Common Industrial Processes PDF

Summary

This document provides an overview of common industrial processes, focusing on materials handling, including solids and powders, liquids, and metals. It discusses potential hazards and control measures. The document emphasizes industrial hygiene practices.

Full Transcript

**COMMON INDUSTRIAL PROCESSES**

**9.1 INTRODUCTION**

There is a wide range of industrial processes that use and produce
hazardous substances. In the following sections a number of common
processes are briefly described. The purpose of this is to illustrate
typical exposure scenarios and ways in which exposure to hazardous
substances commonly occurs.

It is not intended to be a comprehensive listing of industrial
processes, nor is it intended to identify all the potential hazards
likely to be present in the particular processes. The range of processes
selected has been chosen to cover a wide range of industry sectors and
should provide the student with an overview of many of the workplace
hazards commonly encountered.

**9.2 MATERIALS HANDLING**

The following section looks briefly at a range of handling operations
for both solids and liquids. These handling operations are found in many
industries (e.g. paints, inks, pesticides, pharmaceuticals, polymers,
chemicals, mining, agriculture etc) and are often the source of exposure
to hazardous substances.

In accordance with good industrial hygiene practice consideration should
always be given to prevention of exposure. This may be by elimination or
substitution of the substance with a less hazardous material. Where this
is not practicable a combination of engineering, process and operational
controls, together with instruction and training may be required to
achieve adequate control. In many operations, local exhaust ventilation
may be necessary and as a last resort all the above may need to be
supplemented by the use of personal protective equipment. 128

**9.2.1 Handling of solids and powders**

Dust generation under normal working conditions depends essentially on
movement of some sort. This may occur at all stages of the process from
delivery of the material to the factory through various transfers,
weighing, sieving, filling and mixing operations.

**Selection of materials** - In some situations, dust generation can be
reduced or eliminated by using dust reduced forms of the substance which
contain small quantities of a binder. In addition the material may be
supplied in the form of pellets, granules or flakes which are less
liable to generate airborne dust. Completely dust free forms such as
pastes or powders dispersed in liquids may also be available. All of
these options are dependant on whether the reduced dust form of the
substance is compatible with the process requirements.

**Bulk powder delivery and transfer -** Large quantities of bulk
material may be supplied in bulk road or rail tankers or in tote bins,
which are then discharged into silos. Delivery from tankers by pneumatic
conveying is efficient and clean. However, it is reliant on the quality
of the seals between the tanker and the discharge point, and between the
tote bin and the silo. These seals and the flexible ducting need to be
maintained in good condition to prevent leaks as the ducting may be at
positive pressure.

Direct feed of bulk materials from storage silos to mixing may avoid the
need to handle the powder. While these systems are generally totally
enclosed, there may be a need to incorporate vents to account for air
displaced during silo filling and powder transfer. This displaced air
which will contain high levels of airborne dust must be cleaned prior to
discharge.

Bulk powder transfer is often undertaken by moving belt conveying
systems. These usually involve a number of transfer points at which dust
can become airborne. The amount of dust generated can be minimised by
reducing the height of the drop from the conveyor to a minimum and by
129

reducing any cross draughts. Conveyor transfer points may need to be
partially enclosed with local exhaust ventilation incorporated.

Bulk materials may also be delivered in paper or plastic bags;
intermediate bulk containers (IBC's) such as aluminium totes or octabins
or woven polyurethane sacks. Whenever dusty materials are transferred,
handled or used, spillages may occur. It is important that there are
good standards of housekeeping and cleanliness to minimise exposures and
contamination. Wet wiping methods and use of industrial vacuum cleaners
are preferred to the use of brushes which will render airborne settled
dust deposits.

(Source: Steve Bailey -- Reproduced with permission)

***Figure 9.1 -- Split bag containing sodium carbonate***

**Dust generation at powder handling processes -** Dust generation can
occur at a number of different processes including weighing, sieving,
charging (filling) of vessels and mixing (formulation). Whenever
containers are charged or filled with powders air, which may be
dust-laden, is displaced from the container. Depending on the amounts
and toxicity of the powders being handled full or partial enclosure may
be required incorporating local exhaust ventilation. 130

(Source: Steve Bailey -- Reproduced with permission)

***Figure 9.2 -- Manual loading of open mixer from drum***

A common potential problem is opening and emptying of bags containing
powders. The use of enclosed and automated bag and powder handling plant
can significantly reduce dust exposures. Systems are available that
automatically open, empty, evacuate and bale empty bags.

Weighing of mix ingredients may also be undertaken automatically in an
enclosed system; however, if manual weighing is required the use of
ventilated booths or laminar flow cabinets may be appropriate for
hazardous substances.

Sieving of some products may be required to break up agglomerates or
ensure that only products of a certain size range are included. If the
process is not fully enclosed, local exhaust ventilation is usually
needed. Vibratory action is often used and planned maintenance of
sieves, joints and connections is important. 131

**9.2.2 Handling of liquids**

As with solids, exposures to liquids and their vapours can occur at a
range of common operations. Bulk liquids may be supplied in bulk road or
rail tankers or in drums which may be transferred to storage tanks.
Transfer from tankers by enclosed transfer is efficient and clean.
However, it is reliant on the quality of the seals between the tanker
and the discharge point. These seals and the pipework and hoses need to
be maintained in good condition to prevent leaks. Seals and joints on
pipes, valves and pumps also need to be maintained in good condition to
prevent leaks and fugitive emissions.

(Source: Steve Bailey -- Reproduced with permission)

***Figure 9.3 -- Delivery of methanol from tanker***

Direct feed of liquids from storage tanks to point of use may avoid the
need to come into contact with the liquid. While these systems are
generally totally enclosed, there may be a need to incorporate vents to
account for air displaced during tank or container filling. This
displaced air may contain high levels of solvent vapour which should be
recovered or captured using local exhaust ventilation.

Exposure to liquids may also occur when pipework and vessels need
cleaning or maintenance. Systems need to be in place to ensure they are
effectively purged of hazardous materials prior to work. 132

Whenever containers are charged or filled with liquids such as solvents;
air which may contain high levels of solvent vapour is displaced from
the container. Depending on the amounts and toxicity of the liquids
being handled full or partial enclosure may be required incorporating
local exhaust ventilation.

Precautions need to be in place whenever liquids are transferred to
minimise the potential for spills and splashes. Other simple precautions
such as use of lidded containers and closing containers can reduce
exposure to vapours from evaporation of liquids.

(Source: Steve Bailey -- reproduced with permission)

***Figure 9.4 -- Paint bench -- open tins and rags soaked in thinners
can be a source of exposure***

**9.3 WORKING WITH METALS**

There is a range of different techniques that may be used to process and
fabricate metal products. This includes grinding, machining and welding
of metals and metal alloys.

**9.3.1 Grinding**

Grinding involves the use of a bonded abrasive to wear away parts of a
work piece to correct its dimensions, remove imperfections or increase
the smoothness of a surface. Natural abrasives (e.g. diamond and
sandstone) 133

have been largely replaced by artificial abrasives. These include
aluminium oxide, silicon carbide (carborundum) and synthetic diamonds.

(Source: HSE: Working with us on Noise and Hand-Arm Vibration 2008 --
Reproduced under the terms of the Click-Use licence)

***Figure 9.5 -- Grinding***

A variety of tools may be used to undertake grinding including grinding
wheels as well as grinding discs and belts.

Historically, a high incidence of silicosis occurred with the use of
sandstone grinding wheels. Modern grinding wheels are usually made of
corundum (an oxide of aluminium) and do not contain significant amounts
of crystalline silica. However, silica dust may still be produced from
materials being ground -- e.g. sand residues on sand castings. Local
exhaust ventilation is required for most grinding, belt sanding and
finishing operations.

(Source: Steve Bailey -- Reproduced with permission)

***Figure 9.6 -- Grinding*** 134

In addition to the risks from inhalation of airborne dusts, grinding
operations may also generate high noise levels and possibly significant
levels of vibration leading to a risk of hand-arm vibration syndrome
(HAVS), also known as "white finger".

**9.3.2 Machining of metals**

Machining of metal products is undertaken using a variety of machines
including lathes, drills and saws. These processes generally produce
relatively large metal particles and so airborne dust generation is low.
Grinding processes produce much finer dust and are therefore of more
concern in this respect. The main health hazard from machining is
related to cuttings fluids which lubricate and cool the process.

There are three main types of cutting fluids used;

- Mineral oils -- mineral oils of various viscosities are used
together with additives to provide specific characteristics

- Soluble oils -- soluble water-in-oil cutting fluids are mineral oils
that contain emulsifiers and additives including rust inhibitors and
bactericides. They are diluted with water in varying ratios before
being used

- Synthetic fluids -- synthetic cutting fluids are solutions of
non-petroleum based fluids, additives and water

Exposure to cutting fluids during work or maintenance may cause contact
dermatitis. Water-based cutting fluids may contain bacteria and cause
infections, and the emulsifiers may dissolve fats from the skin. Oil
folliculitis can occur with prolonged exposure to oil-based cutting
fluids. Dermatitis is best controlled by good hygiene practices and
minimising exposure. 135

1. A gas flame produced by the combustion of fuel gas such as acetylene
or propane with air or oxygen

An electric arc, struck between an electrode and a workpiece or
between two electrodes

Resistance to passage of electric current

Occupational exposure to oil mists and aerosols may cause a variety of
respiratory effects, including asthma, chronic bronchitis and impaired
pulmonary function.

**9.3.3 Welding and thermal cutting**

Welding is a generic term referring to a process by which metals are
joined together. This is often achieved by melting the metal in the area
to be welded and adding a filler material to form a pool of molten metal
which solidifies on cooling to form a strong joint. Common sources of
heat are:

**Gas welding --** this generally uses a combination of oxygen and
acetylene. The gases are fed to a hand held welding torch to produce a
flame. The heat melts the metal faces of the parts to be joined, causing
them to flow together. A filler metal or alloy with a lower melting
point than the parts to be joined is usually added. Chemical fluxes are
used to prevent oxidation and facilitate the welding process.

**Arc welding** -- an electric current is used to strike an arc between
an electrode connected to an electric supply and the materials to be
welded. The arc can generate temperatures up to about 4,000°C when the
pieces to be welded fuse together.

As with gas welding a filler metal or alloy is added to the joint. This
may be achieved by melting the electrode (consumable electrode process)
or by melting a separate filler rod which is not carrying the electric
current (non-consumable electrode process). 136

To ensure a strong weld is achieved it is vital that the welding area is
shielded from the atmosphere to prevent oxidation and minimise
contamination. The two main ways that this protection can be achieved
are by use of a flux or by use of an inert gas shield.

(Source: Steve Bailey -- reproduced with permission)

***Figure 9.7 -- Arc welding***

In flux-shielded arc welding the consumable electrode consists of a
metal core surrounded by the flux as a coating. The metal electrode core
acts as the filler material for the weld. The flux coating also melts
covering the molten metal with slag and by generating carbon dioxide
envelopes the welding area with a protective atmosphere. In gas-shielded
arc welding, a blanket of inert gas (e.g. argon, helium, nitrogen or
carbon dioxide) seals off the atmosphere and prevents oxidation and
contamination during the welding process. The two most common types of
gas-shielded arc welding are metal inert gas (MIG) welding sometimes
known as gas metal arc welding (GMAW) and tungsten inert gas (TIG)
welding. 137

**Resistance welding** -- this uses the heat generated by the resistance
to the passage of a high electric current through components to be
welded. Heat generated at the interface between the components brings
them to welding temperatures and small pools of molten metal are formed
at these points.

A common type of resistance welding is spot welding of thin metal
sheets. Two electrodes simultaneously clamp the sheets together and
electric current passes through the sheets. Weld strength is lower for
this type of welding but it is very easily automated and is energy
efficient. It is widely applied by industrial robots as in car
manufacturing.

**Health hazards of welding** -- airborne contaminants (including fumes
and gases) from welding and flame cutting arise from a variety of
sources:

- the metal being welded, the metal in the filler rod or constituents
of various types of steel (e.g. nickel or chromium)

- any metallic coating on the article being welded (e.g. zinc and
cadmium on plated metals)

- any paint, grease or dirt on the article being welded (e.g. carbon
monoxide, carbon dioxide and other irritant breakdown products)

- flux coating on the filler rod (e.g. inorganic fluoride)

- action of heat or ultraviolet light on the surrounding air (e.g.
nitrogen dioxide, ozone) or on chlorinated hydrocarbons (e.g.
phosgene)

- inert gas used as a shield (e.g. carbon dioxide, helium, argon)

Fumes and gases should be removed at the source by provision of local
exhaust ventilation. Where there is still a risk to health from toxic
fumes 138

and where local exhaust ventilation is not practicable a good standard
of respiratory protective equipment is necessary.

Additional hazards can occur when welding is undertaken in confined
spaces such as tanks and vessels and ventilation of the confined space
is important. This is required to remove contaminants produced by
welding and also to maintain sufficient oxygen levels. Gas welding uses
up oxygen as part of the process and gas shielded arc welding introduces
inert gases that can displace the oxygen in the space. Entry should only
be permitted after the area has been certified as safe as part of a
permit to work system.

Metal fume fever is associated with exposure to zinc oxide or copper
oxide fumes which can occur in areas such as brass founding and welding
of galvanized (zinc coated) steel. It is an acute effect that can occur
within a few hours of exposure. Flu-like symptoms include cough, nausea
and chills and fever. Recovery is usually complete within a day or two.
It particularly affects people new workers and people returning to work
after a break.

In addition to the chemical hazards other physical hazards are likely to
be present. High noise levels may be generated in several welding
processes. Intense levels of ultraviolet light are emitted by electric
arc welding. Even momentary exposure to ultraviolet radiation may
produce a painful conjunctivitis (photokeratinitis) known as "arc eye".
Exposure to the welder is prevented by use of visors or goggles that
prevent passage of ultraviolet light and by use of screens to prevent
exposure of others in the area. High levels of infra-red radiation may
be produced from the hot surfaces leading to potential thermal stress
issues. 139

(Source: Steve Bailey -- reproduced with permission)

***Figure 9.8 -- Arc gouging or cutting***

The following table summarises the main types of welding and any
specific health hazards. 140

----------------------------------------------------------------------------------- ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- ----------------------------------------------------------------------------------------------
***Table 9.1 Main types of welding and specific health hazards* Type of welding** **Description** **Specific health hazards**
**Gas welding and cutting**
Gas welding The flame melts the metal surface and filler rod to form a joint Metal fumes, nitrogen dioxide, carbon monoxide
Gas cutting The metal is heated by a flame and is directed onto the point of cutting and moved along the line to be cut Metal fumes, nitrogen dioxide, carbon monoxide
**Flux-shielded arc welding**
Manual metal arc welding (MMA) Uses a consumable electrode consisting of a metal core surrounded by a flux coating Metal fumes, fluorides, ultraviolet radiation; ozone, nitrogen dioxide
Submerged arc welding (SAW) Uses a consumable bare metal wire electrode. Granulated flux is deposited on the workpiece, which melts to produce a protective shield in the welding zone. Metal fumes, fluorides, ultraviolet radiation, ozone, nitrogen dioxide
**Gas-shielded arc welding**
Metal inert gas (MIG); gas metal arc welding (GMAW) Uses a consumable metal wire electrode of similar composition to the weld metal. It is fed continuously to the arc. Metal fumes, ultraviolet radiation, ozone, nitrogen dioxide, potential build up of inert gas
Tungsten inert gas (TIG); gas tungsten arc welding (GTAW) The tungsten electrode is non-consumable, and filler metal is introduced as a consumable into the arc manually. Metal fumes, ultraviolet radiation, ozone, nitrogen dioxide, potential build up of inert gas
**Electric resistance welding**
Resistance welding (spot, seam, projection or butt welding) High electric current at low voltage flows through the components from electrodes generating heat at the interface. Heat and pressure by the electrodes produces a weld. No flux or filler metal is used. Metal fumes, ozone
----------------------------------------------------------------------------------- ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- ----------------------------------------------------------------------------------------------

to a product e.g. nickel to protect against corrosion, chromium to
improve the surface properties. The product, wired as the cathode, and
an anode of the metal to be deposited are immersed in an electrolyte
solution (which can be acidic, alkaline or alkaline with cyanide salts)
and connected to a direct current.

(Source: Steve Bailey -- reproduced with permission)

***Figure 9.9 -- Electroplating bath with detergent foam*** 142

Positively charged metal ions migrate from the metal anode to the
cathode, where they are reduced to the metal and deposited as a thin
layer. This continues until the new coating reaches the desired
thickness, and the product is then washed, dried and polished.

(Source: Steve Bailey -- reproduced with permission)

***Figure 9.10 -- Electroplating bath fitted with local exhaust
ventilation***

Galvanizing applies a zinc coating to a variety of steel products to
protect against corrosion. Again, the product must be clean and
oxide-free before processing in order that the coating adheres properly.
This usually involves a number of cleaning or annealing processes before
the product enters the galvanizing bath.

**Chemical hazards of electroplating and galvanizing** -- the heated
alkaline and acid solutions used in cleaning and treatments of metals
are corrosive. They can cause burns and irritation to the skin and to
mucous membranes and the eyes.

Nitric and hydrofluoric acid are a particular problem if inhaled, as it
may be many hours before the effects on the lungs become apparent.
Pneumonitis and potentially fatal pulmonary oedema may appear later in a
worker who suffered little initial effect from the exposure. Skin
contact with hydrofluoric acid can cause severe burns without pain being
noticed for several hours. 143

Baths containing cyanide solutions are frequently used in electrolytic
degreasing and electroplating. If cyanides react with an acid hydrogen
cyanide can be generated. Fatal exposures may also result from skin
absorption or ingestion of cyanides.

Chromic and nickel compounds are used in electroplating. Chromium
compounds are usually present in the form of chromic acid, where the
chromium is in its hexavalent state. This can cause burns and ulcers to
the skin as well as perforation of the nasal septum. Nickel salts can
cause allergic dermatitis and irritation. There is evidence that both
chromium and nickel compounds are carcinogenic.

**9.5 SOLDERING AND BRAZING**

Soldering and brazing are similar processes where metal items are joined
together by heating and melting a filler metal or alloy with a flux that
flows into the joint. They differ from welding in that the metals being
joined do not melt during the process as the filler metal has a much
lower melting point.

Soldering and brazing are distinguished from each other in that
soldering is undertaken at temperatures below 450 0C, whereas brazing is
undertaken at temperatures above 450 0C.

Health hazards depend on the metal or alloys being melted and the type
of flux used. Soft soldering using lead / tin alloy based solders is
widely used in the electrical and electronics industries to make
electrical connections. 144

(Source: Steve Bailey -- reproduced with permission)

***Figure 9.11 -- Soldering***

As soldering is undertaken at lower temperatures metal fumes are
generally of little concern. The main health risk from soldering is from
the breakdown products of the flux. The flux is commonly rosin based and
the breakdown products from this are potent respiratory sensitizers.

(Source: HSE Rosin-cored solder fume assessment: Health and Safety
Laboratory -- reproduced under the terms of the Click-Use licence)

***Figure 9.12 -- Fumes from soldering***

Rosin is a naturally occurring, solid, resinous material obtained from
pine trees. The flux helps the soldering by cleaning the surfaces to be
joined, increasing the flow of the solder and preventing oxidation. 145

The main health effects occur from the breakdown at high temperatures
(or pyrolysis) of the rosin.

- When heated, particularly to temperatures above 200°C, rosin-based
solder fluxes form fumes containing a range of resin acid
particulates and other components as gases. Lower temperatures can
significantly reduce the amount of fume produced. Between 250°C and
400°C particulate fume levels can triple.

- When inhaled, rosin-based solder flux fume can lead to occupational
asthma. Rosin-based solder flux fume is regarded as one of the most
important causes of occupational asthma. The effects are permanent
and irreversible. Continued exposure, even to very small amounts of
fume, may cause asthma attacks and the person affected may not be
able to continue work with rosin-based fluxes

- The fume can also cause irritation to the eyes and upper respiratory
tract. It has not been possible to identify a safe level of exposure
below which occupational asthma will not occur. Exposure to all
rosin-based solder flux fumes should, therefore, be avoided or kept
as low as is reasonably practicable

- Without effective control, solder fume rises vertically and for
manual operations is likely to enter the breathing zone of the
worker. If not captured at source other people may be affected by
build up of background levels. Adequate control often requires the
use of local exhaust ventilation; this may be conventional LEV or a
low volume high velocity system directly applied near the soldering
iron tip. Health surveillance may also be required

- Soldering is also used to form joints in plumbing and pipe fitting.
Use of a gas torch can raise temperatures high enough to produce
lead fume. The use of lead free solders is sometimes required, but
in either case, the risks from breakdown of the flux are still
present

146

In general brazing uses borax or fluoride based fluxes. In 'silver
soldering' -- a type of brazing -- the metal alloy or flux may contain
significant quantities of cadmium. Cadmium free replacements are
available with alloys containing silver, copper and tin.

The fume can also cause irritation to the eyes and upper respiratory
tract. It has not been possible to identify a safe level of exposure
below which occupational asthma will not occur. Exposure to all
rosin-based solder flux fumes should, therefore, be avoided or kept as
low as is reasonably practicable

o

Without effective control, solder fume rises vertically and for manual
operations is likely to enter the breathing zone of the worker. If not
captured at source other people may be affected by build up of
background levels. Adequate control often requires the use of local
exhaust ventilation; this may be conventional LEV or a low volume high
velocity system directly applied near the soldering iron tip. Health
surveillance may also be required

o

Soldering is also used to form joints in plumbing and pipe fitting. Use
of a gas torch can raise temperatures high enough to produce lead fume.
The use of lead free solders is sometimes required, but in either case,
the risks from breakdown of the flux are still present

146

In general brazing uses borax or fluoride based fluxes. In 'silver
soldering' -- a type of brazing -- the metal alloy or flux may contain
significant quantities of cadmium. Cadmium free replacements are
available with alloys containing silver, copper and tin.

9.6 DEGREASING

Many industrial products need to be cleaned at one or more stages of
their manufacture to remove unwanted dirt and grease that would
interfere with subsequent processes such as painting, plating or
soldering where cleanliness of the article is essential.

Solvents are used for degreasing a wide range of items from large metal
panels to electronic components. Degreasing processes can be divided
into two broad categories -- cold degreasing and vapour degreasing.

Cold degreasing uses a solvent at ambient temperature. It includes hand
cleaning by wiping and brushing as well as larger operations that use
spraying of the solvent. In some cases immersion and use of ultrasonic
cleaning is undertaken. Vapour degreasing involves immersing the article
in solvent vapour that condenses on the article and runs off taking the
grease and dirt with it.

9.6.1 Cold degreasing

Dip cleaning is the simplest operation where the articles to be cleaned
are immersed in the solvent. The cleaned articles are then removed by
lifting out of the solvent (preferably in wire baskets so that they can
freely drain excess solvent). Removal should be carried out slowly to
allow sufficient drain time. Covers should be kept on dip tanks as far
as possible to reduce emission of solvent vapours into the workplace.

147

Wiping is more applicable for cleaning large items of equipment but
solvent use should be kept to a minimum. Used cloths containing solvent
residues should be stored in lidded containers and disposed safely.

Brush cleaning can be used to dislodge particles which are not
effectively removed by dipping or wiping. The item to be cleaned is
usually placed in a tray to collect the solvent. Care needs to be taken
to minimise splashing of the solvent.

Spraying is useful to clean areas that are inaccessible to wiping and
brushing - it may avoid the need to dismantle components for cleaning.
However, spraying can lead to high solvent vapour concentrations.

9.6.2 Vapour degreasing

Vapour degreasing is an effective and widely used technique for cleaning
of components. The vapour degreasing plant consists of a steel tank
partly filled with solvent with a heater at the base. The solvent vapour
rises to fill the tank to a height determined by a series of cooling
coils in the upper part of the tank that act as a condenser.

There is usually is a slotted duct (lip extraction) around the rim of
the tank connected to an exhaust ventilation system to prevent escape of
vapour from the tank.

148

(Source: Envirowise GG354 -- Surface cleaning and preparation: choosing
the best option -- reproduced with permission)

Figure 9.13 -- Conventional top loading vapour degreaser

When a 'dirty' component is lowered into the vapour layer formed above
the heated solvent, the vapour condenses on the cold surface of the
component and dissolves any soluble contaminants. As the vapour
condenses, the liquid drains back into the boiling solvent, carrying
some of the 'dirt' with it. This process continues as more vapour
condenses on the component.

When the temperature of the component reaches that of the vapour,
condensation on the component effectively ceases and the cleaning
process stops. The cleaned components are then lifted slowly to drain
fully while still within the tank. Various degrees of automation can be
applied and plant can be integrated into conveyor production lines.

It is then removed and allowed to cool to normal temperature. The
soluble and insoluble dirt removed collects in the sump at the bottom of
the plant. When the concentration of oil and dirt in the sump reaches a
certain level, the solvent is recovered by distillation and may be used
again. After cooling the oily residue can be removed and discarded.

149

(Source: Steve Bailey -- reproduced with permission)

Figure 9.14 -- Large vapour degreasing tank fitted with cooling coils
and slot extraction at the rim

Degreasing solvents that are commonly used in industry include
trichloroethylene and tetrachloroethylene. For specific applications,
various products containing individual solvents, mixtures of solvents or
emulsions are available.

Poor operating methods and inadequate maintenance can lead to increased
solvent emission in the working area. Common operating faults include:

o

poor stacking of hollow bodies -- e.g. tubes / cups should be stacked at
an angle or rotated within the vapour zone to empty any solvents trapped
in the article

o

insufficient drying time -- the components must be held in the

150

freeboard above the vapour layer for sufficient time to allow

evaporation of solvent residues

o

lifting the components at too high a speed

o

excessive movement of components in the bath causing disturbance of the
solvent vapour layer

Procedures need to be in place during maintenance and removal of sludge
from the base of the tank. The tank may be considered a confined space
and high concentrations of solvent vapour may be present. Safe work
procedures including a permit to work may be required to prevent
potentially fatal exposure.

It should be noted that chlorinated solvents are readily decomposed by
hot surfaces and open flames. The toxic decomposition products include
phosgene, hydrogen chloride and carbon monoxide. Smoking and hot
processes such as welding should be prohibited in the vicinity of the
degreasing operations.

9.7 PAINTING

Paints and related products such as varnishes and lacquers are widely
used in industry to provide a surface coating for corrosion protection,
for appearance or other special purposes.

Health risks can arise from solvents, additives or in particular
respiratory sensitisation from isocyanates in polyurethane paints. The
risks vary considerably in because of the variety of products and
constituents, the range of situations in which they are used and the
different methods of application.

Solvent exposure is usually the most significant health risk during
painting. The solvents used vary considerably between products and
include aliphatic and aromatic hydrocarbons, ketones, alcohols, glycols
and glycol ethers and esters. The use of low solvent content or water

151

based paints is becoming more widespread. (Water based paints still
contain some solvents but these are at much lower concentrations).

The amounts of solvent in paints used vary considerably (e.g. 5 - 50%).
However, the paint may be thinned at the point of use, and the thinner
may be of different composition to the primary solvent.

Paint application methods fall into three main groups:

o

paint is applied to the surface by brush or roller

o

paint is applied by spray techniques

o

the surface is immersed in paint and allowed to drain, as in dipping and
flow coating.

In general, paint for spray application will contain more solvent than
those for application by brush or roller.

9.7.1 Exposure to solvents in painting

Painting with brush or roller involves relatively slow application of
paints. The operator continually moves away from the most recently
treated area and exposure largely depends on the general ventilation of
the area.

Spray painting generally involves higher rates of application, larger
areas and higher solvent content. Also spraying of liquids containing
solvents can produce high levels of solvent vapour as the fine spray
produced allows rapid evaporation of the solvent.

The use of respiratory protective equipment may be required if the area
is enclosed or because of other constituents, e.g. applying anti-fouling
paint containing pesticide to the hull of a ship in dry dock or spraying
an isocyanate paint to vehicles in a closed booth or to an aircraft in a
hangar.

152

Spray painting of smaller items on a production line may be done with an
automatic spray gun or by an operator from outside a ventilated
open-fronted booth. Conventional air spraying is the most commonly used
method of painting in industry. A potential problem with air spraying is
that large quantities of solvent vapour may be generated and overspray
of the paint is common.

(Source: HSE LEV Trainer Adviser Briefing Days -- reproduced with
permission)

Figure 9.15 -- Spraying isocyanate based paint in paint spray booth

Electrostatic spraying; which has become more widespread places a charge
on the paint mist particle so it is attracted to the part to be painted.
This reduces rebound and overspray and consequently reduces mist and
solvent exposure to the operator.

In powder coating, the paint powder is conveyed from a powder reservoir
to the spray gun. In the gun, an electrical charge is imparted to the
paint particles. The powder is sprayed onto the electrically grounded
item to be coated and the parts baked to fuse the powder into a
continuous coating.

Most industrial flow and spray painting operations require exhaust

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ventilation for control of solvent vapors at the point of application
and also during drying and baking operations. The use of automated spray
painting allows for greater use of ventilated enclosures and minimises
worker exposure.

As stated earlier, particular care must be taken in the application of
two-component urethane and epoxy paint systems that contain isocyanates
which are potent respiratory sensitisers. This includes effective
ventilation control and protective clothing. In addition where exposure
cannot be effectively controlled by ventilation the operators should
wear air-supplied respirators.

Dermatitis due to primary irritation and de-fatting from solvents or
thinners is common. Skin contact must be minimised, adequate washing
facilities should be available, and suitable protective equip-ment used
by the operator.

(Source: Steve Bailey -- reproduced with permission)

Figure 9.16 -- Paint mixing -- skin and airborne exposure can occur to
solvents and pigments

In addition to the hazards from the solvents, there may also be

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hazards from pigments such as lead, cadmium and chromium compounds. Also
some paints contain additives such as fungicides and pesticides.