File:Hill 60 illowra battery port kembla.jpg|Inside the
Hill 60 Bunker, Port Kembla, New South Wales, Australia. One of many
bunkers south of Sydney File:Project-131-tunnel-door-9791.jpg|In a
Project 131 tunnel under the hills of
Hubei File:Objekt 17 5001 toegangsdeur 02.JPG|Object 17/5001 Prenden, Germany File:Harparskog Line Bunker 2.jpg|Bunker of the Harparskog Line in
Raseborg, Finland File:Used_Bunker_in_Singapore.jpg|Bunker in
Singapore File:Maginot line 1.jpg|The entrance to
Ouvrage Schoenenbourg along the
Maginot Line in France. File:Albania bunkers.jpg|
Bunkers in Albania File:German single person bunker.JPG|German single person bunker for reconnaissance personnel in the field File:Brandenburg_Kirchmoeser_bunker.jpg|Bunker of type Winkel in
Brandenburg an der Havel File:Possum_Park_Bunker_8a.jpeg|Munitions bunker at
Possum Park, Queensland, Australia. File:Gravel_Gertie_-_PANTEX_Plant_-_1981.jpg|
Gravel Gertie at the
Pantex nuclear weapons plant, Amarillo, Texas. File:Austrian bunker from I World War in West Ukraine.jpg|
Austrian bunker from World War I in
West Ukraine Blast protection Bunkers deflect the blast wave from nearby
explosions to prevent ear and internal injuries to people sheltering in the bunker. While frame buildings collapse from as little as of
overpressure, bunkers are regularly constructed to survive over . This substantially decreases the likelihood that a
bomb (other than a
bunker buster) can harm the structure. The basic plan is to provide a structure that is very strong in
physical compression. The most common purpose-built structure is a buried, steel
reinforced concrete vault or
arch. Most expedient blast shelters are civil engineering structures that contain large, buried tubes or pipes such as sewage or rapid transit tunnels. Improvised purpose-built blast shelters normally use earthen arches or vaults. To form these, a narrow, , flexible tent of thin wood is placed in a deep trench, and then covered with cloth or plastic, and then covered with of tamped earth. A large ground shock can move the walls of a bunker several centimeters in a few milliseconds. Bunkers designed for large ground shocks must have sprung internal buildings to protect inhabitants from the walls and floors.
Nuclear protection Nuclear bunkers must also cope with the underpressure that lasts for several seconds after the
shock wave passes, and block
radiation. Usually, these features are easy to provide. The overburden (
soil) and structure provide substantial radiation shielding, and the negative pressure is usually only of the overpressure.
General features , in the Netherlands. The doors must be at least as strong as the walls. The usual design is now starting to incorporate
vault doors. To reduce the weight, the door is normally constructed of steel, with a fitted steel lintel and frame. Very thick wood also serves and is more resistant to heat because it chars rather than melts. If the door is on the surface and will be exposed to the blast wave, the edge of the door is normally counter-sunk in the frame so that the blast wave or a reflection cannot lift the edge. A bunker should have two doors. Door shafts may double as ventilation shafts to reduce digging. In bunkers inhabited for prolonged periods, large amounts of
ventilation or
air conditioning must be provided in order to prevent ill effects of heat. In bunkers designed for war-time use, manually operated ventilators must be provided because supplies of electricity or gas are unreliable. One of the most efficient manual ventilator designs is the
Kearny Air Pump. Ventilation openings in a bunker must be protected by
blast valves. A blast valve is closed by a shock wave, but otherwise remains open. One form of expedient blast valve is worn flat rubber
tire treads nailed or bolted to frames strong enough to resist the maximum overpressure. ==Countermeasures==