| The
following general suggestions for safe storage of
chemicals in the laboratory should be implemented. |
| |
|
|
| |
• |
The
quantities of chemicals that are stored within a laboratory
should be minimized, as specified by NFPA 45 and OSHA.
Many authorities recommend that the NFPA guidelines
for maximum quantities and sizes of containers should
be reduced to one-half or even one-third of the recommended
values. |
| |
|
|
| |
• |
Bulk
quantities of chemicals (i.e., larger than one-gallon)
must be stored in a separate storage area. Transfer
of flammable liquid from 5 gallon or larger metal
containers may not be done in the laboratory. |
| |
|
|
| |
• |
Chemicals
must be stored at an appropriate temperature and humidity
level. This can be especially problematic in hot,
humid climates. As a rule, chemicals should not be
stored near heat sources, such as steam pipes or laboratory
ovens. Chemicals should never be stored in direct
sunlight. |
| |
|
|
| |
• |
Chemicals should be dated when received and when opened.
If the chemical is one that degrades in quality or
becomes unsafe after prolonged storage, the shelf-life
expiration date should also be included. |
| |
|
|
| |
• |
Visual
inspection of the material and its container should
be conducted routinely. Indications for disposal include: |
| |
|
o |
cloudiness in liquids |
o |
material
changing color |
o |
evidence
of liquids in solids or solids in liquids |
o |
"puddling"
of material around outside of container |
o |
pressure build-up within bottle |
o |
obvious
deterioration of container |
|
| |
|
|
| |
• |
Chemicals should not be routinely stored on the benchtops.
In such locations they are unprotected from exposure
and participation in a fire situation and are also
more readily knocked over. Each chemical should have
a specific storage area and be returned there after
use. Large quantities of flammable materials should
not be stored in the laboratory. Only the amounts
needed should be kept on benchtops, the remainder
should be kept in flammable storage cabinets. |
| |
|
|
| |
• |
Laboratory shelves should have a raised lip along
the outer edge to prevent containers from falling.
Never allow the container to hang off the edge of
the shelf! Liquid or corrosive chemicals should never
be stored on shelves above eye-level. Glass containers
should not touch each other on the shelves. Secondary
containers or trays should be used for chemical storage
whenever possible to minimize the flow of material
should a spill or rupture occur. Round bottom flasks
should always be supported properly in cork rings
or by other means to keep them from tipping. |
| |
|
|
| |
• |
Adequate security must be provided so that unauthorized
personnel do not have access to hazardous materials. |
| |
|
|
| |
• |
Chemicals
must never be stored on the floor, not even temporarily! |
| |
|
|
| |
• |
Chemicals that are no longer to be used for research
purposes should be properly disposed of or given to
another research group that has a use for it. |
| |
|
|
| |
• |
Flammable materials must never be stored in domestic-type
refrigerators. Only explosion-proof or flammable material
refrigerators should be used for storage of these
chemicals within a laboratory environment. |
| |
|
|
| |
• |
All containers stored within the refrigerator should
be tightly capped to keep vapors from interacting
with each other and to alleviate "smell"
problems. Flasks with cork, rubber or glass stoppers
should be avoided because of the potential for leaking.
All containers stored in the refrigerator must be
properly labeled. |
| |
|
|
| |
• |
Inventory the materials in your refrigerator frequently
to avoid overcrowding with materials that have long
since been forgotten. Also make it a point to defrost
your refrigerator occasionally so that chemicals do
not become trapped in unique ice formations! |
| |
|
|
| |
• |
Before flammable materials are stored in a refrigerator,
it should be determined if keeping the material chilled
will serve any purpose. No benefit is derived from
refrigerating a chemical that has a flash point below
the temperature of the refrigerator. Never store peroxide
formers (i.e., ether) in a refrigerator! |
| |
|
|
| |
• |
Fume hoods should not be used as general storage areas
for chemicals. This may seriously impair the ventilating
capacity of the hood. |
| |
|
|
| |
• |
Gas cylinders must be securely strapped to a permanent
structure (wall, lab bench, etc.). When they are not
in use they should be capped off. |
| |
|
|
| |
• |
On termination, graduation or transfer of any laboratory
personnel, all hazardous materials must be properly
disposed of, or arrangements made to transfer them
to the laboratory supervisor. |
| |
| Segregation
Based on Hazard Classes |
| |
| In
addition to general safe storage practices, segregated
storage of incompatible materials is a must. As a
minimum, laboratories should separate chemicals according
to similar hazards, such as flammability, corrosivity,
sensitivity to water or air, and toxicity. The following
major categories of chemicals, each of which will
be discussed in greater detail, are strongly recommended: |
| |
• |
Flammables |
| |
• |
Oxidizers |
| |
• |
Corrosives |
| |
|
|
| |
• |
Highly Reactives |
| |
• |
Extreme
Toxics/Regulated Materials |
| |
• |
Low Hazard |
| |
|
| However,
problems may arise with a general segregation of chemicals.
Below, you will find a few of these potential problems. |
| |
|
| 1. |
The
actual identification of the hazards themselves.
Recent legislation has made this task somewhat easier
since all chemical manufacturers are now required
to list all hazards on outgoing chemical containers
and each chemical must be accompanied by a Material
Safety Data Sheet (MSDS). The chemical label thus
furnishes a quick method of determining whether the
material is a fire hazard, health hazard or reactivity
hazard. The MSDS furnishes more detailed information
regarding toxicity exposure levels, flashpoints, required
safety equipment and recommended procedures for spill
containment.
|
| |
2. |
Multiple
hazards for chemicals. Most chemicals have
multiple hazards and a decision must be made as to
which storage area would be most appropriate for each
specific chemical. First you have to determine your
priorities! |
| |
a.
|
When
establishing a storage scheme, the number one consideration
should be the flammability characteristics of the
material. If the material is flammable, it should
be stored in a flammable cabinet. |
| |
b.
|
If
the material will contribute significantly to a fire
(i.e., oxidizers), it should be isolated from the
flammables. If there were a fire in the lab and response
to the fire with water would exaggerate the situation,
isolate the water reactive material away from contact
with water. |
| |
c.
|
Next
look at the corrosivity of the material, and store
accordingly. |
| |
d.
|
Finally,
consider the toxicity of the material, with particular
attention paid to regulated materials. In some cases,
this may mean that certain chemicals will be isolated
within a storage area, for instance, a material that
is an extreme poison but is also flammable, should
be locked away in the flammable storage area to protect
it against accidental release. There will always be
some chemicals that will not fit neatly in one category
or another, but with careful consideration of the
hazards involved, most of these cases can be handled
in a reasonable fashion. For the safety of all personnel
and to protect the integrity of the facilities, hazardous
materials must be segregated. |
| |
|
|
Peroxide-Forming
Materials |
| |
|
| Peroxides
are very unstable and some chemicals that can form
them are commonly used in laboratories. This makes
peroxide-forming materials some of the most hazardous
substances found in a lab. Peroxide-forming materials
are chemicals that react with air, moisture, or impurities
to form peroxides. The tendency to form peroxides
by most of these materials is greatly increased by
evaporation or distillation. Organic peroxides are
extremely sensitive to shock, sparks, heat, friction,
impact, and light. Many peroxides formed from materials
used in laboratories are more shock sensitive than
TNT. Just the friction from unscrewing the cap of
a container of an ether that has peroxides in it can
provide enough energy to cause a severe explosion. |
| |
|
| Use
and Storage of Peroxide-Formers |
| |
|
|
|
Do
not open the chemical container if peroxide formation
is suspected. The act of opening the container could
be sufficient to cause a severe explosion. Visually
inspect liquid peroxide-forming materials for crystals
or unusual viscosity before opening. Pay special attention
to the area around the cap. Peroxides usually form
upon evaporation, so they will most likely be formed
on the threads under the cap. |
| |
|
|
| 2.
|
Date
all peroxide forming materials with the date received,
and the expected shelf life. Chemicals such as diisopropyl
ether, divinyl acetylene, sodium amide, and vinylidene
chloride should be discarded after three months. Chemicals
such as dioxane, diethyl ether, and tetrahydrofuran
should be submitted to Environmental Management Operations
(EMO) Waste Management Depart for disposal after one
year. |
| |
|
3. |
Store all peroxide-forming materials away from heat,
sunlight, and sources of ignition. Sunlight accelerates
the formation of peroxides. |
| |
|
4. |
Secure the lids and caps on these containers to discourage
the evaporation and concentration of these chemicals. |
| |
|
5. |
Never store peroxide-forming materials in glass containers
with screw cap lids or glass stoppers. Friction and
grinding must be avoided. Also, never store these
chemicals in a clear glass bottle where they would
be exposed to light. |
| |
|
6. |
Contamination of an ether by peroxides or hydroperoxides
can be detected simply by mixing the ether with 10%
(wt/wt) aqueous potassium iodide solution - a yellow
color change due to the oxidation of iodide to iodine
confirms the presence of peroxides. Small amounts
of peroxides can be removed from contaminated ethers
via distillation from lithium aluminum hydride (LiAlH-4-),
which both reduces the peroxide and removes contaminating
water and alcohols. However, if you suspect that peroxides
may be present, it would be wise to call the Environmental
Management Operations (EMO) Waste Management Department
at ANL for disposal. If you notice crystal formation
in the container or around the cap, do not attempt
to open or move the container. Call the ANL Waste
Handling Group for proper disposal. |
| |
|
| 7. |
Never
distill an ether unless it is known to be free of
peroxides. |
