Chemwatch : 22-2369 Version No : 3.1.1.1
Page 5 of 14 Fido ' s Everyday Shampoo
Issue Date : 02 / 13 / 2014 Print Date : 06 / 27 / 2016
Australia Exposure Standards |
formaldehyde solutions - non flammable |
Formaldehyde |
1.2 mg / m3 / 1 ppm |
2.5 mg / m3 / 2 ppm |
Not Available |
Sen |
EMERGENCY LIMITS |
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Ingredient Material name TEEL-1 TEEL-2 TEEL-3
formaldehyde solutions - non flammable
Formaldehyde Not Available Not Available Not Available
Ingredient Original IDLH Revised IDLH
lauryl sulfate , monoethanolamine salt
Not Available Not Available formaldehyde solutions - non flammable
30 ppm 20 ppm non hazardous ingredients , proprietary
Not Available
Not Available
water Not Available Not Available
MATERIAL DATA
NOTE D : Certain substances which are susceptible to spontaneous polymerisation or decomposition are generally placed on the market in a stabilised form . It is in this form that they are listed on Annex I When they are placed on the market in a non-stabilised form , the label must state the name of the substance followed by the words " non-stabilised " European Union ( EU ) List of harmonised classification and labelling hazardous substances , Table 3.1 , Annex VI , Regulation ( EC ) No 1272 / 2008 ( CLP ) - up to the latest ATP
Exposure controls
Engineering controls are used to remove a hazard or place a barrier between the worker and the hazard . Well-designed engineering controls can be highly effective in protecting workers and will typically be independent of worker interactions to provide this high level of protection . The basic types of engineering controls are : Process controls which involve changing the way a job activity or process is done to reduce the risk . Enclosure and / or isolation of emission source which keeps a selected hazard " physically " away from the worker and ventilation that strategically " adds " and " removes " air in the work environment . Ventilation can remove or dilute an air contaminant if designed properly . The design of a ventilation system must match the particular process and chemical or contaminant in use . Employers may need to use multiple types of controls to prevent employee overexposure .
General exhaust is adequate under normal operating conditions . Local exhaust ventilation may be required in special circumstances . If risk of overexposure exists , wear approved respirator . Supplied-air type respirator may be required in special circumstances . Correct fit is essential to ensure adequate protection . Provide adequate ventilation in warehouses and enclosed storage areas . Air contaminants generated in the workplace possess varying " escape " velocities which , in turn , determine the " capture velocities " of fresh circulating air required to effectively remove the contaminant .
Type of Contaminant : Air Speed :
Appropriate engineering controls solvent , vapours , degreasing etc ., evaporating from tank ( in still air ).
aerosols , fumes from pouring operations , intermittent container filling , low speed conveyer transfers , welding , spray drift , plating acid fumes , pickling ( released at low velocity into zone of active generation )
direct spray , spray painting in shallow booths , drum filling , conveyer loading , crusher dusts , gas discharge ( active generation into zone of rapid air motion )
grinding , abrasive blasting , tumbling , high speed wheel generated dusts ( released at high initial velocity into zone of very high rapid air motion )
Within each range the appropriate value depends on :
0.25-0.5 m / s ( 50-100 f / min )
0.5-1 m / s ( 100-200 f / min .)
1-2.5 m / s ( 200-500 f / min .)
2.5-10 m / s ( 500-2000 f / min .)
Lower end of the range
Upper end of the range 1 : Room air currents minimal or favourable to capture 1 : Disturbing room air currents 2 : Contaminants of low toxicity or of nuisance value only . 2 : Contaminants of high toxicity 3 : Intermittent , low production . 3 : High production , heavy use 4 : Large hood or large air mass in motion 4 : Small hood-local control only
Simple theory shows that air velocity falls rapidly with distance away from the opening of a simple extraction pipe . Velocity generally decreases with the square of distance from the extraction point ( in simple cases ). Therefore the air speed at the extraction point should be adjusted , accordingly , after reference to distance from the contaminating source . The air velocity at the extraction fan , for example , should be a minimum of 1-2 m / s ( 200-400 f / min ) for extraction of solvents generated in a tank 2 meters distant from the extraction point . Other mechanical considerations , producing performance deficits within the