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STANDARD PRACTICES FOR WORKING WITH FIBERGLASS
Fiberglass is one of the most useful manufactured products in industry, with numerous commercial applications. It is a man-made fiber used primarily in the production of insulating materials and for reinforcing plastics and composites. Various products ranging from home insulation materials to boats are composed of fiberglass. Its physical properties make it ideal for structural building materials because it is inert, lightweight, heat resistant and a very strong fiber. These same properties are also responsible for some of the hazards encountered in the workplace.
Depending on the size and dimensions of the fibers measured in the workplace, you will find different biological effects on humans. Smaller fibers, generally less than 3.5 microns in length, can be inhaled and deposited in the lung where they can accumulate and cause fibrotic changes, while larger fibers cause skin irritation due to mechanical action. It is both the inhalation and dermal hazards that give fiberglass a greater hazard potential than nuisance dust and require appropriate protective equipment to minimize exposure. The purpose of this paper is to review the potential hazards of working with fiberglass, assess the risk and provide a recommended best practice.
Hazards
Since there are numerous uses for fiberglass, one needs to identify the other hazards associated with the production of fiberglass products in order to determine and control the greater hazard. Generally, the principles involved are similar for most hazardous substances and basically involve following good industrial hygiene practices. Various trade organizations have developed and published their own specific guides and work practices and should be consulted for reference. For the purpose of this paper, fiberglass will be considered the primary hazard and the best practices will be limited to general principles.
As was mentioned before, small fiberglass fibers can be inhaled and therefore are an inhalation hazard, but the primary hazard associated with fiberglass is skin irritation. Respiratory protection devices are not needed for fiberglass exposures below the recommended environmental limit (ACGIH TWA 10mg/m3), but for situations where airborne concentrations may exceed the limits recommended, respirators approved by NIOSH may be used, but not as a substitute for feasible engineering controls.
The primary health effect and hazard associated with larger fiberglass fibers involve skin and eye irritation. Most skin problems arise from direct contact with fiberglass through handling rather than from airborne fibers or dust. Decisions on whether to wear gloves or other protective clothing will depend on the nature of the work as well as the nature of the materials involved. In general, wearing gloves and other items of protective clothing such as booties will prevent fiberglass from contacting exposed skin surfaces and street clothes worn underneath. Fiberglass can and does adhere to street clothes and shoes where it is retained in fabrics and bonded to shoes if adhesives are used in production processes to make fiberglass composites. If these street clothes and shoes are not removed and laundered at work, they are brought home contaminated with fiberglass which in turn will contaminate household family laundry.
Eye irritation is another hazard associated with working with fiberglass, particularly when installing fiberglass insulation materials overhead. Safety glasses or goggles will prevent contact with the eye and alleviate potential eye injuries. It should also be noted that in many applications and processes fiberglass is bound with adhesives and in plasticizers where it becomes rigid and sharp.
These sharp glass fibers then can act like a razor blade, causing cuts and lacerations, particularly when cutting fiberglass products or when removing them from molds.
Because of the diverse use of fiberglass in manufacturing operations, there is no one main occupational disease associated with working with fiberglass. Epidemiological studies have not determined that there is a substantial risk of lung injury resulting from the inhalation of small fiberglass fibers, even though fibrotic changes in lung tissue have been observed in some occupations working exclusively with the production of fiberglass. However, large fiberglass fibers can and do cause irritation to the skin and eye. The irritation is primarily due to the mechanical abrasion of fiberglass on wet sweaty exposed skin. Repeated exposures to the skin cause additional irritation, redness and itchiness. In some cases individuals develop tough skin as a result of continued exposure and become immune to irritation. Individuals who work intermittently with fiberglass tend to develop irritation repeatedly after each exposure. Therefore, these acute exposures that repeatedly cause irritation tend to be the major risk involved with handling fiberglass.
Standard Practices
The best practice to follow when working with fiberglass is to prevent and avoid skin contact. Inhalation of small fiberglass fibers is not a major concern if airborne fiber concentrations are below recommended environmental limits. Respirators should be worn if concentrations exceed this limit and if other airborne contaminants produced in the process exceed recommended exposure limits.
Protection from skin exposure is best achieved by wearing appropriate protective equipment such as gloves, suits and boots if necessary. A hazard assessment should be made in accordance with OSHA's personal protective equipment standard to determine the appropriate protective clothing and procedures to be followed. This would include wearing gloves, suits and booties that prevent skin exposure. These items of clothing should be worn over regular street clothes and disposed of or removed at the end of the work day to be laundered if they are going to be worn again the next day. Workers should have access to lockers and a shower and wash basin where they wash away fibers from contaminated body surfaces.
In general good industrial hygiene practices should be followed, such as utilizing engineering controls to reduce airborne exposures and good housekeeping to keep fiberglass contained in work areas. A separate lunchroom or area should be designated for eating and drinking. Eye glasses or goggles should be worn to prevent eye exposures, and an eye wash and safety shower should be readily accessible. Since cuts can occur from handling bonded fiberglass, first aid kits should also be readily available. Finally, waste bins or cans should be located in work areas to dispose of excess unused fiberglass.
LINTING CHARACTERISTICS OF Tyvek® vs. COTTON vs. PAPER DISPOSABLES
Test Procedure
Samples were precleaned, enclosed in a polyethylene envelope and flexed 500 cycles in a stress-flex tester. After flexing, materials were vacuumed and loose material was collected on a filter and counted.
| Test Results
| Tyvek®
| Cotton
| Scrim Reinforced
Paper Disposable |
| Fibers per sq. in. |
0.7 |
29 |
9 |
| Particles per sq. in. |
3.9 |
280 |
115 |
|
Conclusions
Tyvek® reduces particle generation vs. paper disposables 96% and vs. cotton: 99%
Tyvek® reduces fiber generation vs. paper disposables 92% and vs. cotton: 98%
DuPont Tyvek® Type 1422 provides excellent barrier to particulates.
Tyvek® proprietary nonwoven is a unique DuPont material that offers high strength and provides excellent barrier to many dry particulates including asbestos, lead dust, and radioactive dusts down to sub-micron size. Laboratory tests have shown Tyvek® to hold out >99 % of asbestos fibers.
| PARTICULATE HAZARD
| AVERAGE %
PENETRATION
|
| Dust particles (0.2-6 µ) |
< 0.6 |
| Asbestos (<1 µ) |
0.9 |
| Co 60 Colloid |
ND |
| Radioactive dust particles (0-80 µ) |
ND |
|
ND = none detected < = less than
DON'T SETTLE FOR A SUBSTITUTE. SPECIFY GARMENTS OF DUPONT Tyvek.
We believe this information is the best currently available. It is subject to revision as additional knowledge and experience are gained. DuPont makes no guarantee of results and assumes no obligation or liability in connection with this information. It is the user's responsibility to determine the level of toxicity and the proper personal protective equipment needed. The information set forth herein reflects laboratory performance of fabrics, not complete garments, under controlled conditions. It is intended for informational use by persons having the technical skill for evaluation under their specific end-use conditions at their own discretion and risk. Anyone intending to use this information should first verify that the garment selected is suitable for the intended use. Since conditions of use are outside our control, we make no warranties, express or implied, and assume no liability in connection with any use of this information. This information is not intended as a license to operate under or a recommendation to infringe any patent or technical information of DuPont or others covering any material or its use.
WARNINGS:
(1) Garments of Tyvek® spunbonded olefin are not flame resistant and should not be used around heat, flame, sparks, or in potentially flammable or explosive environments.
(2) Garments of Tyvek® spunbonded olefin should have slip resistant or antislip materials on the outer surface of boots, shoecovers, or other garment surfaces where slipping could occur.
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