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The substances referred to in these recommendations are nitrogen, air, and helium.
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General Safety Rules
Cryogenic liquids, even when kept in insulated storage vessels (dewars), remain at a constant temperature at their respective boiling points and will gradually evaporate. The very large increase in volume accompanying this vaporization is approximately 700:1 for helium and nitrogen and therefore:
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In the event of a large spillage operate the fire alarm and evacuate the area.
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Health Hazards
Asphyxia of varying severity will occur if the magnet room is not properly ventilated. (Helium can displace air from the top of a room and cold nitrogen can displace air from lower levels).
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Exposed or insufficiently protected parts of the body coming into contact with uninsulated venting pipes or vessels (see ventilation section) will stick fast and the flesh will be torn if removed.FIRST AID
First Aid
If any of the cryogenic liquids come into contact with eyes or skin, immediately flood the affected area with large quantities of cold or lukewarm water and then apply cold compresses. NEVER use hot water or dry heat. MEDICAL ADVICE SHOULD BE SOUGHT IMMEDIATELY.
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Protective Clothing
Protective clothing must be worn mainly to avoid cold burns and dry leather or PVC gloves must be worn when handling or working with cryogenic liquids. Gloves must be loose fitting so that they can be removed easily in case of liquid spillage. Eyes must be protected by goggles. Do not wear any metallic objects (e.g. jewelry) on those parts of the body where they may come into contact with the liquid.
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Handling
Cryogenic liquids must be handled and stored in well ventilated areas.
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Use only metal tubing connected by flexible metal hose for transferring liquid nitrogen. For the coupling DO NOT use rubber tube, silicon rubber tube (including hospital grade tube - this explodes!), or plastic tubing e.g. garden hose and including reinforced tubes e.g. for air lines - this shatters unexpectedly and may cause injury to personnel. It should be noted that polythene and nylon lines are sometimes used, however, this should not be taken as an implied recommendation, all lines should be tested in safe circumstances or used only after the manufacturer's recommendation.
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Equipment
Only use containers specifically designed for use with particular cryogens and constructed of non-magnetic materials.
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The weight of the system is approximately 1,000 kg. Appropriate lifting gear must be used to move the cryostat.
This system, when energized to full field has a considerable stray field, ex-tending over many meters, and the system stored energy is approximately 0.5 MJ. It is therefore VITAL that the safety section is read by ALL personnel coming near the system.
Liquid Nitrogen
Good ventilation is essential.
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Rooms in which cryogenic liquids are being handled should be designated no smoking areas. While nitrogen and helium do not support combustion, their extreme cold can cause oxygen from the air to condense on cold surfaces and may increase the oxygen concentration locally. There is a particular fire danger if the cold surfaces are covered with oil or grease which is itself combustible.
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Liquid Helium
Liquid helium is the coldest of all cryogenic liquids. It will therefore condense and solidify any other gas (air) coming into contact with it, with the consequent danger that pipes and vents may become blocked.
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Ventilation of Exhaust Gases
Gaseous nitrogen and helium exhausted from the cryostat will displace oxygen and if not properly ventilated, the possibility of asphyxiation exists.
Cryogenic substances in liquid, or vapor form, or as low temperature gases, produce effects on the skin similar to burns (cold burns).
Exposed or insufficiently protected parts of the body coming into contact with uninsulated venting pipes or vessels will stick fast and the flesh may be torn if removed.
Exhaust systems are required in order to vent to atmosphere any discharge from the system cryostat as described below.
The static helium evaporation exits from the turret via a non-return valve. The valve prevents ambient air leaking back into the cryostat. The outlet from this valve should be vented out of the room to atmosphere or, if required, to a helium recovery system. In the event of a quench, the evaporated helium will be exhausted from the manifold via the pressure relief valve(s). The amount of gas is dependent on the type of system, but for a 500MHz NMR magnet quenching with 100% helium, the volume of gas at room temperature will be approximately 50,000 liters. If the system is located in a small room then a system should be provided that is capable of exhausting this gas to the atmosphere or to a recovery system.
The static nitrogen evaporation will exit from one (or two) of the nitrogen ports. This gas should be vented out of the room to atmosphere.
Environmental Safety
It is the responsibility of the user to ensure that all equipment, services, data links, or personnel passing through the affected space are adequately protected and that access to the area is controlled. Access doors leading into the affected areas must be capable of being secured against unauthorized entry and fitted with warning signs. It is also recommended that local barriers be erected around the magnet and be fitted with warning signs. Care must be taken to advise personnel who have access (in particular security or cleaning staff who often have their own keys) of all the risks associated with magnetic fields and systems operating with cryogens.