| Over the weekend I sent you an email all about how the "healthy"foods you're eating can end up acting like a bee sting in your body. Increasing inflammation and that puffy, swollen look : Well... About 6,000 people checked it out and we had a bunch of emails from people saying that it was the best analogy the ever heard! After all... If you think you're eating relatively healthy but you're still bloated and can't seem to lose fat, then this probably has to do with your body being inflamed like it's gotten stung by a bee. It all makes sense in the documentary I sent out this last weekend. Which is why I'm emailing you now... If you haven't checked it out yet, make sure you do, ok. [SIGN OFF] P.S. Tomorrow I will be sharing a personal story that I bet most (if not all) of you can relate to. |
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k4e2 Underwater use[edit] As well as t k4e2 ransporting divers, a diving chambe k4e2 r carries tools and 4e2 equipment, high 4e2 pressure storage 4e2 cylinders for e 4e2 mergency 4e2 reathing gas supply, and communications and emergency equipment. It provides a temporary dry air environment during extended dives for rest, eating meals, carrying out tasks which can't be done underwater, and for emergencies. Diving chambers also act as an underwater base for surface supplied diving operations, with the divers' umbilicals (air supply, etc.) attached to the diving chamber rather than to the diving support vessel. 4e2 D k4e2 iving bells[edit] D k4e2 iving bells and k4e2 open diving chambers of the same 4e2 principle 4e2 were more common in the past owing to their 4e2 simplicity, since they do not 4e2 necessarily need to mo 4e2 nitor, control and mechanically adjust the internal pressure. Secondly since internal air pressure and external water pressure on the bell wall are almost balanced, the chamber does not have to be as strong as a pressurised diving chamber (dry bell). The air inside an open bell is at the same pressure as the water at the air-water interface surface. This pressure is constant and the pressure difference on the bell shell can be higher than the external pressure to the extent of the height of the air space in the bell. A wet diving bell or open diving chamber must be raised slowly to the 4e2 urface with d 4e2 ecompression stops appropriate to the dive pr 4e2 ofile so that the 4e2 occupants can avoid 4e2 decompression sickness. This may take hours, and so limits its use. k4e2 Submersible k4e2 hyperbaric chambers[edit] k4e2 k4e2 Submersible k4e2 hyperbaric chambers can be brought to the su 4e2 rface without delay to allow divers to decompress since they can ma 4e2 intain the same 4e2 pressure at which the divers were working. The divers can stay in the chamber on the support vessel to decompress. This flexibility makes them safer to use and more useful in an accident or emergency, including problems affecting the dive support vessel, such as sudden bad weather. They are used to support saturation diving for which the decompression times are very long. A diving k4e2 chamber based on a pressure vessel is more 4e2 expensive to construct sinc 4e2 e it has to withstand very high pressure di 4e2 fferentials. These may be 4e2 both crushing pressures when the chamber is lowered into the sea and the internal pressure is kept less than ambient water pressure, or it may be an outwards pressure when it is out of the water and its internal pressure is set the same as water pressure at a certain depth. k4e2 H k4e2 yperbaric c k4e2 hambers also require more 4e2 sophisticated systems to set and control internal gas pressure. However modern 4e2 manufacturing 4e2 techniques and control 4e2 systems have reduced the cost and this type of diving chamber is now more common than the older dive bell type. 4e2 4e2 Rescue bells are specialized diving chambers or 4e2 submersibles able to retrieve 4e2 divers o 4e2 r occupants of diving 4e2 chambers or 4e2 underwater ha 4e2 bitats in an 4e2 emergency and to keep them under the required pressure. They have airlocks for underwater entry or to form a watertight seal with hatches on the target structure to effect a dry transfer of personnel. Rescuing occupants of submarines or submersibles with internal air pressure of one atmosphere requires being able to withstand the huge pressure differential to effect a dry transfer, and has the advantage of not requiring decompression measures on returning to the surface. Out of water use[edit] k4e2 Hyperbaric chambers are also used on land a 4e2 nd above the water 4e2 to k4e2 take surface supplied divers who have been bro k4e2 ught up from underwater through their 4e2 decompression stops 4e2 , either as surface d 4e2 ecompression or after transfer under pressure from a dry bell. (decompression chambers) to k4e2 train divers to adapt to hyperbaric cond 4e2 itions and decompression routines and test their 4e2 performance under pressure. 4e2 to k4e2 treat divers for decompression sickness (recompression chambers) to k4e2 treat people using raised oxygen pre k4e2 ssure in 4e2 hyperbaric oxygen therapy to treat people infected with gas gangrene and other conditions unrelated to diving[1] In k4e2 saturation diving life support systems in k4e2 scientific research requir k4e2 ing elevated gas pressures. H k4e2 yperbaric chambers designed only for use out of wat 4e2 er do not have t 4e2 o resist inward crushing f 4e2 orces, only outward expansion forces. Those for medi 4e2 cal applications typically only operate up to two or three atmospheres, while those for diving applications may have to go to six atmospheres and above. 4e2 k4e2 Lightweight portable h k4e2 yperbaric chambers which can be 4e2 lifted by helic 4e2 opter are used by co 4e2 mmercial diving oper 4e2 ators and rescue services t 4e2 o carry one or more divers requiring hospitalisation. 4e2 |
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