💾 Archived View for gemini.spam.works › mirrors › textfiles › anarchy › lab-safe.txt captured on 2020-10-31 at 20:37:56.
-=-=-=-=-=-=-
Date: 31 Oct 93 21:27:17 GMT The following is a quote (quite long) from PATR 2700 (The Encyclopedia of Explosives and Related Items), on lab safety. All typos that may be present are mine - not in the original text. Part 1 of 2 parts _______________________________________________________________________ LABORATORY SAFETY We shall consider here a lab scale of operation to be one which deals with hazardous materials in quantities less than 1 kg. The damage potential is therefore not a great one in respect to structures, but it will be appreciable for the exposed personnel. The hazard arises from the (presumed) unfamilarity with developmental formaulation and compounds as well as from the handling of hazardous chemicals as these would be found in any laboratory operation, and which is due to the ignition of the formulation by static discharge or friction,(for some reason, they fail to mention impact here - bill) producing a fireball and flying fragments. Death and injury are caused in a large majority of instances by burns (Ref 9), fragments impact and lung damage. Often, the explosion obliterates the information which could have told of the causes. In these instances the very costly method of replicating the test conditions must be resorted to until the reasons for the accident are understood and the hazardous condition is corrected(Ref 17). Often laboratory accidents go unreported simply because serious damage was limited to the test facilities. We must therefore assume that hazardous laboratory conditions are, in fact, common, and that continued vigilance by the worker himself coupled with unrelenting surveillance will remain to be the best preventative. Because of the multiplicity of the causes for accidents, a discussion of lab safety practices must necessarily contain a list of "do's" and "dont's". DO NOT WORK ALONE Experimental or hazardous work should only be performed when two persons are present, although each person shuld have a separate work area assigned in order to avoid the danger of both being injured by the same accident. DO NOT SMOKE Quite properly, the prohibition of matches and open flames is a universal one in explosives handling labs. Most facilities have separate rest areas for the personnel which feature oversized cigarette lighters which discourage their being pocketed. Moreover, smoking should not be permitted when personnel is wearing protective clothing which is contaminated with flammable dust. USE SAFETY SHIELDS On an industrial scale, operations are commonly carried out by remote control(Ref 10) and the considerations of quantity-distance(Ref 48) and barrier design(Refs 13 & 75) apply. On a lab scale, remote weighing, mixing and pressing are not practical, and the protection of the personnel must take the form of shielding for eyes, face and hands, as well as thru protection for the hair and the choice of suitable clothing. H.Ellern(Ref 6) remarks on the fact that self-interest is not sufficient motivation for experienced workers to accept the requisite encumberances of safety glasses, gloves and safety shields and that, therefore, no choice must be given to the individual regarding this matter. Complete eye shields, while desireable, are often foregone in order to make the minimum protection of ordinary safety glasses enforceable. Rubber or plastic gloves are recommended for work with acidic or caustic reagents, but these must not be worn when handling flammable materials because they melt and stick to the damaged skin. Ellern(Ref 6) prefers for pyrotechnic work suede leather gloves which must be washed after use to prevent the impregnation of flammable or toxic matter. These are easily cleaned in lukewarm water while on one's hands. A rinse after the final soaping is omitted in order to keep the gloves flexible after drying. This author favors face shields when handling hazardous liquids, and always a suitable confinement for expansive hair styles. Stationary shields are preferred when work is performed while seated at a work bench or when the equipment is situated in a hood. Full length shields and forced ventilation are a necessity when failure of the test might cause flying debris, a fireball or sprayed liquids. Safety showers are a necessity while safety blankets are of questionable value. BE CONSCIOUS OF FIRE HAZARDS This areticle is not the appropriate place to discuss fire fighting except to remind the reader that for certain materials special fire fighting agents must be provided. Water an aqueous cupric sulfate solutions are recommended for phosphorus fires. Reactive metals must not be mixed with chlorinated hydrocarbons, instead hydrocarbons should be used for storage and degreasing. Special carbonaceous powders are marketed for smothering burning alkali metals. Propellant and explosives fires can be deluged with water, provided always that the material is not confined. GROUND YOUR FACILITIES To minimize the risk of electrostatic discharge, materials, personnel and facilities should be grounded. The source of the static charge is often the packing material unless special precautions are taken in its selection, glass bottles and jars as well as pplyethylene containers are to be avoided for the pouring and shaking of dielectric liquids and powders. Pointed spatulas, particularly when these are used to scrape or dislodge dry components, are frequently found to be the cause of mishaps. Some powdered materials are best handled when moistened with eater or alcohol (except for certain metal powders, see section on Hazardous Compounds and Systems). Work tables and floors should be covered with a grounded conductor of which a rubber based formulation (Velostat) is preferred over the use of sheet metal. WEAR PROTECTIVE GARMENTS. Personnel should wear shoes with conductive soles and be grounded with the appropriate wrist and ankle straps. In an emergency, a grounded alligator clip fastened to a metallic watch band may be substituted. As a further precaution, materials should, where possible, be stored in metallic or conductive rubber containers in metal cabinets. Nylon garments should not be worn in view of their tendency to accumulate static charges. Fireproof metallized fabrics are on the market but these induce clumsiness and are uncomfortable so that they tend to be avoided. Cotton remains the best material, especially if fireproofed. Ellern(Ref ) recommends wool as a fabric. Polyesters have the nasty tendency to melt when hot, causing them to adhere to burnt skin. Protective garments amy become impregnated with flammable materials and regular laundering should be part of the safety routine. PRACTICE HUMIDITY CONTROL This author does not favor the use of static charge meters because their use is subject to operator diligence. It is a safer procedure to avoid the conditions which promote static charge accumulation as a matter of routine. Low ambient humidity is the chief contributing factor in the accumulation of hazardous static charges. In many desert areas (which seem to be favorites for ordnance work), the daytime ambient humidity is below 20% and in temperate regins, winter-time air, and indoor air, has likewise a low humidity. For this reason, also, air conditioned air, in the absence of artifical humidification, should be strictly controlled. In order to mantain a relative safe humidity above 50% RH, the use of evaporative coolers is helpful in desert environments. The matter of humidy control on pyrotechnic processing plants was recently considered by Avrami et al(Refs 55 & 56). MISCELLANEOUS LABORATORY HAZARDS. Advance planning for the possibility of an accident will greatly minimize the consequences. A common hazard is found when a bench scale operation is scaled up when this scale-up occurs in an overutilized laboratory area. Solvents in small and large quantities may be found in the immediate vicinity and batches of oxidizers, explosives and similar hazardous ingredients may be present where they may be exposed to ignition by one or more mechanisms. Often other personnel are present within the structure not knowing of the potentially hazardous operations which are conducted in their immediate vicinity. Exits and walk-ways may be blocked by materials, equipment or personnel in transit. While there is no safe explosive, propellant or pyrotechnic material, familiarity does breed complacency. We are reminded of a recent explosion of a Black Powder replica plant (Ref 80) (I would guess this what the Pyrodex plant explosion - bill) which resulted in the loss of life and the destruction of the plant. Nevertheless, Title XI, Public Law 91-452 permits the individual antique firearms fancier to store without a license up too 50 pounds (23 kg) of black powder in his home or car. __________________________________________________________________________ Part 2 to follow. Bill -------------- From: billn@hpcvaac.cv.hp.com (bill nelson) Date: 31 Oct 93 22:03:03 GMT This is the continuation of the quote from PATR 2700. Part 2 of 2. ____________________________________________________________ MATERIAL HANDLING HAZARDS Certain materials are a special source of hazard and their handling should be reviewed periodically. Hydrocarbon solvents, their flammability not withstanding, are the only acceptable degreasing agents for alkali metals which are known to react explosively with chlorinated hydrocarbons such as carbon tetrachloride. This special care in the selection of wetting agents should be exercised when ball milling operations are undertaken. Most oxidizers are hazardous only when mixed with fuel. Mixtures of chlorates with carbonaceous matter deserve special caution because the gaseous reaction products coupled with the exothermic decomposition of chlorates cause a particularly rapid rate of flame propagation. A similar measure of care is deserved by monopropellants such as nitrate esters, hydrazine and organic nitro compounds. Mixtures of ammonium compounds with chlorates may undergo an exchange reaction to form ammonium chlorate which is know to explode at moderate temperaturs. No mixtures of chlorates and sulfur should be prepared either wet or dry unless Na bicarbonate is added as a phlegmatizer. Red phosphorus and chlorate mixtures, being the most sensitive of all pyrotechnic systems, should only be mixed after both components are thoroughly wetted with water. (Ref 6 p 51). (Note: this is called a Death Mix by the pyrotechnics industry. The mix has been reported to explode, even when wet. - bill) Water must never be used to blend mixtures containing zinc, aluminum or magnesium, nor should it be used with titanium or zirconium powder unless water is in at least twentyfold excess by volume. Wet slurries, formed by settled zirconium, are particularly dangerous if they are "dug out" without excess water. Water wetted metal powders have explosive properties when initiated with a detonator(ref 30). Ammonium nitrate (AN) is sensitized by carbonaceous matter and by metal powders. Classic is the Texas City explosion of 1947 in which a 1% wax anticaking coating caused the fertilizer grade AN to detonate when it was ignited (Ref 14). Today, diatomaceous earth or a similar inert material is used as an anticaking material. (Note - there is still argument over the cause of the TC blast. A number of authorities feel that the wax primarily acted as a fuel, which provide the heat to cause decomposition of the AN. The detonation of these gases, under the relatively high pressures and temperatures present, initiated the detonation of the AN mass. - Bill) The danger of dust explosions is ever present when fuels are present in finely divided form. Of particular concern is the handling of zirconium powder which, when free of hydride, is pyrophoric in air. Wet zirconium powder, when dried in bacuo, may ignite when again exposed to air. Some of the principal recurring explosions take place in Black Powder milss, and even newly developed continuous processed do not seem to be immune to this problem (ref 66). TOXIC HAZARDS The explosives and pyrotechnics industries have an abundance of toxicological hazards which are becoming to an increasing extent identified. Isocyanate curing agents can cause serious allergenic reactions in sensitive individuals. Notrate esters cause severe headaches in low concentrations, although personnel have been known to become addicted to these vapors causing severe withdrawal symptoms when they are denied access to them (ref 25). Organic dyes and chromic oxides as used in pyrotechnic smokes and signals, as well as in gasless reaction mixtures, are rightly suspected of being carcinogenic. Metal chlorides, found in combustion products, are known to cause pulmonary edema upon hydrolysis in the lung tissue. Heavy metal ions of barium and lead can bring on chronic impairment of liver and kidney functions. Toxic hazards never seem as acute as other hazards in the ordnace industries, and the prevailing habits of cleanliness and orderliness go a long way toward their amelioration. The current emphasis on the maintenance of environmental standards have placed additional requirements on the control of effluent gas and liquid process streams. The care now being exercised is evidenced by new analytical techniques for the detection of trace contaminants ... PREPARE A WORK PLAN Lastly, and perhaps most importantly, should be mentioned the advisability of preparing a work plan prior to the commencement of any hazardous activity in which the objectives and the step-by-step procedures are clearly described. In this manner the safety practices of inexperienced personnel can be supervised, and if an accident should occur, the procedure can be replicated with a minimum of uncertainty. ___________________________________________________________ Yet to come - Evaluation of new explosives and explosive materials.