CHEMICAL HYGIENE PLAN
JOHN CARROLL UNIVERSITY
Version 7 (effective 29th Aug. 1996)
This document replaces the previous Chemical Hygiene Plan (version 6)
and sets forth procedures, equipment, personal protective equipment
and work practices that
(i) are designed to protect employees of John Carroll University (JCU)
who work in JCU laboratories from the health hazards presented by
hazardous chemicals used in the JCU laboratories and,
(ii) meet the requirements of paragraph (e) Part 1910 of title 29
of the Code of Federal Regulation (CFR), "Occupational Exposures to
Hazardous Chemicals in Laboratories", published by the Department of
Labor, Occupational Safety and Health Administration (OSHA).
Statement of Policy.
John Carroll University is committed to protecting the health
and safety of its employees in their work within the university.
Recognizing that particular health risks may be encountered by employees
who operate in laboratories where hazardous chemicals are in use, the
administration endorses the implementation of the Chemical Hygiene Plan
herein. The goal of this plan is to make JCU laboratories as safe as
possible, and to ensure the continuing protection of faculty, student
assistants and all other employees who work within the labs, as well as
the students who are trained in them.
The ultimate responsibility for excellent safety and health
performance lies with the employees themselves. Employees should be
always vigilant and dedicated to safety practices as a first priority.
There can be no room for carelessness or for casual attitudes.
Responsibility for implementation of this plan lies with all
employees, but the effort will be coordinated by the Chemical Hygiene
Officer, Dr. P. R. Challen, of the Chemistry Department. He is available
to provide assistance to employees in fulfilling their safety
responsibilities.
Sources.
This document has been adapted from the following sources:
Department of Labor; OSHA; 29 CFR Part 1910
"Prudent Practices for Handling Hazardous Chemicals in Laboratories";
Committee on Hazardous Substances in the Laboratory, Assembly of
Mathematical and Physical Sciences, National Research Council;
National Academy Press; Washington, D.C. 1981.
"Safety in Academic Chemistry Laboratories"; American Chemical Society.
"OSHA Laboratory Standard Implementation Guide"; Leo C. Hearn, Jr., CIH,
Steven L. Goode, CSP, CIH, David F. Coble, CSP; Lewis Publishers
TABLE OF CONTENTS
Part 1. STANDARD OPERATING PROCEDURES 3
1.1 Description of the JCU Chemistry Laboratory Facility 3
1.2 General lab safety policies 4
i. Eye protection 4
ii. Clothing 5
iii. Gloves 5
iv. Personal hygiene 5
v. Laboratory protocol 5
vi. Housekeeping 6
vii. Cleaning glassware 6
viii. Transporting chemicals 6
ix. Disposal 6
x. Unattended operation of equipment 7
xi. Fume hoods and ventilation 7
xii. Refrigerators 8
xiii. Working alone 8
xiv. Dealing with chemical exposure 8
1.3 Procedure for handling materials received from chemical suppliers 8
1.4 General procedures for handling chemicals in the labs 9
i. Flammability: 9
ii. Toxic or corrosive vapors: 10
iii. Corrosive liquids and solids: 10
iv. Toxic liquids and solids: 10
v. Highly toxic substances, carcinogens and other substances
warranting special procedures: 10
vi. Dry ice and liquid nitrogen: 11
1.5 Storage and Transportation of Hazardous Materials 11
1.6 Equipment use 12
i. Glassware 12
ii. Assembling apparatus 12
iii. Fume Hoods 13
iv. Centrifuges 13
v. Lasers 14
vi. X-ray generators 14
vii. Compressed gases 14
1.7 Operations 16
i. Extractions 16
ii. Distillations 16
iii. Temperature control 17
iv. Reduced Pressure Operations 17
PART 2. EXTRA PROTECTIVE MEASURES FOR PARTICULARLY HAZARDOUS SUBSTANCES 19
2.1 Carcinogens and Reproductive Toxins. 19
2.2 Substances which have a high degree of acute toxicity, or a
moderate degree of chronic toxicity. 20
2.3 Substances with a high degree of chronic toxicity (including
known carcinogens). 21
PART 3. CRITERIA FOR IMPLEMENTATION OF CONTROL MEASURES 23
3.1 Environmental monitoring 23
3.2 Housekeeping, Maintenance and Inspections. 23
i. Cleaning. 23
ii. Inspections. 23
iii. Maintenance. 23
3.3 Medical Program 23
i. Compliance with regulations. 24
ii. Routine surveillance. 24
3.4 Safety and Emergency Equipment 24
PART 4. FUME HOODS AND OTHER ENGINEERING CONTROLS 25
4.1 Fume hoods: Purpose 25
4.2 Hood availability. 25
4.3 Hood Inspection and Maintenance 25
4.4 Hood use 25
4.5 Storage cabinets 26
4.6 Special ventilation areas. 26
4.7 General laboratory ventilation. 26
PART 5. EMPLOYEE INFORMATION AND TRAINING 27
5.1 Hazard Information 27
5.2 Training 27
PART 6. PRIOR APPROVAL OF LABORATORY ACTIVITIES 28
6.1 Permit System 28
6.2 Off-Hours Work Procedures. 28
6.3 Sole Occupancy 28
6.4 Hazardous Work 28
6.5 Unattended Operations 28
PART 7. MEDICAL CONSULTATIONS AND EXAMINATIONS 29
PART 1. STANDARD OPERATING PROCEDURES
This section describes general equipment in use in JCU labs, and
general operating procedures to be followed when working in those labs or
in other places in the JCU chemistry department (such as the stockroom)
where hazardous chemicals may be encountered. The procedures apply to both
teaching and research laboratories.
Safety is an ongoing and active concern in a laboratory. All
employees are responsible to their peers for ensuring that specific
standard safety procedures are followed by everyone involved. Safety
in the laboratory depends on critical judgements and how each team member
applies the information that is made available and observes the procedures.
The approval of the Department Head and/or the Safety Officer is required
before any deviations from these procedures are permitted.
1.1 Description of the JCU Chemistry Laboratory Facility
The JCU chemistry department, located on the 2nd floor of the Bohannon
Science Building, consists of two(2) General Chemistry Teaching Labs,
two(2) Organic Chemistry Teaching Labs, one(1) Physical Chemistry
Teaching Lab, one(1) Analytical Chemistry Teaching Lab, one(1)
Biochemistry Teaching Lab, one(1) Instrumentation Lab, ten(10) Research
Labs, a Stockroom, a solvent and waste storage room (adjacent to the
loading dock), an acid storage room (adjacent to the "Radiochemistry"
lab.), several lecture rooms, and departmental offices.
The ventilation system of the building brings air from outside via
ducts in the walls of the 3rd floor. This air is mixed with air drawn
from inside the building and either heated or cooled, depending on the
season. The air is forced under positive pressure into the labs, offices
and other rooms. Other vents allow air out of the rooms and return it
to be mixed with outside air. The fume hoods draw air from the labs,
mix it with air drawn from outside and pass it up to the roof and out
through vents.
Each teaching lab contains the following general features:
Bench areas where most experiments and other manipulations are carried
out.
Sinks on each bench for washing hands, rinsing glassware, other uses of
flowing water (condensers, aspirators etc) and disposal of a limited
number of non-hazardous materials.
Outlets for water, gas and air on each bench.
Safety shower attachments on each bench for a fire victim and for
providing water rinse.
Eye-wash attachments on most sinks at the ends of the benches.
Fume hoods for operations with hazardous gases, flammable liquids,
materials that evolve hazardous vapors (toxic or flammable), and certain
operations with very hazardous materials.
Fire blankets for use on a fire-victim.
Fire Extinguisher.
Eye wash bottles.
First-aid kit.
The organic labs and general labs contain in addition:
Safety showers.
The stockroom contains:
Supplies of chemicals, glassware and apparatus.
Oxygen supply for medical emergencies.
Eye-wash bottles
First-aid kit.
Respirators and gas-masks.
Material safety data sheets (MSD sheets) and other safety data.
The stockroom is off-limits to non-authorized personnel.
Authorized personnel include the stockroom manager, chemistry department
faculty and administrators, stockroom assistants, and certain graduate
and undergraduate assistants. Students who do not fall into one of the
above categories are not allowed in the stockroom.
By virtue of the large volume of chemical supplies that are stored
therein, the stockroom should be regarded as a potentially hazardous
place, and the same precautions and safety procedures that apply to
labs also apply in equal or greater force to the stockroom.
The solvent storage room contains bulk storage containers of flammable
solvents as well as some other toxic or smelly chemicals and containers
of waste chemicals. It is ventilated and insulated from the rest of the
building by brick walls. Access is restricted to the stockroom manager
and chemistry faculty.
1.2 General lab safety policies
The following is adapted from the American Chemical Society document
"Safety in Academic Chemistry Laboratories". It is applicable to students
under the direction of employees as well as to the employees themselves.
i. Eye protection
All people in the laboratory including visitors must wear eye protection
at all times. This should take the form of safety goggles, which provide
protection from the side as well as from the front. Wearing of contact
lenses in the lab is forbidden because contact lenses can hold foreign
materials against the cornea. Furthermore they may be difficult to
remove in the event of a splash. Soft contact lenses present a particular
hazard because they can absorb and retain chemical vapors.
ii. Clothing
Clothing worn in the lab should offer protection from splashes and spills,
should be easily removable in case of an accident, and should be at least
fire resistant. High-heeled or open-toed shoes, sandals, or shoes made
of woven material should not be worn in the lab. If shorts or short
skirts are worn, a lab coat should be worn to provide leg protection.
Long hair and loose clothing should be constrained. Jewelry such as
rings, bracelets, and watches should not be worn in order to prevent
chemical seepage under the jewelry, contact with electrical sources,
catching on equipment, and damage to the jewelry itself.
iii. Gloves
Plastic or rubber gloves should be worn when handling corrosive, toxic
or carcinogenic materials. Check to ensure the absence of cracks or
small holes in the gloves before each use. The gloves should be discarded
immediately after use to prevent the spread of chemicals to telephones,
doorknobs, lab notebooks and the like. When handling chemicals in a hood,
the gloves should be removed in the hood before leaving the hood area,
and they should not be removed from the hood until they are free of
hazardous chemicals. Be aware that if a chemical diffuses through a
glove, that chemical is held against the hand and the exposure is worse
than if the glove had not been worn. For this reason gloves should be
removed and discarded at frequent intervals, and the hands promptly and
thoroughly washed. Not all glove materials provide protection against
all chemicals. Choice of an appropriate glove based on knowledge of the
resistant properties of the glove material to the chemicals being handled
should be made with due care.
iv. Personal hygiene
Everyone working in a chemical lab should be aware of the dangers of
ingesting chemicals. These common sense precautions will minimize the
possibility of such exposure:
Do not prepare, store (even temporarily), or consume food or beverages
in any laboratory.
Do not smoke in any laboratory. Additionally, be aware that tobacco
products in opened packages can absorb chemical vapors.
Do not apply cosmetics in a lab
Wash hands and arms thoroughly before leaving the lab, even if gloves
have been worn
Wash lab coats separately from other laundry
Never wear or bring lab jackets or gloves into areas where food is
consumed
Never pipette by mouth. Always use a pipette aid or suction bulb
v. Laboratory protocol
The lab is a place for serious learning and working. Horseplay cannot be
tolerated. Variations in procedures including changes in quantities or
reagents may be dangerous. It is the responsibility of employees to
insist that students under their direction follow proper lab protocol,
both for the students' own safety and for the safety of the employees
and all others in the lab.
vi. Housekeeping
In the lab and elsewhere, keeping things clean and neat generally leads
to a safer environment. Avoid unnecessary hazards by keeping drawers
and cabinets closed while working. Never store materials, especially
chemicals, on the floor, even temporarily. Work spaces and storage areas
should be kept clear of broken glassware, leftover chemicals and scraps
of paper. Packaging materials and empty boxes may constitute a fire
hazard and should be removed from the lab promptly after unpacking.
Keep aisles free of obstructions such as chairs, boxes and waste
receptacles. Avoid slipping hazards by keeping the floor clear of ice,
glass beads or rods, other small items, and spilled liquids.
vii. Cleaning glassware
Clean glassware at the laboratory sink. Use plastic buckets to carry
glassware to the sink area and heavy rubber gloves when washing glassware.
Use hot water and detergent and avoid the use of organic solvents if
possible. Avoid the use of strong oxidizing cleaning solutions such
as chromic sulfuric acid mixtures since these present an explosion
hazard under certain circumstances. Special non-chromium cleaning
agents are commercially available. Take care of broken glass hidden
in turbid water. To minimize breakage of glassware, sink bottoms
should have rubber or plastic mats which do not block the drains.
viii. Transporting chemicals
Refer also to 1.5 "Storage and Transportation of Hazardous Materials"
below. Transport all chemicals using the container-within-a-container
concept. This will shield them from shock during any sudden change of
movement. Use of plastic buckets to carry bottles of flammable solvents
or corrosive materials is strongly recommended. Large containers (more
than one liter) should not be used for routine transfer of materials.
Rather the material should be transferred first to a smaller container.
When a flammable liquid is withdrawn from a drum, or when a drum is
filled, both the drum and the other equipment should be electrically
wired to each other and to the ground in order to avoid the possible
buildup of a static charge.
ix. Disposal
The handling of reaction byproducts, surplus and waste chemicals, and
contaminated materials is an important part of laboratory safety
procedures. Each lab worker is responsible for ensuring that wastes are
handled in a manner that minimizes personal hazard and recognizes the
potential for environmental contamination. The following is the standard
procedure to be followed in the lab on a routine basis.
Dispose of waste materials promptly. When disposing of chemicals one
basic principle applies: Keep each different class of chemical in a
separate clearly labeled disposal container. Disposal containers are
available from the stockroom.
Never put chemicals into a sink or down the drain unless they are
deactivated or neutralized and they are allowed by local regulation in
the sanitary sewer system. If in doubt, use a waste container not the
sink. Be aware that a sink may contain a chemical which will adversely
react with the chemical you are dumping (e.g. an acid sink with a sulfide
will evolve deadly hydrogen sulfide gas).
Put ordinary waste paper in a wastepaper basket separate from the
chemical wastes. If a piece of paper is contaminated, such as paper
toweling used to clean up a spill, put the contaminated paper in a
special container that is marked for this use. It must be treated as a
chemical waste. The container should be labeled with a description that
identifies the chemical on the paper.
Broken glass belongs in its own marked waste container. If the glass is
contaminated with chemical, the name of the chemical should be added to
the label of the container. Broken mercury thermometers belong in a
separate "broken mercury thermometer" container, since they may contain
mercury in the fragments.
x. Unattended operation of equipment
See also 6.5
Reactions that are left to run unattended overnight or at other times are
prime sources for fires, floods and explosions. One should always
consider a "worst case scenario" before leaving a reaction unattended.
Do not let equipment such as power stirrers, hot plates, heating mantles,
and water condensers run overnight without fail-safe provisions. Check
unattended reactions periodically. Always leave a note plainly posted
with a phone number where you can be reached in case of emergency.
Remember that in the middle of the night emergency personnel are entirely
dependent on accurate instructions and information.
xi. Fume hoods and ventilation
A large number of common substances present acute respiratory hazards and
should not be used in a confined area in large amounts. They should be
dispensed and handled only where there is adequate ventilation, such as
in a hood. This applies also to flammable liquids and gases (see General
Procedures for handling chemicals in the labs). Adequate ventilation is
defined as ventilation that is sufficient to keep the concentration of a
chemical below the threshold limit value (TLV) or permissible exposure
limit. If you smell a chemical, it is obvious that you are inhaling it.
However, odor does not necessarily indicate that a dangerous concentration
has been reached. By contrast, many chemicals can be present at hazardous
concentrations without any noticeable odor. As a rule of thumb, use a
hood or other local ventilation device when working with any appreciably
volatile substance with a TLV of less than 50 ppm.
xii. Refrigerators
Refrigerators are notorious sources of leaks of hazardous or smelly
chemicals. The refrigerator should be explosion-proof. Chemicals stored
in refrigerators should be sealed, double packaged if possible, and
labeled with the name of the material, the date placed in the
refrigerator, and the name of the person who stored the material.
Freezer bags are useful in this regard. Chemicals should be stored in a
refrigerator only with good reason (e.g. they deteriorate at room
temperature, they develop too high a pressure at room temperature, they
evaporate too fast at room temperature) and not because they are smelly
or toxic (fume hoods, or a ventilated storage cabinet are better for
these substances). Food should never be stored in a refrigerator used
for chemical storage and vice-versa.
xiii. Working alone
See also Part 6.
A Chemical Hygiene Permit (Appendix B) is required for any employee
working in a laboratory with hazardous chemicals when no-one else is
in the building.
Avoid working alone in a building; do not work alone in a laboratory if
the procedures being conducted are very hazardous.
xiv. Dealing with chemical exposure
In the event of exposure of a large area of the body or clothing to a
hazardous chemical, the safety showers should be used. These provide
continuous drenching for an unlimited period.
A smaller area of exposure, such as a hand or part of an arm, can be
treated using the shower attachments located next to the sinks in all labs.
Chemicals in the eyes should be rinsed out using the eyewash attachments
located in the sinks in all labs. Eyes should be rinsed for several
minutes. Bottles of eye-rinse can be used for further rinsing.
Do not use organic solvents such as alcohol or acetone to rinse hazardous
chemicals from the skin. These solvents may carry the hazardous chemical
into the skin and worsen the situation. Always rinse with water as a
first action, then later wash the area thoroughly with soap and water.
Further first-aid treatment can be carried out in the stock-room where
bandages, anti-septic creams and other items are available.
If additional medical treatment is needed, the victim should be taken to
a local emergency facility, or an ambulance called.
1.3 Procedure for handling materials received from chemical suppliers
DO NOT UNDERESTIMATE THE POTENTIAL HAZARDS ASSOCIATED WITH ANY CHEMICAL.
New information is constantly being accumulated, and chemicals once
considered harmless are often found to have harmful properties. Do not
rely exclusively on your chemical training, however extensive that may be.
Always consult safety data as described below.
Upon receiving any chemical from a supplier, the Material Safety Data
(MSD) sheet accompanying the material should be read carefully with a
view to establishing the particular hazards associated with the chemical,
and the correct procedures for opening, handling, using, storing, and
disposing of the chemical. The law requires all chemical suppliers to
provide such information. If the MSD sheet has not yet been received
from the company and it is deemed necessary to open and use the chemical,
the following procedure should be adopted:
i. The file of MSD sheets in the stockroom should be consulted to
ascertain if the relevant sheet is already on file.
ii. The Aldrich-Sigma catalog of safety data should be consulted.
This two-volume book, kept in the stockroom next to the MSD sheets,
contains safety information on 14,500 chemicals supplied by Aldrich-Sigma.
The information is less extensive than that covered by MSD sheets, but
nevertheless includes the most pertinent hazard and safety procedure
information.
iii. Consult the catalog of the chemical company from which the
chemical was purchased to find more (usually brief) information on
potential hazards.
iv. Read the warnings on the outer and inner packaging of the
chemical. Most chemicals come in boxes containing layers of metal
cans, other boxes, plastic wrapping etc. and a final container (usually
glass) containing the material. Any or all of these wrappings may contain
hazard warnings. The final inner container will certainly contain a list
of hazards. Consult the sheet with explanations of codes and technical
terms which is contained in the Aldrich-Sigma volumes (see ii. above).
This will explain less familiar terms such as carcinogen, teratogen etc.
1.4 General procedures for handling chemicals in the labs
As a general principle when ordering chemicals which are known to be
hazardous one should order no more than is to be used in a short period
of time (weeks rather than months). This will alleviate the problem of
storage of hazardous materials. Most labs and stockrooms are replete
with containers of chemicals which have been sitting for years and which
have deteriorated and now present a disposal problem. Such problems can
be avoided with a little forethought.
Before using any chemical in the lab, and before allowing any student to
handle the chemical, the Material Safety Data (MSD) sheet should be
consulted to establish correct safety procedures. These sheets have
been described above. Copies of the MSD sheets relating to each chemical
in common use in each lab will be posted in those labs. In addition
there are the files of MSD sheets in the stockroom as well as additional
safety data sources in the stockroom. Care should be taken to establish
the following hazards:
i. Flammability:
Highly flammable liquids or gases should not be used in any lab in which
flames, sparks or other potential sources of ignition are present. Use
of a fume-hood is good safety practice for the transfer of flammable
materials from one container to another.
ii. Toxic or corrosive vapors:
Any material (solid, liquid or gas) which gives rise to toxic or
corrosive vapors should be stored, handled and disposed in a fume-hood.
The fume-hood should be examined prior to opening the container of
chemical to establish that (a) it is turned on (b) it is operating
properly (i.e. it is generating a draft of air in which air flows from
the lab into the hood and upwards toward the hood's exhaust vents. A
quick way to check this is to partially close the hood's front screens
and place a piece of Kimwipe or tissue paper in the opening to see if
it is blown into the hood and upwards toward the vents). (c) it has been
serviced and checked for face velocity.
If an appropriate respirator or gas-mask is indicated by the safety
information it may be obtained from the stock-room.
iii. Corrosive liquids and solids:
These should be handled with due caution. Gloves (plastic or rubber)
and a lab coat should be worn. Of course, safety goggles, which should
be worn at all times in the lab, are vitally important when handling such
materials.
iv. Toxic liquids and solids:
Measures should be taken to prevent contact with the skin, eyes, mouth
and lungs. Eye protection must be worn. If vapors or dust are involved
the material should be handled in a fume hood. An appropriate respirator
or gas-mask may be indicated by the safety information and may be
obtained from the stock-room.
v. Highly toxic substances, carcinogens and other substances
warranting special procedures:
Acute toxins, certain carcinogens, and other substances with particularly
severe harmful properties require special procedures in their handling
and disposal. A list of some of these substances which may be encountered
in our laboratories is appendix A of the CHP. By no means is this list
to be considered complete in the sense that a substance not appearing on
the list is not a special hazard or is never to be encountered in our
laboratories. Rather the list should be regarded as an attempt to focus
on well-known highly toxic or specially hazardous materials that are more
likely to be encountered in our labs than other such specially hazardous
materials. The list draws attention to this class of severely hazardous
substances. It should not, however, take the place of a thorough review
of the MSD sheets and other safety data as described in 1.3. If there is
doubt concerning the special hazards of a substance, its use should be
avoided or postponed until the properties have been investigated and the
necessary safe procedures understood.
Highly toxic gases must be used and disposed within a fume-hood whose
efficient operation has been previously established. The gas should be
used in a system which is closed except for an outlet through which
unused gas is allowed to vent via a trap which removes, chemically or
otherwise, the highly toxic gas. The highly toxic gas must not be
allowed to pass into the hood in an uncontrolled fashion; every effort
should be made to contain it within the system and to render it less
harmful at the place where it eventually vents into the hood. This
procedure will minimize the possibility of exposure to the gas of both
the operator and the environment. Respirators are available in the
stockroom which can handle certain highly toxic gases up to certain
concentrations. These respirators should be regarded as a final line
of defense against the toxic gas and not as a substitute for the safe
procedures outlined above. Their use would be called for, for example,
if the above controls were found not to be capable of adequately limiting
the escape of the gas into the lab, and temporary protection were required
for the operator while the generation or flow of toxic gas was cut off.
vi. Dry ice and liquid nitrogen:
These extremely cold (cryogenic) materials present a number of potential
hazards. They may burn the skin on contact and should be handled using
insulating gloves designed for the purpose. Before pouring liquid
nitrogen into a Dewar flask, the flask should be "tempered" with a
small quantity of the cold material to prevent it cracking and imploding
from thermal shock. The possibility of the condensation of liquid oxygen
should be considered when using liquid nitrogen. Liquid oxygen is
potentially explosive, especially when in contact with oxidizable
materials such as grease. Thus a system connected to a liquid nitrogen
trap should not be opened to the atmosphere until the trap has been
removed. Also, if the system is closed after even a brief exposure to
the atmosphere, some oxygen (or argon) may have already condensed.
Then, when the liquid nitrogen bath is removed or when it evaporates,
the condensed gases will vaporize with attendant pressure buildup and
potential blowup. When adding dry ice to a solvent to prepare a "slush
bath" the rapid bubbling and foaming of the mixture should be anticipated.
Such an operation should be carried out in a fume hood. Isopropanol or
ethanol should be used in preference to acetone since they are cheaper,
less toxic, less flammable, and less prone to foaming. A less flammable
mixture of ethylene glycol or propylene glycol in a 3:2 mixture with
water and thinned with Isopropanol may also be used. Add the dry ice
to the liquid in small amounts, waiting for the foaming to subside before
proceeding with the addition. Dry ice and liquid nitrogen baths should
never be closed systems since they can develop uncontrolled and
dangerously high pressures.
1.5 Storage and Transportation of Hazardous Materials
Before opening any package, establish, by consulting the sources of
information referred to in 1.3 i - iv above, the correct place to store
the chemical before and after use. Highly flammable liquids should be
stored in flame-proof metal cabinets; liquids or solids which evolve
toxic or corrosive vapors should be stored in vented cabinets or fume-
hoods; heat sensitive and/or thermally unstable materials should be
refrigerated in an explosion-proof refrigerator; cylinders of toxic or
corrosive gases should be stored in fume-hoods; large tanks of gases
should be stored in the room next to the stockroom, and when in use in
labs should be well secured by clamping to a fixed support (such as a
bench; clamps are available in the stockroom); liquid nitrogen and
dry-ice (solid carbon dioxide) should be stored in the designated
containers. If a material has a combination of the above properties
such that it is unclear as to the correct storage procedure, consult
the Chemical Hygiene Officer before opening the package.
Containers of hazardous chemicals should be transported in plastic
buckets to reduce the possibility of breakage through impact, and to
contain the materials in the event of breakage of the primary container.
Large containers of flammable or corrosive liquids should never be
carried without using a secondary container such as a plastic bucket.
Gas tanks should be transported from the storage room to the lab in the
wheeled cart which is kept in the stockroom. These containers should be
promptly clamped to a bench or other fixed support as described above.
Dry ice should be transported in a Dewar or other cryogenic container.
Liquid nitrogen should be transported in a special carrying Dewar.
1.6 Equipment use
The following is adapted from the American Chemical Society document
"Safety in Academic Chemistry Laboratories". It is applicable to
students under the direction of employees as well as to the employees
themselves.
i. Glassware
Borosilicate glassware is recommended for all laboratory glassware
except for special experiments that use UV or other light sources.
Any glass equipment to be evacuated, such as suction flasks, should
be specially designed with heavy walls. Dewar flasks and large vacuum
vessels should be taped or contained in a metal jacket to prevent flying
glass in the case of an implosion.
ii. Assembling apparatus
Following these recommendations will help make apparatus assembly easier
and equipment use safer:
Use only equipment that is free from flaws. Glassware can be examined
in polarized light for strains. Do not use flasks that contain star-
cracks, especially in vacuum work.
A properly placed pan under a reaction vessel or container will confine
spilled liquids in the event of glass breakage.
When working with flammable gases or liquids, do not allow burners or
other ignition sources in the vicinity. Note that electrical devices
such as stirrer plates can be sources of ignition through electrical
sparking. Use a fume hood. Use appropriate traps, condensers or
scrubbers to minimize release of material to the environment. If a
hot plate is used, ensure that its temperature is less than the
autoignition temperature of the chemicals likely to be released and
that the temperature control device does not spark.
Whenever possible, use controlled electrical heaters or steam in
place of gas burners.
Condensers should be properly supported with securely positioned
clamps and the attached water hoses secured with wire or clamps.
A vent should be provided as part of the apparatus for chemicals that
are to be heated.
Whenever hazardous gases or fumes are likely to be evolved, an
appropriate gas trap should be used and the operation confined to
a fume hood.
Use a hood when conducting a reaction that could result in an explosion
or when using a vacuum system (which may implode). Close the sash to
provide a shield. If a hood is not available, use a standing shield.
Proper eye and face protection must be worn even when using the shields
or hood.
iii. Fume Hoods
Fume hoods serve to control exposure to toxic, offensive or flammable
vapors. Apparatus used in hoods should be fitted with condensers, traps
or scrubbers to contain or collect waste solvents or toxic vapors. The
hood is not an appropriate means for disposing of chemicals, nor is it a
storage cabinet. Stored chemicals can interfere with efficient hood
operation, and in the event of an accident or fire, every item in the
hood may become involved.
Before each use, check that the hood is working properly. Although not
a substitute for velometer measurement, a continuous monitoring device
such as a narrow strip of tissue paper can be used to ensure that the
hood is operating. Adequate air flow and the absence of excessive
turbulence are necessary for safe operation. Exhaust ports from the
hood and supply air vents to the room should not be blocked. Sash
openings should be kept to a minimum. Horizontal sashes or combined
horizontal and vertical sashes make this easier to do. Users should
keep their faces outside the plane of the hood sash and should remain
alert to changes in air flow. Equipment should be placed as far back
in the hood as practical and activities carried out at least six inches
from the front edge of the hood.
iv. Centrifuges
If a tabletop centrifuge is used, make certain that it is securely
anchored in a location where its vibration will not cause bottles or
equipment to fall. The following rules apply to the safe operation
of centrifuges:
Always close the centrifuge lid during operation.
Do not leave the centrifuge until full operating speed is attained.
Stop the centrifuge immediately and check the load balances if vibration
occurs. Check swing-out buckets for clearance and support.
Regularly clean rotors and buckets with non-corrosive cleaning solutions.
v. Lasers
The FTIR instrument in the instrumentation lab contains a visible laser,
and the FT Raman instrument in the Analytical Research lab contains a
near infra-red laser. Normal operation of these instruments should not
involve any health risk. Do not look directly into the beam source, or
allow any object into the sample compartment which might deflect the beam.
vi. X-ray generators
The powder diffractometer in the Physics Department generates X-rays.
Potential hazards arise from the radiation generated and the high
voltage used. Warning signs must be displayed on or near the main
power switch of the instrument. Do not use this instrument without
first acquiring detailed instructions and safety information. Do not
tamper with the beam-stop mechanism. Check that the cooling-water supply
to the X-ray tube is connected and operating properly.
vii. Compressed gases
Gases are often supplied in cylinders under high pressure. These
present some hazards beyond the chemical hazards associated with the
gases themselves. The procedures for the proper use of compressed gases
include:
Handle cylinders of compressed gases as high-energy sources and therefore
as potential explosives.
Restrain cylinders of all sizes, empty or full, by strapping them to a
solid, firm support, and by using a suitable stand.
When storing or moving cylinders, have the protective caps securely in
place to protect the valve stems.
When moving large cylinders use the special cart kept in the stockroom.
Never lubricate, modify, force, or tamper with cylinder valves.
Use toxic, flammable, or reactive gases in fume hoods only. Cylinders
should be stored in the ventilated room adjacent to the stockroom.
Smoking and eating or drinking are forbidden in that room.
Do not extinguish a flame involving a highly combustible gas until the
source of gas has been shut off; otherwise it can re-ignite causing an
explosion.
Close the main cylinder valve tightly when not in use.
Promptly remove the regulators from empty cylinders and replace the
protective caps at once. Mark the empty cylinder.
Never bleed cylinders completely empty. Leave a slight pressure to
keep contaminants out.
Use the appropriate regulator on each gas cylinder. The threads on the
regulators are designed to avoid improper use. Adaptors or homemade
modifications can be dangerous.
Do not put oil or grease on the high pressure side of an oxygen,
chlorine, or other oxidizing agent cylinder. A fire or explosion can
result.
1.7 Operations
The following is adapted from the American Chemical Society document
"Safety in Academic Chemistry Laboratories". It is applicable to students
under the direction of employees as well as to the employees themselves.
i. Extractions
Extracting a solute from an aqueous phase by means of a volatile organic
solvent (such as ether or chloroform) can present a hazard because of the
possible buildup of pressure. Glass separatory funnels are commonly used
for this operation. A buildup of pressure could result in the ejection
of the stopper or stopcock and the spilling of the liquid. The following
procedure is designed to minimize this risk.
Do not attempt to extract a solution until it is cooler than the boiling
point of the extracting solvent. When a volatile solvent is used, the
unstoppered separatory funnel should first be swirled to allow some
solvent to vaporize and expel some air. Close the funnel and invert
it with the stopper held in place and immediately open the stopcock to
release more air plus vapor. This should be done with the hand
encompassing the barrel to keep the stopcock plug securely seated.
The operation should be carried out away from flames and preferably
in a fume hood. Close the stopcock, shake with a swirl, and immediately
open the stopcock to again vent the vapors. The procedure can be
repeated to complete the extraction, each time venting the vapors
through the stopcock with the funnel in the inverted position. If
it is necessary to use a separatory funnel larger than 1 liter for
an extraction with a volatile solvent, the force on the stopper may
be too great and cause the stopper to be expelled. Consider performing
the extraction in several smaller batches.
ii. Distillations
Distillations may be carried out at atmospheric pressure, under inert
atmosphere, at reduced pressure (vacuum distillations), and using steam
(steam distillation). Dangers arise from the pressures that may buildup,
the flammability of the materials, and the use of heat. Each type of
distillation involves a particular design of apparatus, and experimental
descriptions and diagrams should be consulted.
The distillation should be carried out in a fume hood whenever possible.
Heat should never be applied to a system in which there is no outlet for
the excess pressure to escape.
Bumping should be avoided by stirring the distillation mixture, or by
using boiling stones (only effective for distillations at atmospheric
pressure).
Even heating is important, especially under reduced pressure, to avoid
local hot-spots. A flame should not be used. Heating mantles, steam
rings or hot water baths, silicone or mineral oil baths on a hot plate,
sand baths, and metal blocks with appropriately sized cavities can all
be used.
Never evaporate organic solvents to dryness, especially ethers or other
organics which may form peroxides. These peroxides can be highly
explosive and have led to many documented cases of serious injuries.
Bumping is particularly common with vacuum distillations. A standing
shield should be used for protection in the event of implosion. Heating
should be even, and evacuation should be carried out gradually. The
apparatus should be securely clamped. The mixture should be magnetically
stirred, or an air or nitrogen bleed tube should be used.
iii. Temperature control
Care should be taken when reagents are first mixed. An exothermic
reaction may have an induction period during which time little reaction
or heating occurs, followed by a rapid reaction with the release of heat
and too rapid boiling of the solvent. To avoid this, one reagent should
be added in small amounts to the other, with a cooling bath available to
quickly cool down the mixture if necessary. The apparatus should be set
up so that heating or cooling can be applied or withdrawn readily.
Test tubes should be held with a test tube holder, shaken while
cautiously heated, and pointed away from people. A hot water bath,
steam bath, or oil bath are preferable to a flame. If a Bunsen burner
is used it should be a small flame without a blue cone, and the test
tube should be alternately heated and removed from the flame, with
shaking, and spreading the heat uniformly around the tube to avoid
the contents being ejected.
If oil baths are used, care should be taken to ensure that the oil is
water free, since the presence of water can cause violent bumping and
splashing of the hot oil. Mineral oil or silicone oil may be used.
Do not heat beyond the flash point of the oil. Do not leave a hot oil
bath unattended.
For cooling baths use ice water, or ice/salt if lower temperatures are
required. For very low temperatures use a dry ice slush bath or liquid
nitrogen. For appropriate procedures in using these materials see
1.4 (vi) above.
iv. Reduced Pressure Operations
Special care should be taken with glassware under reduced pressure
("vacuum").
Vacuum desiccators and vacuum line bulbs should be wrapped in duct tape
to prevent flying glass in the event of an implosion.
Only heavy walled flasks should be used for vacuum filtration.
Vacuum pumps should be protected from vapors by means of a cold trap.
Exhausts from vacuum pumps should be vented to the hoods whenever
possible.
Portable explosion guards are available for reactions or other
operations carried out under reduced pressure. See the stockroom
manager or safety officer.
PART 2. EXTRA PROTECTIVE MEASURES FOR PARTICULARLY HAZARDOUS SUBSTANCES
2.1 Carcinogens and Reproductive Toxins.
Before any package from a chemical company is opened, or before any
chemical is used, the MSDS and other safety information available in
the stockroom should be consulted, as described in 1.3. If the
information refers to the chemical as being a carcinogen (cancer
causing agent), teratogen (causes fetal mutation), embryotoxin or
reproductive toxin, special precautions may need to be taken.
Examples of OSHA-regulated carcinogens are 2-Acetylaminofluorene,
acrylonitrile, 4-aminobiphenyl, asbestos, benzidine,
bis(chloromethyl)ether, 3,3'-Dichlorobenzidine (and its salts),
4-Dimethylaminoazobenzene, ethyleneimine, inorganic arsenic,
methyl chloromethyl ether, 4,4'-methylene-bis(2-chloroaniline),
a-naphthylamine, §-naphthylamine, 4-Nitrobiphenyl, N-Nitrosodimethylamine,
§-Propiolactone, vinyl chloride. Examples of embryotoxins are
organomercurials, lead compounds, formamide. The package should
not be opened or the chemical used until the safety officer has been
consulted. The safety officer will determine whether the special
precautions described below will need to be followed.
Special precautions:
Embryotoxins: These are substances that act during pregnancy
to cause adverse effects on the fetus. These effects include
embryolethality (death of the fertilized egg, the embryo, or the
fetus), malformations (teratologic effects), retarded growth, and
postnatal functional deficits. If you are a woman of childbearing
age, handle these substances only in a hood whose satisfactory
performance has been confirmed, using appropriate protective apparel
(especially gloves) to prevent skin contact. Store these substances,
properly labeled (e.g. EMBRYOTOXIN: READ SPECIFIC PROCEDURES FOR USE),
in an adequately ventilated area in an unbreakable secondary container.
Notify supervisors of all incidents of exposures or spills; consult a
qualified physician when appropriate (e.g. skin contact or any inhalation
by a woman of child-bearing age).
Select Carcinogens: Use and store these substances only in areas
of restricted access with special warning signs. Always use a hood
(previously evaluated to confirm adequate performance with a face
velocity of at least 60 linear feet per minute) or other containment
device for procedures which may result in the generation of aerosols
or vapors containing the substance. Do not dispose of these materials
by evaporation into the hood. If practical, waste materials and waste
solvents containing select carcinogens should be decontaminated
chemically by some procedure that can reasonably be expected to
convert essentially all of the material to non-carcinogenic substances.
If chemical decontamination is not feasible, the waste carcinogens
should be stored in closed impervious containers so that personnel
handling the containers will not be exposed to their contents. In
general, liquid residues should be contained in glass or polyethylene
bottles half-filled with vermiculite. The containers should carry the
warning: CANCER-CAUSING AGENT. Contaminated clothing or shoes should be
thoroughly decontaminated or incinerated. The lab worker should be
prepared for possible accidents or spills. If a carcinogen contacts
the skin, the area should be washed well with water. If there is a
major spill outside the hood, the room or appropriate area should be
evacuated and cleanup personnel should wear suitable protective apparel
and equipment (refer to the MSDS). If the material is volatile, or
produces dust, the cleanup personnel should wear a supplied-air
full-face respirator. Records should be kept that include amounts of
material on hand, amounts used and names of workers involved. These
records will normally be a part of the laboratory notebook record of
the experiment.
2.2 Substances which have a high degree of acute toxicity, or a
moderate degree of chronic toxicity.
Before any package from a chemical company is opened, or before any
chemical is used, the MSDS and other safety information available in
the stockroom should be consulted, as described in Part 1 (c). If the
information in the "Health Hazard Data" section of the MSDS or other
information describes the substance as being "highly toxic", "acutely
toxic", "severe health hazard" or contains other indications of extreme
toxicity, special precautions may need to be taken. Examples of acute
toxins are hydrogen cyanide, hydrogen sulfide, hydrofluoric acid, arsine,
nitrogen dioxide, di-isopropyl fluorophosphate. Substances of moderate
chronic toxicity are those for which infrequent exposure to small
quantities does not constitute a significant health risk, but which
can be dangerous to those exposed to high concentrations or repeated
small doses. Substances which are not known to cause cancer in humans,
but have shown statistically significant, but low, carcinogenic potency
in animals fall into this category. Examples are very numerous, and the
MSDS should be used as the appropriate indicator. The package should not
be opened or the chemical used until the safety officer has been
consulted. The safety officer will determine whether the special
precautions described below will need to be followed.
Special precautions:
At least two people should be present at all times if the compound is
highly toxic. Areas where highly toxic substances are being used and
stored should have restricted access, and special warning signs should
be posted. Protect the hands and forearms by wearing gloves and a
laboratory coat to prevent contact of toxic material with the skin.
Always wash hands and arms immediately after working with these
materials. Use a hood (previously evaluated to confirm adequate
performance with a face velocity of at least 60 linear feet per minute).
Store breakable containers of these substances in pans or trays of
polyethylene or other chemically resistant material; also mount
apparatus above such trays, or line the hood with a chemically resistant
liner to contain spills. If a major spill occurs outside the hood,
evacuate the area, and ensure that cleanup personnel wear suitable
protective apparel and equipment (refer to the MSDS). Do not dispose
of these materials by evaporation into the hood. If practical, waste
materials and waste solvents containing these materials should be
decontaminated chemically by some procedure that can reasonably be
expected to convert essentially all of the material to non-toxic
substances. If chemical decontamination is not feasible, the waste
toxins should be stored in closed impervious containers so that
personnel handling the containers will not be exposed to their contents.
In general, liquid residues should be contained in glass or polyethylene
bottles half-filled with vermiculite. The containers should carry the
warning: ACUTE TOXICITY. Contaminated clothing or shoes should be
thoroughly decontaminated or incinerated. Records should be kept that
include amounts of material on hand, amounts used and names of workers
involved. These records will normally be a part of the laboratory
notebook record of the experiment.
2.3 Substances with a high degree of chronic toxicity (including
known carcinogens).
Before any package from a chemical company is opened, or before any
chemical is used, the MSDS and other safety information available in
the stockroom should be consulted, as described in Part 1 (c). If the
information in the "Health Hazard Data" section of the MSDS or other
information describes the substance as having a "high degree of chronic
toxicity", or "causes cancer in humans", or "shows high carcinogenic
potency in test animals", special precautions may need to be taken.
Examples include certain heavy metal compounds (e.g. dimethyl mercury
and nickel carbonyl), benzo-a-pyrene (3,4-benzpyrene),
N-nitrosodiethylamine (diethylnitrosamine), and strong carcinogens.
These substances may be cumulative toxins whose harmful effects are
subtle and not immediately apparent but are often irreversible. They
may be harmful in very small quantities. If they are to be used in
quantities in excess of a few milligrams to a few grams (depending on
the hazard posed by the particular substance), the additional
precautions described below should be used. The package should not be
opened or the chemical used until the safety officer has been consulted.
Special precautions:
In addition to the procedures described above for substances of high
acute or moderate chronic toxicity, the following extra precautions
should be taken for substances of high chronic toxicity:
Prepare a plan for use and disposal of the materials, and
obtain the approval of the laboratory supervisor or safety officer.
Conduct all transfers and work with these substances in a "controlled
area": a restricted access hood, glove box, or portion of a lab., for
which all people with access are aware of the substances being used
and necessary precautions. Any area being used for storage of substances
of high chronic toxicity should be maintained under negative pressure
with respect to surrounding areas. Controlled areas should be clearly
marked with a conspicuous sign such as WARNING:TOXIC SUBSTANCE IN USE or
CANCER-SUSPECT AGENT: AUTHORIZED PERSONNEL ONLY. If a positive pressure
glove box is used with highly toxic compounds, the box should be checked
for leaks before each use, and the exit gases should be passed through a
suitable trap or filter. Lab vacuum pumps should be protected by
high-efficiency scrubbers or HEPA filters, and vented into an exhaust
hood. Vacuum pumps and other contaminated equipment, including glassware,
should be decontaminated in a hood before removal from the controlled
area. On leaving a controlled area, remove any protective apparel
(placing it in an appropriate container with a label such as
CAUTION: CONTENTS CONTAMINATED WITH SUBSTANCES OF HIGH CHRONIC TOXICITY
and a list of the contaminants) and thoroughly wash hands, forearms,
face and neck. Waste chemicals (including washings from contaminated
flasks) should be collected and either decontaminated chemically, or
placed in closed, suitably labeled containers for incineration away
from the controlled area. An example of decontamination would be the
treatment of b-propiolactone, bis(chloromethyl)-ether or methyl
chloromethyl ether with concentrated aqueous ammonia for 10 min.
An appropriate label for waste would be CAUTION: COMPOUNDS OF HIGH
CHRONIC TOXICITY or CAUTION: CANCER-SUSPECT AGENT followed by a list
of the waste chemicals. Normal work in the controlled area should
resume only after adequate decontamination has been achieved. In
the event of repeated use of a substance of high chronic toxicity a
qualified physician should be consulted to ascertain whether regular
medical surveillance is advisable.
PART 3. CRITERIA FOR IMPLEMENTATION OF CONTROL MEASURES
3.1 Environmental monitoring
Regular instrumental monitoring of airborne concentrations is not
usually justified or practical in laboratories but may be appropriate
when testing or redesigning hoods or other ventilation devices, or
when a highly toxic substance is stored or used regularly.
If a chemical falls under the category of "particularly hazardous
substance" as described in Part 2, and if the particular chemical is
in use more than three times in a week, the safety officer should be
consulted about setting up air sampling.
If there is reason to believe that exposure levels for a hazardous
chemical exceed the OSHA "action level" or, in the absence of an action
level, the OSHA "Permissible Exposure Limit" (PEL), the safety officer
should be consulted about setting up air sampling. The action levels
and PELs are listed in the OSHA publication 29 CFR part 1910, the
relevant section of which will be appended to the CHP. Reasons for
believing that the action levels are exceeded could be
(a) Malfunction or possible inadequacy of a control device such as a hood.
(b) Excessive smell of a chemical which has a pronounced odor.
(c) Indications of toxic effects on persons in the vicinity.
The results of air sampling studies will be recorded in a form which
will be appended to the CHP.
3.2 Housekeeping, Maintenance and Inspections.
i. Cleaning.
Floors should be cleaned regularly. All spills on lab benches or
floors should be immediately cleaned and properly disposed of. The
lab benches should be kept clear of equipment and chemicals except
those necessary for the work currently being performed. All floors,
aisles, exits, fire extinguishing equipment, eyewashes, showers,
electrical disconnects and other emergency equipment should remain
unobstructed. Chemical containers should be clean, properly labeled
and returned to storage upon completion of usage. All chemical wastes
should be disposed of in accordance with the directions described in
other parts of the CHP.
ii. Inspections.
Formal housekeeping and chemical hygiene inspections should be held
biannually; informal inspections should be continual.
iii. Maintenance.
Safety showers and eye wash equipment should be inspected quarterly.
Fume hoods should be inspected biannually, and the hood face velocity
(at half-height) maintained at between 75 and 150 linear feet per minute.
A record of inspections should be maintained by the Chemical Hygiene
Officer.
3.3 Medical Program
i. Compliance with regulations.
Regular medical surveillance should be established to the extent
required by regulations.
ii. Routine surveillance.
Anyone whose work involves regular and frequent handling of
toxicologically significant quantities of a chemical should consult
a qualified physician to determine on an individual basis whether a
regular schedule of medical surveillance is desirable.
3.4 Safety and Emergency Equipment
Telephone numbers of emergency personnel, supervisors and other
workers as deemed appropriate will be posted. All laboratory personnel
will be trained in the proper use of fire extinguishers when hired and
annually thereafter. All employees who might be exposed to chemical
splashes shall be instructed in the location and proper usage of
emergency showers and eyewashes. The eyewash and emergency shower
shall be inspected monthly. These inspections shall be performed by
the safety officer and helpers, and shall be in accordance with ANSI
Z358.1 and manufacturer's specifications. Records shall be maintained.
Location signs for safety and emergency equipment will be posted.
PART 4. FUME HOODS AND OTHER ENGINEERING CONTROLS
4.1 Fume hoods: Purpose
As well as their function as local ventilation devices used to prevent
toxic, offensive or flammable vapors from entering the general
laboratory atmosphere, hoods offer two other significant types of
protection. With the hood sash closed, a physical barrier is placed
between the worker and the chemical reaction. This can provide
protection from splashes, sprays, fires, and minor explosions.
Furthermore, the hood can provide an effective containment device
for accidental spills of chemicals.
4.2 Hood availability.
In a laboratory where workers spend most of their time working with
chemicals, there should be at least one hood for each two workers,
with at least 2.5 linear feet of hood space at the face. In teaching
labs where hoods are used intermittently, experiments should be designed
so that students have access to hood space whenever they conduct an
operation which requires such ventilation (see Part 1.4).
4.3 Hood Inspection and Maintenance
Hoods will be inspected biannually for the following features:
i. Adequate face velocity (60-150 linear feet per minute).
ii. Uniformity of air delivery (lack of turbulence) across the
face area at various sash positions.
iii. Appropriate baffle position to give uniform air flow across
the hood and into the vent ducts.
The latest inspection was completed during July '97. The documentation
from this inspection is available from the stockroom manager or from the
Safety Officer.
4.4 Hood use
i. Confirm adequate hood ventilation performance prior to opening
chemical containers inside the hood. An inward flow of air can be
confirmed by holding a piece of paper at the face of the hood and
observing the movement of the paper.
ii. Keep the sash of the hood closed at all times except when
adjustments within the hood are being made. At these times, maintain
the sash height as low as possible.
iii. Storage of chemicals and equipment inside the hood shall be
kept to a minimum.
iv. Minimize interference with the inward flow of air into the hood.
v. Leave the hood operating when it is not in active use if hazardous
chemicals are contained inside the hood or if it is uncertain whether
adequate general laboratory ventilation will be maintained when the hood
is non-operational.
vi. The hood shall not be used as a means of disposal for volatile
chemicals.
4.5 Storage cabinets
i. Flammable solvents and substances which yield corrosive or toxic
vapors should be stored in ventilated cabinets designed for the purpose.
Such cabinets can be found in the stockroom, the organic lab, and some
research labs. The cabinets should be vented into a fume hood, and an
adequate supply of air should pass so as to remove the vapors.
4.6 Special ventilation areas.
i. Exhaust air from glove boxes should be passed into a hood. If
the glove box is of the negative pressure type, and a particularly toxic
material is being handled inside, the exhaust air will require special
treatment before release into the regular exhaust system. Glove boxes
of the positive pressure type, such as are used to handle air-sensitive
materials under inert atmosphere, should be checked for leaks if highly
toxic materials are inside. There should be a method of monitoring the
integrity of the system, such as a pressure gage.
4.7 General laboratory ventilation.
i. This system should provide a source of air for breathing and for
input to local ventilation devices.
ii. It should not be relied upon for protection from toxic substances
released into the lab.
iii. It should continually replace the laboratory air, preventing
increase of air concentrations of toxic substances during the working
day. A rate of 4-12 room air changes/hour is adequate, provided fume
hoods are in operation as the primary method of toxic vapor control.
iv. Air flow should be directed into the laboratory from non-
laboratory areas and out to the exterior of the building.
v. General air flow should not be turbulent and should be
relatively uniform throughout the laboratory, with no high velocity or
static areas.
PART 5. EMPLOYEE INFORMATION AND TRAINING
5.1 Hazard Information
All employees will be apprised of the hazards presented by the chemicals
in use in the laboratory. Each employee shall receive training at
the time of initial assignment to the laboratory, prior to assignments
involving new exposure situations, and at a regular frequency as
determined by the Chemical Hygiene Officer.
5.2 Training
This training shall include methods of detecting the presence of a
hazardous chemical, physical and health hazards of chemicals in the lab,
and measures employees can take to protect themselves from these hazards.
The training shall present the details of the Chemical Hygiene Plan, and
shall include;
i. The contents of the OSHA laboratory standard, and its appendices.
ii. The location and availability of the Chemical Hygiene Plan.
iii. The permissible exposure limits for OSHA regulated substances or
recommended exposure values for other hazardous chemicals not
regulated by OSHA which are present in the laboratory.
iv. Signs and symptoms associated with exposure to the chemicals
present in the laboratory.
v. Location and availability of reference material on chemical
hygiene.
PART 6. PRIOR APPROVAL OF LABORATORY ACTIVITIES
6.1 Permit System
A permit system shall be used for laboratory activities which present
specific, foreseeable hazards to the employees. These activities
include off-hours work, sole occupancy of building, extremely hazardous
operations and unattended operations. The permit entitled "Chemical
Hygiene Permit" will be included as an appendix to this plan and shall
be executed prior to the performance of these activities.
6.2 Off-Hours Work Procedures
Work in labs outside of normal working hours is permitted with the
approval of the appropriate faculty member. A Chemical Hygiene Permit
should be filled out (Appendix B).
6.3 Sole Occupancy
At no time shall hazardous work be performed in the laboratory when the
only person in the building is the laboratory person performing the work.
Under unusual conditions, cross-checks, periodic security guard checks,
or other measures may be taken when permitted. A Chemical Hygiene Permit
should be filled out (Appendix B).
6.4 Hazardous Work
All hazardous operations are to be performed during a time when at least
two personnel are present at the laboratory. At no time shall a
laboratory person, while working alone in the laboratory, perform work
which is considered hazardous. The determination of hazardous operations
shall be made by the appropriate faculty member.
6.5 Unattended Operations
When laboratory operations are performed which will be unattended by
laboratory personnel (continuous operations, overnight reactions, etc.),
the following procedures will be employed:
i. The faculty member will review work procedures to ensure for the
safe completion of the operation.
ii. An appropriate sign will be posted at all entrances to the
laboratory.
iii. Precautions shall be made for the interruption of utility
service during the unattended operation (loss of water pressure,
electricity, etc.).
iv. The person responsible for the operation will return to the
laboratory at the conclusion of the operation to assist in the
dismantling of the apparatus.
PART 7. MEDICAL CONSULTATIONS AND EXAMINATIONS
An opportunity to receive medical attention is available to all
employees who work with hazardous chemicals in the laboratory. The
opportunity for medical attention will be made available to employees
under the following circumstances:
i. Whenever an employee develops signs or symptoms associated with
a hazardous chemical to which the employee may have been exposed
in the laboratory,
ii. Where exposure monitoring reveals an exposure level above the
action level for an OSHA regulated substance for which there are
exposure monitoring and medical surveillance requirements, and/or,
iii. Whenever an event takes place in the laboratory such as a spill,
leak, explosion or other occurrence resulting in the likelihood
of a hazardous exposure the employee will be provided an
opportunity for medical consultation for the purpose of
determining the need for medical examination.
These medical consultations and examinations shall be provided without
cost to the employees, without loss of pay and at a reasonable time and
place.
These medical consultations and examinations shall be administered by or
under the direct supervision of a licensed physician.
Appendix A
List of some highly toxic substances and/or carcinogens, which may be
encountered in JCU labs.
Substance
TLV-TWA* (ppm) or ceiling*(C)
Hydrofluoric acid
3 (C)
Sodium azide
0.11 (C)
1,1,2,2-Tetrachloroethane (skin)
1
Thionyl chloride
1 (C)
o-Toluidine (skin)
2, A2*
p-Toluidine (skin)
2, A2
Vinyl bromide
5, A2
Strychnine sulfate
0.02
Uranium(natural)
0.02
Vanadium pentoxide (dust)
0.05
Zirconium compounds
1
Antimony (and compounds)
0.1
Arsenic (and compounds)
0.1
Barium (and compounds)
0.1
Cadmium (dusts and salts)
0.01
Chromium (VI) compounds
0.02
Hydrazine (skin)
0.1,A2
Lead (dusts)
0.02
Mercury (vapor)
0.005
Phosphorus
0.1
Cyanides (skin)
5
Selenium (and compounds)
0.1
Anisidine(o-,p-isomers)(skin)
0.1
Benzidine (skin)
A1
Benzoquinone
0.1
Biphenyl
0.2
Boron trifluoride
C1
Bromine
0.1
1,1,-Dichloro-1-nitroethane
2
Dicyclopentadiene
5
Dimethyl sulfate (skin)
0.1,A2
Dinitrobenzene(all isomers)(skin)
0.15
Ethylene chlorohydrin (skin)
C1
Ethylene oxide
1, A2
Hexamethylphosphoramide (skin)
A2
Hydrazine (skin)
0.1, A2
Hydrogen sulfide
10
Iodine
C 0.1
Iron pentacarbonyl
0.1
Maleic anhydride
0.25
N-Methylaniline (skin)
0.5
2-Naphthylamine
A1
Nitric oxide
25
Nitrogen dioxide
3
2-Nitropropane
10, A2
Pentachlorophenol (skin)
0.1
Phenylhydrazine (skin)
5, A2
Platinum (soluble salts)
0.001
Rhodium (soluble salts)
0.005
*TLV-TWA: Threshold Limit Value-Time-Weighted Average
*C: Ceiling
*A1: Confirmed Human Carcinogen
*A2: Suspected Human Carcinogen
Appendix B
Chemical Hygiene Permit
Execution of the activity for which this permit is requested shall be
carried out in full compliance with the procedures described in the
Chemical Hygiene Plan. The permit is issued on the understanding that
safety will be the first consideration in setting up and conducting said
activity.
Name: Department:
Employee ID no.: Supervisor:
Activity for which permit is requested:
Approval of supervisor:
Approval of Chemical Hygiene Officer:
Approval of Departmental Chairperson:
Return to Central Scientific Stores
Revised: July 1, 2002