyrene)56-55-3, 202-33-5, 205-99-2, 195-19-7, 205-82-3, 207-08-9, 218-01-9, 226-36-8, 224-53-3, 189-64-0, 189-55-9, 194-59-2, 75321-20-9, 42397-64-8, 42397-65-9, 3697-24-3, 17117-34-9, 57835-92-4ʼ16
Perfluorooctanoic acid335-67-1ʼ17
Phenyl glycidyl ether122-60-1ʼ91
o-Phenylenediamine and its dihydrochloride95-54-5, 615-28-1ʼ19
Polybrominated biphenyls59536-65-1ʼ91, (ʼ17)
Polychlorophenols (technical grades)ʼ86
Ponceau 3R3564-9-8ʼ91
Ponceau MX3761-53-3ʼ91
β-Propiolactone57-57-8ʼ91
Propylene imine (2-Methylaziridine)75-55-8ʼ91, (ʼ17)
Propylene oxide75-56-9ʼ91, ʼ95
Pyridine110-86-1ʼ18
Quinoline91-22-5ʼ18
Radiofrequency electromagnetic fieldsʼ15
Styrene100-42-5ʼ91
1,1,2,2-Tetrachloroethane79-34-5ʼ15
Tetrachloroethylene127-18-4ʼ91, (ʼ01)
Tetrafluoroethylene116-14-3ʼ01, (ʼ17)
2,4,6-Trichlorophenol88-06-2ʼ18
Tetrabromobisphenol A79-94-7ʼ19
Tetrahydrofuran109-99-9ʼ19
Tetranitromethane509-14-8ʼ98
4,4’-Thiodianiline139-65-1ʼ91
Thiourea62-56-6ʼ95
Titanium dioxide13463-67-7ʼ15
Toluene diisocyanates (TDI)26471-62-5ʼ91
Trimethylolpropane Triacrylate (technical grade)15625-89-5ʼ19
Trypane blue72-57-1ʼ91
Urethane51-79-6ʼ91
Vanadium pentoxide1314-62-1ʼ15
Vinylidene chloride75-35-4ʼ18
Vinyl acetate108-05-4ʼ98
4-Vinylcyclohexene100-40-3ʼ95
4-Vinylcyclohexene diepoxide106-87-6ʼ95

*Evaluation does not necessarily apply to all individual chemicals within the group.

Provisional

( ) in the year of proposal indicates year of reconsideration resulting in no classification change.

N,N-dimethylformamide is proposed to be excluded from Group 2B

Only when scientifically reasonable information is available, JSOH will estimate a reference value corresponding to an individual excess lifetime risk of cancer due to exposure to a Group I carcinogen, and show it in Table III-2. JSOH does not recommend either the reference value as a safe exposure level or the individual excess lifetime risk as an acceptable risk level. The reference value should be applied only by experts well-trained and well-experienced in occupational health to avoid or minimize the risk of occupational cancer.

Table III-2. Reference values corresponding to an individual excess lifetime risk of cancer
SubstanceIndividual excess lifetime risk of cancerReference valueMethod of estimationYear of estimation
Arsenic and inorganic arsenic compounds10–33μg/m3Average relative risk modelʼ00
10–40.3μg/m3
Asbestos
 chrysotile10–30.15fibers/mlAverage relative risk modelʼ00
10–40.015fibers/ml
 containing asbestos fibers10–30.03fibers/ml
  other than chrysotile10–40.003fibers/ml
Benzene10–31ppmAverage relative risk modelʼ97, (ʼ19)
10–40.1ppm
Ionizing radiation(Table III-3)ʼ12
Nickel smelting dusts (as Ni)10–310μg/m3Average relative risk modelʼ09
10–41μg/m3
Vinyl chloride10–31.5ppmAverage relative risk modelʼ17
10–40.15ppm

The occupational carcinogens may have OEL in Table I-1. These values must be used with caution. Some substances had epidemiological or experimental evidences that carcinogenicity was observed only at significantly higher concentrations than those for non-carcinogenic health effects, but the others did not. For the latter case, the substance is indicated as ψ in Table I-1**.

Table III-3 indicates reference values corresponding to an individual excess lifetime risk of cancer for ionizing radiation. A series of the reference values, i.e. unit risk doses of ionizing radiation, are shown as Radiation Exposure Induced Death (REID) levels of 100, 50, 10, 1 for 1,000 population with stratified by sex, age, and exposure situation (single, repeated). Dose and dose-rate effectiveness factor (DDREF) of 1 is being adopted primarily, and REID levels with DDREF of 2 are also calculated for comparison. The reference values here are calculated based on exposure-response relationship of low LET radiation, indicating that the values should not be applied in the case that internal exposure is considered.

*,  Epidemiological evidences include serum epidemiology and molecular epidemiology

**,  See Table I-1 for Group 1 and Group 2A carcinogens.

Table III-3. Unit risk doses of ionizing radiation: Risk of Exposure-Induced Death (REID) levels of 100, 50, 10, 1, for 1,000 population
Single exposure (mSV) DDREF=1
(a) Male(b) Female
REIDage at first exposureREIDage at first exposure
18283848581828384858
10−1892.21,075.51,342.11,760.82,441.810−1762.9939.21,204.21,628.92,320.5
5×10−2440.8535.2676.9911.21,325.05×10−2374.1462.3597.7821.71,207.9
10−287.4106.8136.7189.0291.610−273.791.4119.0166.0251.9
10−38.710.713.719.130.010−37.39.111.916.625.5
10−40.91.11.41.93.010−40.70.91.21.72.6
Repeated exposure until age 68 (from first exposure age to the end of age 67) (mSv/year) DDREF=1
(a) Male(b) Female
REIDage at first exposureREIDage at first exposure
18283848581828384858
10−134.150.883.5160.2412.810−128.642.770.1133.0342.4
5×10−216.424.540.377.5203.95×10−213.820.733.964.5167.5
10−23.24.87.815.140.410−22.74.06.612.633.0
10−30.30.50.81.54.010−30.30.40.71.33.3
10−40.030.050.080.150.4010−40.030.040.070.130.33
Repeated 10 year exposure, (10 years from first exposure age) (mSv/year) DDREF=1
(a) Male(b) Female
REIDage at first exposureREIDage at first exposure
18283848581828384858
10−1101.7126.8168.1245.8412.810−185.5108.2145.3211.0342.4
5×10−249.261.481.4119.6203.95×10−241.552.570.5102.6167.5
10−29.612.015.923.440.410−28.110.313.820.133.0
10−31.01.21.62.34.010−30.81.01.42.03.3
10−40.100.120.160.230.4010−40.080.100.140.200.33
Repeated 5 year exposure, (5 years from first exposure age) (mSv/year) DDREF=1
(a) Male(b) Female
REIDage at first exposureREIDage at first exposure
18283848581828384858
10−1192.5236.8306.4430.4673.310−1161.8202.3266.4376.7581.4
5×10−293.3115.0149.3211.4337.95×10−278.698.3129.7184.1287.1
10−218.222.529.341.768.010−215.419.225.436.256.9
10−31.82.22.94.26.810−31.51.92.53.65.7
10−40.180.220.290.420.6810−40.150.190.250.360.57
Single exposure (mSv) DDREF=2
(a) Male(b) Female
REIDAge
18		28384858REIDAge
18		28384858
10−11,541.01,801.12,139.42,599.63,245.910−11,403.11,692.12,084.02,646.23,436.8
5×10−2797.0946.91,153.41,455.71,911.25×10−2707.5862.91,085.71,425.21,940.6
10−2165.1199.8251.4335.9486.310−2142.8176.1226.6309.8453.4
10−316.720.325.835.153.310−314.317.722.931.747.7
10−41.72.02.63.55.410−41.41.82.33.24.8
Repeated exposure until age 68 (from first exposure age to the end of age 67) (mSv/year) DDREF=2
(a) Male(b) Female
REIDage at first exposureREIDage at first exposure
18283848581828384858
10−163.593.4150.2276.5650.510−154.981.4131.9244.7596.9
5×10−230.745.373.2136.8337.35×10−226.639.564.2120.1301.3
10−26.08.814.427.270.210−25.27.712.623.760.9
10−30.60.91.42.77.110−30.50.81.32.46.1
10−40.060.090.140.270.7110−40.050.080.130.240.61
Repeated 10 year exposure, (10 years from first exposure age) (mSv/year) DDREF=2
(a) Male(b) Female
REIDage at first exposureREIDage at first exposure
18283848581828384858
10−1191.2235.3304.2424.7650.510−1165.2207.5274.3387.7596.9
5×10−293.2115.1149.9212.5337.35×10−280.5101.2134.4191.7301.3
10−218.322.629.742.670.210−215.819.926.538.060.9
10−31.82.33.04.37.110−31.62.02.63.86.1
10−40.180.230.300.430.7110−40.160.200.260.380.61
Repeated 5 year exposure, (5 years from first exposure age) (mSv/year) DDREF=2
(a) Male(b) Female
REIDage at first exposureREIDage at first exposure
18283848581828384858
10−1358.0433.6545.5726.91,032.710−1310.9385.1497.8681.2989.7
5×10−2176.0214.5272.8371.6550.85×10−2152.1189.1246.1341.5510.3
10−234.842.654.776.1118.510−229.937.348.868.6105.3
10−33.54.35.57.712.110−33.03.74.96.910.6
10−40.350.420.550.771.2110−40.300.370.490.691.06

IV. Occupational Sensitizers

This table is the list of occupational sensitizers to the airway and skin (Table IV). The sensitizers are classified into Group 1 substances which induce allergic reactions in humans, Group 2 substances which probably induce allergic reactions in humans, and Group 3 substances which are considered possibly to induce allergic reactions in humans based on animal experiments.

Table IV. Occupational sensitizers
Airway
Group 1
 Beryllium*, Cobalt*, Colophony (Rosin)*, Diphenylmethane-4,4’-diisocyanate (MDI), Glutaraldehyde, Hexane-1,6-diisocyanate, Methyltetrahydrophthalic anhydride, Phthalic anhydride, Platinum*, Toluene diisocyanates*, Trimellitic anhydride
Group 2
 Chlorothalonil, Chromium*, Ethylenediamine, Formaldehyde, Maleic anhydride, Methyl methacrylate, Nickel*, Piperazine
Skin
Group 1
 Aniline, Benzoyl peroxide, Benzyl alcohol, Chlorothalonil, Chromium*, Cobalt*, Colophony (Rosin)*, 4,4’-Diaminodiphenylmethane, 2,4-Dinitrochlorobenzene (DNCB), Epichlorohydrin, Formaldehyde, Glutaraldehyde, Hydrazine*, Mercury*, Methacrylic acid 2-hydroxyethyl ester (2-Hydroxyethyl methacrylate), 4,4’-Methylenedianiline, Nickel*, p-Phenylenediamine, Platinum*, Resorcinol, Sodium ethylmercury 2-sulfidobenzoate (Thimerosal), Thiuram, Trichloroethylene, Tri (propylene glycol) diacrylate, N,N’,N’’-Tris (β-hydroxyethyl)-hexahydro-1,3,5-triazine, Turpentine*, m-Xylylendiamine
Group 2
 Acrylamide, Benomyl, Benzyl alcohol, Beryllium*, Buthyl acrylate, N-butyl-2,3-epoxy-propyl ether, Copper*, Dibutyl phthalate, Dichloropropane, Dicyclohexylcarbodiimide, Diethanolamine, 2,3-Epoxypropyl methacrylate (Glycidyl methacrylate, GMA), Ethyl acrylate, Ethylene oxide, Ethylenediamine, Hydroquinone, 2-Hydroxyethyl methacrylate, Iodine*, Maleic anhydride, Methyl acrylate, Methyl methacrylate, Picric acid, Polyvinyl chloride plasticizers*, Rodium*, Toluene diamine*, Toluene diisocyanates*, Usnic acid
Group 3
m-Chloroaniline, Dimethylamine, Isophoronediisocyanate, o-Phenylenediamine, m-Phenylenediamine

*Evaluation does not necessarily apply to all individual chemicals within the group. Provisional.

The revised definition of “Occupational sensitizer” has been applied to the substances proposed in 1998 or later, and the substances listed before 1998 are not fully re-examined at this time; please note that OEL values are not necessarily recommended to all the substances listed here. See JSOH web site for brief summary of OEL documentation at http://sanei.or.jp/oel-eng

Recommendation of occupational exposure limits for the occupational sensitizers does not necessarily consider either prevention of sensitization or allergic reaction. Any substance which is not included in the list does not indicate that the substance is not a sensitizer.

V. Reproductive Toxicants

The Japan Society for Occupational Health (JSOH) classifies reproductive toxicants on the basis of evidence of reproductive toxicity obtained from epidemiological studies and other studies in humans, as well as that from experimental studies in animals. The classification is made based on the strength of the evidence for adverse effects on reproduction in humans, but does not reflect the potency of such adverse effects. Namely, the classification does not necessarily indicate that exposures to the classified substances at the present Occupational Exposure Limit (OEL-M) levels induce adverse effects on reproduction. The definition of reproductive toxicity and the classification criteria for judgment are as follows.

1. Definition of reproductive toxicity

Reproductive toxicity includes adverse effects on reproductive functions in males and females, as well as on the offspring. Effects on functions such as fertility, pregnancy, delivery, and lactation in women, and fertility/insemination in men are within the scope of the definition. Substances that have adverse effects on reproductive organs are also included within the classification criteria if it is suspected that the reproductive functions referred to above are affected. In the case of offspring, reproductive toxicity is defined as the effects on the development of the embryo/fetus including teratogenic insults by prenatal exposure to the substance and/or the effects on the infant by postnatal exposure via lactation due to transfer in breast milk. If effects on post-weaning growth, behavior, function, sexual maturation, carcinogenesis, accelerated aging, and other processes are clearly demonstrated in the offspring as a result of parental exposure, then such effects are considered as reproductive toxicity.

2. Classification and judgment criteria

1) Classification of reproductive toxicants:

Reproductive toxicants shall be classified in Group 1, Group 2, or Group 3, defined as follows.

Group 1: Substances known to cause reproductive toxicity in humans.

Group 2: Substances presumed to cause reproductive toxicity in humans.

Group 3: Substances suspected to cause reproductive toxicity in humans.

2) Judgment criteria for the classification of reproductive toxicity:

Group 1: Substances for which sufficient evidence in humans has been obtained from epidemiological studies and other human studies shall be classified.

Sufficient evidence that demonstrates reproductive toxicity in humans is required, where sufficient means two or more reports of epidemiological studies conducted in an appropriate manner. A single epidemiological study can be used as the evidence for classification to this group if any of the following conditions are satisfied: a) the study takes into consideration both dose-response relationships and co-exposure to other substances or potential confounding factors, in an appropriate manner; b) the study is supported by many non-epidemiological study reports on, for example, clinical cases or accidental exposures, indicating reproductive toxicity and it can therefore be decided overall that there is sufficient evidence of toxicity in humans. Animal experimental data are considered as supportive information.

Group 2: Substances for which sufficient evidence demonstrating reproductive toxicity has been obtained in appropriate animal experiments, and thus presumed to cause reproductive toxicity in humans, shall be classified.

Judgment shall be made on the basis of animal experiments, namely, evidence showing obvious adverse effects on reproduction in animals, identified by appropriately conducted animal experimental studies, and thus reasonably indicating that the substance causes reproductive toxicity in humans. When judgment is made from the results of animal experiments, it is required that the observed effects should not be the consequences of secondary non-specific effects of other general toxicities, and that the identified mechanism of action be non-species-specific and therefore relevant for extrapolation to humans. In addition, if the observed changes are small and exert only non-significant effects on the life or function of the subject, then such changes are considered as not satisfying the requirement.

Group 3: Substances for which limited evidence has been demonstrated shall be classified.

Substances are allocated into this group when reproductive toxicities are suspected from reports in humans or from animal experiments. If information for reproductive toxicity is obtained from epidemiological studies, other human studies, and/or animal experiments, but such evidence is not considered to be sufficient for allocating the substance to Group 1 or Group 2, then classification in Group 3 should be considered.

3. Classified reproductive toxicants

Table V. lists the substances classified in each reproductive toxicant group according to the judgment criteria referred to above. The judgment is made for substances for which OEL is recommended by JSOH based on information described in the documentation for Recommendation of Occupational Exposure Limits by JSOH and other relevant information; this does not mean that substances not included in the table do not meet the classification criteria of reproductive toxicity. There may be some substances for which reproductive toxicity might be observed below the level of OEL-M or OEL-B; in such cases, precautionary notice is given by adding a symbol (#) next to the substances in Table V.

Table V. Reproductive toxicants
Group 1
 Arsenic and compounds, 2-Bromopropane, Cadmium and compounds, Carbon disulfide, Carbon monoxide#, Di (2-ethylhexyl) phthalate#, Ethylene glycol monomethyl ether, Ethylene glycol monomethyl ether acetate, Ethylene oxide, Lead and compounds#, Perfluorooctanoic acid (PFOA)#, Polychlorobiphenyls (PCB), Toluene
Group 2
 Acrylamide, Benomyl#, 1-Bromopropane, Chlorodifluoromethane, Chloromethane, 2,4-Dichlorophenoxyacetic acid (2,4-D), N,N-Dimethylacetamide, N,N-Dimethylformamide (DMF), Ethyl benzene, Ethylene glycol monobutyl ether, Ethylene glycol monoethyl ether, Ethylene glycol monoethyl ether acetate, Inorganic mercury (including mercury vapor), Manganese and compounds, Methanol, Pentachlorophenol (PCP), Styrene, Vanadium and compounds, Xylene for industrial use
Group 3
 Atrazine, n-Butyl-2,3-epoxypropylether, Chromium and compounds, p-Dichlorobenzene, 2,3-Epoxypropyl methacrylate (Glycidyl methacrylate, GMA), Ethyleneimine, 2-Ethyl-1-hexanol, Ethylidene norbornene, Nickel and compounds, Phenol, Tetrachloroethylene, Trichloroethylene, Xylene (ortho-, meta-, para-xylene and their mixture)

Not all substances that may exert reproductive toxicity are identified.

#: Precaution should be given for lower exposure than OEL-M or OEL-B. As for reproductive toxicity, it is generally known that there is a sensitive period, during pregnancy for example, and such effects of this substance have been identified.

Provisional

See JSOH web site for brief summary of OEL documentation at http://sanei.or.jp/oel-eng

VI. Occupational Exposure Limits for Continuous or Intermittent Noise

Occupational exposure limits (OELs) for continuous or intermittent noise exposure are recommended as follows to protect against noise-induced hearing loss.

1. OELs for continuous or intermittent noise

Values in Fig. VI or Table VI-1 show OELs, at or below which noise-induced permanent threshold shift (NIPTS) is expected to be below 10 dB at or below a frequency of 1 kHz, below 15 dB at 2 kHz, and below 20 dB at or more than 3 kHz after more than 10 years of continuous or intermittent noise exposure for 8 hours a day in most workers.

Fig. VI.

Occupational exposure limits for continuous or intermittent noise.

Table VI-1. Occupational exposure limits for continuous or intermittent noise
Center frequency (Hz)OELs by octave-band level (dB)
480 min240 min120 min60 min40 min30 min
25098102108117120120
500929599105112117
10008688919599103
2000838485889092
3000828384868890
4000828385878991
800087899297101105

2. Applicable noise

OELs can be applied to wide and narrow-band noise with band width below 1/3 octave. OELs are temporarily applicable to pure tones regarded as narrow-band noise. Impulsive or impact noise is excluded from the application (see Section VII).

3. Application method

(1) In the case of continuous noise exposure throughout the work-time, OELs corresponding to the exposure duration should be taken from Fig. VI or Table VI-1.

(2) In the case of intermittent noise exposure, an equivalent exposure duration is considered to be the sum of exposure duration throughout the work-time minus an effective resting duration, and OELs corresponding to the equivalent exposure duration should be taken from Fig. VI or Table VI-1. The effective resting duration is the duration when the noise levels are below 80 dB.

(3) In the case that noise is analyzed by an octave band filter, OELs corresponding to exposure duration are the values at the left ordinate of Fig. VI or in Table VI-1. In the case that noise is analyzed by a narrower band filter with a band width of 1/3 octave or less, OELs are the values at the right ordinate of Fig. VI or the values subtracted 5 from the figures in Table VI-1.

4. OELs by A-weighted sound pressure level

Basically, frequency analysis of noise is recommended. In the case of evaluating with an A-weighted sound pressure level, OELs in Table VI-2 should be used.

Table VI-2. Occupational exposure limits for continuous or intermittent noise by A-weighted sound pressure level
Exposure duration
(hours-minutes)		OELs by A-weighted sound pressure level (dB)Exposure duration
(hours-minutes)		OELs by A-weighted sound pressure level (dB)
24−00802−0091
20−09811−3592
16−00821−1593
12−41831−0094
10−04840−4795
8−00850−3796
6−20860−3097
5−02870−2398
4−00880−1899
3−10890−15100
2−3090

5. Noise measurement

For measurement methods, refer to ‘Japan Industrial Standard (JIS) Z 8731–1999 Acoustics-Description and measurement of environmental noise’.

VII-i. Occupational Exposure Limits for Impulsive or Impact Noise

Occupational Exposure Limits (OELs) for impulsive or impact noise exposure in the workplace are recommended as follows to protect against noise-induced hearing loss.

1. OELs for impulsive or impact noise

In the case that total frequency of exposure to impulsive or impact noise is at or below 100 times a day, the peak sound pressure level shown in Fig. VII-1 is recommended as the OEL corresponding to the duration of impulsive or impact noise explained in “3. Measurement method”.

In the case that total number of exposures to impulsive or impact noise is above 100 times a day, the sum of the peak sound pressure level in Fig. VII-1 with the adjustment value in Fig. VII-2 to cerrect the difference of exposure frequency is recommended as OEL. At or below these limits, NIPTS is expected to be below 10 dB at or below a frequency of 1 kHz, below 15 dB at 2 kHz, and below 20 dB at or more than 3 kHz after more than 10 years of impulsive or impact noise exposure in most workers.

Fig. VII-1.

Occupational exposure limits for impulsive or impact noise.

Fig. VII-2.

Correction values corresponding to exposure frequency a day.

2. Applicable noise

These OELs are applicable to impulsive or impact noise only. In the case of mixed exposure to both impulsive or impact noise and continuous or intermittent noise, both OELs should be satisfied.

3. Measurement method

Impulsive or impact noises are classified by their oscilloscope-measured wave forms into two groups, as shown in Fig. VII-3 (A) and (B). In Fig. VII-3 (A), A duration is defined as the duration between TO and TD. In Fig. VII-3 (B), B duration is defined as either the duration between T0 and TD’ if no reflection sound exists, or the sum of durations between T0 and TD’ and between T0’’ and TD’’ if reflection sound dose exists. In the case of (B), TD’ or TD’’ is determined by the intersection of a wave envelope indicating sound pressure change with a line indicating a sound pressure 20 dB below peak sound pressure. This method is also applicable in the case of multiple reflection sounds.

Fig. VII-3.

Measurement for impulsive or impact noise.

VII-ii. Occupational Exposure Limit for Impulsive or Impact Noise by A-Weighted Sound Pressure Level

1. Occupational exposure limit (OEL)

In the case that total frequency of exposure to impulsive or impact noise is at or below 100 times a day, OEL is 120 dB at A-weighted sound pressure level. In the case that total frequency of exposure to impulsive or impact noise is above 100 times a day, the adjustment value in Fig. VII-2 corresponding to frequency of exposure should be added for OEL determination.

2. Application

OEL is applicable to type B wave in Fig. VII-3 only.

3. Measurement method

Maximum values should be measured by the Sound Level Meter (JIS C 1509-1-2005) with use of an A-weighted frequency response and fast dynamic characteristic.

VIII. Occupational Exposure Limits for Heat Stress

1. Occupational Exposure Limits

Permissible heat exposure limits were proposed as Table VIII-1 on the presumption that any unfavorable physiological response should not be caused by the heat stress.

Table VIII-1. Occupational Exposure Limits for heat stress
Work loadOELs
WBGT (°C)
RMR ~1 (Very Light, ~130 kcal/h)32.5
RMR ~2 (Light, ~ 190 kcal/h)30.5
RMR ~3 (Moderate, ~ 250 kcal/h)29.0
RMR ~4 (Moderate, ~ 310 kcal/h)27.5
RMR ~5 (Heavy, ~ 370 kcal/h)26.5

2. Application

These exposure limits show the condition for which the workers work without health impairment or decrease in work efficiency for one hour of continuous work or two hours of intermittent work. The workers mentioned here are healthy adult male workers, adapted themselves to hot environment, well used to the work, wearing usual summer clothes, and taking enough water and salt.

Hot environment means the condition in which the regulation of body temperature is mainly performed by the evaporation responding to the complex of ambient temperature, humidity, and heat radiation.

Adaptation is the effect of the vicarious physiological change of the worker working under hot environment.

The thermal adaptation is obtained by usually working for one week under hot environment. If hot environment exposure is ceased, the adaptation effect is lost immediately and usually disappears in two weeks. Therefore, it is necessary to pay attention to the workers’ condition when their adaptation is not enough or when they return to work after two or more days off.

The unfavorable physiological response is the state that physiological burdens such as increase of the heart rate, a rise in temperature, the increase of the quantity of water loss continue increasing.

Therefore, if the physiological burden on worker continues increasing under hot environment, some engineering measures should be taken or other measures like wearing cool clothes and reducing work load should be performed to decrease heat strain. The heat stress consists of factors such as environmental thermal condition, heat production through metabolism and heat exposure time.

The work load means metabolic energy used at the work. We expressed the degree in Relative Metabolic Rate (RMR) and classified in five categories as shown in Table VIII-2. RMR is calculated by the following expression.   

RMR = (energy consumption on exertion)− (energy consumption at rest) (basal metabolic rate)
Table VIII-2. Work load and metabolic energy (kcal/h)
Work loadMetabolic energy (kcal/h)
RMR ~1 (Very Light, ~130 kcal/h)~130
RMR ~2 (Light, ~ 190 kcal/h)~190
RMR ~3 (Moderate, ~ 250 kcal/h)~250
RMR ~4 (Moderate, ~ 310 kcal/h)~310
RMR ~5 (Heavy, ~ 370 kcal/h)~370

RMR values according to common movements are displayed in Table VIII-3. This table should be referred to estimate the work load.

Table VIII-3. Classification of RMR by work
RMRPrincipal
motion sites		MotionExamples of works
0−0.5
0.5−1.0		handmoving mechanicallycall handling (seated) 0.4, data entry 0.5, gauge monitoring (seated) 0.5,
moving consciouslystraightening (hammer tapping, 98 times/min) 0.9, vehicle driving 1.0
1.0−2.0
2.0−3.0		hand movement with some upper limb movementhand movement with some forearm
movement forearm		lathe work (pairing, 0.83 minutes/unit) 1.1,
surveillance work (standing) 1.2, walking slowly on level ground (45 m/min) 1.5
hand movement with some upper arm movementwalking (ordinary, 71 m/min) 2.1, concrete polishing (lightly) 2.0, circular saw work 2.5, stair walking (down, 50 m/min) 2.6
3.0−4.0upper limbnormal movementchinning grinder (grinding 150 kg parts, 6 min. / unit) 3.0, riding bicycle (level ground, 170 m/min) 3.4, walking (fast, 95 m/min) 3.5
4.0−5.5relatively big
movement with power		riveting (1.3 /min) 4.2, filing (36 cm file, 150 times /min.) 4.2, rough saw 5.0
5.5−6.5whole body
lifting, turning,
pulling, pushing,
throwing,
moving
up-and-down, scraping		normal movementtapping (poking 7 kg, 16-20 times/min) 5.7, shoveling (6 kg, 18 times/min) 6.5, stair walking (up, 45 m/min) 6.5
6.5−8.0relatively big
movement with equal power
especially momentary		hammering (6.8 kg, 26 times/min.) 7.8
8.0−9.5pile up (15 kg, 10 times/min) 9.0
10.0−
12.0		whole body (same as above)physically strenuous work with a bit of leeway; may continue
for sometime		pushing at full power 10.0
pickaxe (concrete bursts) 10.5
shovel (72 times/min.) 11.0
12.0−physically
strenuous work
such as
construction work		concentrate on whole body movement and can tolerate only for less than one minutehammering (4.5 kg, 29 times/min) 19.3

In an ordinary industrial setting, many of the works are manually performed continuously with the work load of around RMR 1.0. And most of the work loads are not more than RMR 2. However, it is considered possible to work continuously for one hour by the work load of RMR 4, we set one hour continuous work as the basic work unit for the work load up to RMR 4. Furthermore, although the work exceeding RMR 4 may exist, we assumed those work must be performed intermittently, as it is difficult to continue for one hour.

Therefore, regarding the working hour mentioned here, we classify the work into continuous work or intermittent work. We assumed one-hour work as the evaluation unit for continuous work and proposed the method of evaluating the environment in one-hour continuous work for normal eight hours. Likewise, we assumed two-hour work as the evaluation unit for intermittent work and proposed the method of evaluating the environment in two-hour intermittent work similarly. We adopted these methods in order to make it applicable to the real industrial workshop and to make it possible to evaluate in a short time.

3. Thermal index and method for measuring workload

We decided to use the environmental index corresponding to the physiological response by the heat stress for an evaluation of the hot environment. As the best method now, we adopted Wet Bulb Globe Temperature (WBGT) as the simple and practical index for the thermal condition.

Calculation of thermal index

Methods for the measurement of thermal index are described elsewhere. WBGT is calculated as follows.

Calculation of WBGT

(1) Inside the room or outdoors without sunlight radiation

WBGT = 0.7NWB + 0.3GT

(2) Outdoors with sunlight radiation

WBGT = 0.7NWB + 0.2GT + 0.1DB

NWB (natural wet bulb temperature): Wet bulb temperature (without breathing forcibly and not surrounding the bulb part to prevent heat radiation) measured with being exposed to natural air flow

GT (globe thermometer temperature): Temperature measured by globe thermometer of 6 inches in diameters

DB (dry bulb temperature): Dry bulb temperature measured by covering the bulb part to prevent the direct effect of heat radiation without interfering spontaneous air flow

At measurement, it is important to comprehensively evaluate the thermal load affected by the ambient thermal condition and artificial heat production in the workplace. The actual situation including the workers’ condition should be fully understood such as the work position, the work intensity, the time and frequency of the heat exposure. We estimate the actual work condition as follows.

In the case of continuous work, the thermal condition of the workplace should be defined as the highest one-hour value of WBGT in a daily working hour.

In the case of two-hour intermittent work, the thermal condition of the workplace should be defined by two-hour time-weighted value of WBGT.

Two-hour time-weighted value of WBGT = (WBGT1 × t1 + WBGT2 × t2 +... + WBGTn × tn) /120 minutes WBGT1, WBGT2... WBGTn: Each value of WBGT at work or at break

t1, t2... tn: Each value of time at work or at break (minute)

The method to calculate work load of two-hour intermittent work is as follows.

If the workers are engaged in heavy/moderate work load for more than one hour, we define it as moderate workload.

If the workers are engaged in light work load for more than one hour, and the rest in moderate workload, we define it as light work load.

If the workers are engaged in light work load for more than one hour, and the rest in heavy workload, we define it as moderate work load.

When each of the work load is of concern, we calculate the two-hour load average of the work load as follows.

Two-hour load average of the work load = (WL1 × t1 + WL2 × t2 + … + WLn × tn) /120 minutes

WL1, WL2 … WLn: Each value of work load at each work or at break

t1, t2... tn: Each time at work or at break (minute)

4. Year of proposal: 1982

IX. Occupational Exposure Limits for Cold Stress

Workers should wear appropriate clothing to protect themselves from cold stress in cold environments. The values of thermal insulation of the combination of clothing are shown in Table IX-1.

Table IX-1. Thermal performance of clothing
Combination of clothingclo value
Underwear (top /bottom), shirt, trousers, coat, vest, socks, shoes1.11
Underwear (top /bottom), thermal jumper, thermal trousers, socks, shoes1.40
Underwear (top /bottom), shirt, trousers, coat, over jacket, cap, gloves, socks, shoes1.60
Underwear (top /bottom), shirt, trousers, coat, over jacket, over trousers, socks, shoes1.86
Underwear (top /bottom), shirt, trousers, coat, over jacket, over trousers, cap, gloves, socks, shoes2.02
Underwear (top /bottom), over jacket, over trousers, thermal jumper, thermal trousers, socks, shoes2.22
Underwear (top /bottom), over jacket, over trousers, thermal jumper, thermal trousers, cap, gloves, socks, shoes2.55
Cold protective clothing3~4.5
Sleeping bag3~8

Recommendations about clothing: Wear several layers of loose clothing. Layering provides better insulation. Make sure to protect the ears, face, hands, and feet in extremely cold weather. Boots should be waterproof and insulated. Avoid touching cold metal surfaces with bare skin.

The gloves are necessary to prevent frostbite of the hands. The appropriate gloves should be chosen, depending on work, and waterproof gloves in some cases. If the degree of the chilliness is severer, mittens are more effective.

The relationship between equivalent temperature and thermal insulation of clothing, during both light and moderate workloads is presented in Table IX-2.

Table IX-2. Occupational exposure limits for cold stress (Maximal work duration in a 4-hour shift)
TemperatureWork loadMaximal work duration (min)
−10~–25°CLight work (RMR~2)~ 50
Moderate work (RMR~3)~ 60
−26~–40°CLight work (RMR~2)~ 30
Moderate work (RMR~3)~ 45
−41~–55°CLight work (RMR~2)~ 20
Moderate work (RMR~3)~ 30

When air temperature is lower, the worker should wear clothing with higher thermal insulation power. And also, when a workload is low, the worker should wear higher thermal insulation clothing, because the internal heat produced by the body is lower than in the case of a higher workload.

In the cold environment, the wind velocity becomes a critical factor as well as air temperature.

An equivalent chill temperature chart relating the air temperature and the wind velocity is presented in Table IX-3.

Table IX-3. Cooling power of wind on exposed body areas air expressed as equivalent chill temperature
wind velocity
(m/sec)		air temperature (°C)
0−5−10−15−20−25−30−35−40−45−50
equivalent chill temperature (°C)
calm0−5−10−15−20−25−30−35−40−45−50
2−1−6−11−16−21−27−32−37−42−47−52
3−4−10−15−21−27−32−38−44−49−55−60
5−9−15−21−28−34−40−47−53−59−66−72
8−13−20−27−34−41−48−55−62−69−76−83
11−16−23−31−38−46−53−60−68−75−83−90
15−18−26−34−42−49−57−63−73−80−88−96
20−20−28−36−44−52−60−68−76−84−92−100

Maximum work period recommended for properly clothed workers, working 4-hour shifts, at air temperatures and workloads are shown in Table IX-4. The workload is expressed in RMR (Relative Metabolic Rate) with the identical case of occupational exposure limits for heat stress. Light workload is less than RMR 2, (less than 190 kca1/h, metabolic energy), and moderate workload is RMR 2-3 (about 250 kca1/h, metabolic energy).

Table IX-4. Occupational exposure limits for cold stress (Maximum work period recommended working 4-hour shift)
Air temperatureWork lordMaximum work period (min)
−10~−25°Clight work lord.(RMR~2)~50
moderate work load(RMR~3)~60
−26~−40°Clight work load(RMR~2)~30
moderate work load(RMR~3)~45
−41~−55°Clight workload(RMR~2)~20
moderate work load(RMR~3)~30

Wind velocity is below 0.5 m/sec, in an almost windless environment.

The standard work conditions are for four hours by shift work taking a rest in a recovery room for at least 30 minutes after one work sequel to.

There is much continuous light work (RMR l-2) and moderate work of RMR 3 in some cases. In the workload of these levels, physical loads to thermoregulation system by the cold stress, are bigger than the load to breathing and the circulatory system in the body function by the work.

The standard work conditions are for four hours shift work, taking a rest for at least 30 minutes after each shift work, wearing adequate cold-protective clothing to work in an almost windless environment.

Physical effects by cold chill index and equivalent temperature are shown in Table IX-5.

Table IX-5. Physical effects by cold chill index and equivalent temperature
Cold chill indexEquivalent air temperature (°C)Physical effects
1,000−14Very cold
1,200−22Extremely cold
1,400~1,550−30~−38Frostbite of exposed skin in one hour
1,700~1,900−45~−53Dangerous outside activity such as walking, frostbite occurs on exposed part of the face in one minute
2,000~2,300−61~−69Frostbite occurs on exposed part of the face in 30 seconds

In cold environments, skin temperatures decrease particularly in the tip of the hands and feet. Body temperatures decrease, when heat production in the body is less than the heat radiation on the equilibrium of the internal heat balance.

Tremors and unconsciousness appear by hypothermia. Core temperature such as rectal temperature should keep above 36°C. Outbreak of more intense tremors is the danger signal that temperature is decreasing more, and one should promptly stop exposure to the cold.

Work efficiency decreases and is unsafe due to pain, tightening, and the chilliness of the peripheral parts such as hands and feet. Furthermore, the skin temperature of the toes is approximately 13°C, and 10°C at the fingers. Pain and numbness by cold is a danger signal leading to frostbite.

X. Occupational Exposure Limits for Whole Body Vibration

0.35 m/s2Asum (8)

XI. Occupational Exposure Limits for Hand-Arm Vibration

Fig. XI.

Occupational exposure limits for hand-arm vibration using vibration total value of frequency-weighted r.m.s. acceleration.

Table XI. Occupational exposure limits for hand-arm vibration using vibration total value of frequency-weighted r.m.s. acceleration
Exposure time (min)Vibration total value of frequency-weighted r.m.s. acceleration (m/s2 r.m.s.)
≤625.0
1019.4
1515.8
3011.2
607.92
906.47
1205.60
1505.01
1804.57
2104.23
2403.96
2703.73
3003.54
3303.38
3603.23
3903.11
4202.99
4502.89
4802.80

XII. Occupational Exposure Limits for Time-Varying Electric, Magnetic and Electromagnetic Fields (up to 300 GHz)

Table XII-1. Static magnetic fields (Frequency: 0~0.25 Hz)
OEL-MOEL-C
Head, trunk200 mT (1.63×105 Am–1)2T
Extremities500 mT (4.08×105 Am–1)5T

Table XII-2. Low frequency time-varying electric and magnetic fields (Frequency: 0.25 Hz~100 kHz)
Frequency (f)EF*Magnetic flux densityMF
0.25~1.0 Hz50/f mT4.08 × 104/f Am−1
1.0~25 Hz20 kVm−150/f mT4.08 × 104/f Am−1
25~500 Hz500/f kVm−150/f mT4.08 × 104/f Am−1
500~814 Hz500/f kVm−10.1 mT81.4 Am−1
0.814~60 kHz614 Vm−10.1 mT81.4 Am−1
60~100 kHz614 Vm−16/f mT4,880/f Am−1

*EF: electric field, MF: magnetic field

Table XII-3. Radio-frequency electromagnetic fields (Frequency: 0.1 MHz~300 GHz)
Frequency (f)EF*Magnetic flux densityMFPower density
0.1~3.0 MHz614Vm−16/f μT4.88/f Am−1
3.0~30 MHz1,842/f Vm−16/f μT4.88/f Am−1
30~400 MHz61.4Vm−10.2 μT0.163Am−110Wm−2
400~2000 MHz3.07f0.5Vm−10.01f0.5 μT8.14f0.5mAm−1f/40 Wm−2
2~300 GHz137Vm−10.447 μT0.364Am−150Wm−2

*EF: electric field, MF: magnetic field

Fig. XII-1.

OEL-Ms of time-varying electric fields

Fig. XII-2.

OEL-Ms of static and time-varying magnetic fields

XIII. Occupational Exposure Limit for Ultraviolet Radiation

Occupational Exposure Limit for ultraviolet radiation with wavelengths between 180 nm and 400 nm is recommended to be 30 J/m2 as effective irradiance integrated over 8 hours a day, to avoid acute effects on eye (cornea or conjunctiva) or the skin. This value is not applicable to laser radiation.

Effective irradiance is defined as follows:   

E eff = λ=180nm 400nm E λ S (λ)Δλ

where: Eeff = effective irradiance

Eλ = spectral irradiance at exposure

S (λ) = relative spectral effectiveness (Table XIII)

Δλ = band width

Table XIII. Ultraviolet radiation and relative spectral effectiveness
Wavelength (nm)Relative spectral effectivenessWavelength (nm)Relative spectral effectivenessWavelength (nm)Relative spectral effectiveness
1800.0122800.8803250.00050
1900.0192850.7703280.00044
2000.0302900.6403300.00041
2050.0512950.5403330.00037
2100.0752970.4603350.00034
2150.0943000.3003400.00027
2200.1203030.1203450.00023
2250.1503050.0603500.00020
2300.1903080.0253550.00016
2350.2303100.0153600.00013
2400.3003130.0063650.00011
2450.3603150.0033700.000094
2500.4303160.00233750.000077
2540.5003170.00203800.000064
2550.5203180.00163850.000053
2600.6503190.00123900.000044
2650.8103200.00103950.000036
2701.0003220.000674000.000030
2750.9703230.00054

Members of the Committee for Recommendation of Occupational Exposure Limits (2019–2020)

Chairperson

Tetsuo Nomiyama (Matsumoto)

Members

Tetsuhito Fukushima (Fukushima), Kunio Hara (Tokyo), Hajime Hori (Kita-Kyusyu), Masayoshi Ichiba (Saga), Gaku Ichihara (Chiba), Michihiro Kamijima (Nagoya), Kanae Karita (Tokyo), Takahiko Katoh (Kumamoto), Toshihiro Kawamoto (Kita-Kyusyu), Shinji Kumagai (Kita-Kyusyu), Yukinori Kusaka (Fukui), Muneyuki Miyagawa (Tokyo), Yasuo Morimoto (Kita-Kyusyu), Hirokazu Okuda (Kanagawa), Tomotaka Sobue (Osaka), Toru Takebayashi (Tokyo), Tatsuya Takeshita (Wakayama), Yuko Yamano (Tokyo), Kazuhito Yokoyama (Tokyo)

Drafting members

Atsuko Araki (Sapporo), Kenichi Azuma (Osaka), Kouji Harada (Kyoto), Hyogo Horiguchi (Sagamihara), Yuki Ito (Nagoya), Satoko Iwasawa (Saitama), Takeyasu Kakamu (Fukushima), Akiko Matsumoto (Saga), Katsuyuki Murata (Akita), Hisao Naito (Nagoya), Makiko Nakano (Tokyo), Masayuki Okuda (Yamaguchi), Kazuhiro Sato (Fukui), Yasushi Suwazono (Chiba), Akito Takeuchi (Osaka), Teruomi Tsukahara (Matsumoto), Masashi Tsunoda (Saitama), Susumu Ueno (Kita-Kyusyu), Jun Ueyama (Nagoya), Yumi Umeda (Kanagawa), Kenya Yamamoto (Tokyo), Takenori Yamauchi (Tokyo)

Specialized members

Seichi Horie (Kita-Kyusyu), Tatsuya Ishitake (Fukuoka), Akiyoshi Ito (Kita-Kyusyu), Ayano Takeuchi (Tokyo), Hiroyuki Miyauchi (Kita-Kyusyu)

Advisory members

Ginji Endo (Osaka), Yoko Endo (Osaka), Masayuki Ikeda (Kyoto), Toshio Kawai (Osaka), Reiko Kishi (Sapporo), Akio Koizumi (Kyoto), Kasuke Nagano (Kanagawa), Tamie Nakajima (Nagoya), Kazuyuki Omae (Tokyo), Haruhiko Sakurai (Tokyo), Hiroshi Satoh (Tokyo), Masatoshi Tanaka (Fukushima), Shigeru Tanaka (Saitama), Eiji Yano (Tokyo)

 
© 2020 Japan Society for Occupational Health
feedback
 Top