A rebreather is a closed-circuit breathing apparatus that absorbs the carbon dioxide of a user's exhaled breath to permit the rebreathing (recycling) of the substantially-unused oxygen content of each breath. Fresh oxygen is added to replenish the amount metabolised by the user. This differs from open-circuit breathing apparatus, such as:
- the oxygen enrichment systems primarily used by patients and by high altitude mountaineers, in which the user breathes ambient air which is enriched by a small amount (2-5 l/min) of pure oxygen,
- open circuit breathing apparatus used by firefighters and scuba divers, which supplies fresh gas for each breath, which is then discharged into the environment.
A fit person working hard may ventilate at a rate of 100 l/min but will only metabolise a maximum of 6l/min of oxygen (Sleeping requires ½ to 1 l/min). A high ventilation rate is usually necessary to eliminate the metabolic product carbon dioxide (CO2). The breathing reflex is triggered by CO2 concentration in the blood, not by the oxygen concentration, therefore even a small buildup of CO2 in the inhaled gas quickly becomes intolerable; if a person tries to rebreathe their exhaled breathing gas, they will quickly feel an acute sense of suffocation, therefore rebreathers must absorb the CO2, and add the small amount of oxygen used to maintain the required concentration of oxygen.
Rebreather technology is used in many environments:
- Underwater – where it is variously known as "closed circuit scuba", "closed circuit rebreather" (CCR), "semi-closed scuba", "semi-closed rebreather" (SCR), "closed circuit underwater breathing apparatus" (CCUBA - a military term), or just "rebreather", as opposed to "open circuit scuba" where the diver exhales breathing gas into the surrounding water.
- Mine rescue and in industry – where poisonous gases may be present or oxygen may be absent.
- Crewed spacecraft and space suits – outer space is, effectively, a vacuum with no oxygen to support life.
- Hospital anaesthesia breathing systems – to supply controlled concentrations of anaesthetic gases to patients without contaminating the air that the staff breathe.
- Himalayan mountaineering. Both chemical and compressed oxygen has been used in experimental closed-circuit oxygen systems—the first on Mt. Everest in 1938. A high rate of system failures due to extreme cold has not been solved. Breathing pure oxygen results in an elevated partial pressure of oxygen in the blood. A climber breathing pure oxygen at the summit of Mt. Everest has a greater oxygen partial pressure than breathing air at sea level. This results in being able to exert greater physical effort at altitude.
- Submarines, underwater habitats and saturation diving systems use a scrubber system working on the same principles as a rebreather.
- Surface supplied diving equipment may incorporate rebreather technology either as a gas reclaim system, where the surface supplied breathing gas is returned and scrubbed at the surface, or as a self-contained diver bailout system.
Read more about Rebreather: Function, History of Rebreathers, Disadvantages of Rebreather Diving, Sport Diving Rebreather Technology Innovations