System usable in nuclear environment for providing breathing gas

What is claimed is: 1. A system structured for use in conjunction with an interior region of a nuclear environment, the interior region being at least partially enclosed, the system comprising: a reservoir having stored therein breathable gas whose stored condition is at least one of at a temperature less than the ambient temperature at the exterior of the reservoir and at a pressure greater than the ambient pressure at the exterior of the reservoir, the reservoir being structured to output a stream of the breathable gas responsive to a command; a control apparatus connected with the reservoir and structured to provide the command to the reservoir in a predetermined situation; a deployment system that is structured to receive the stream, the deployment system comprising a generation apparatus comprising a turbine and an electrical generator that are mechanically connected together, the turbine being in fluid communication with the reservoir and being structured to receive therethrough at least a portion of the stream and being, operable therefrom to cause the electrical generator to generate electrical power; wherein the deployment system further comprises a delivery system having an outlet that is in fluid communication with the interior region, the outlet being in fluid communication with the turbine and being situated downstream of the turbine, the outlet being, structured to deliver to the interior region at least a portion of the stream to provide breathable gas to the interior region; and wherein the deployment system further comprises a bypass leg, the bypass leg comprising a valve and a fluid passage, the valve being in fluid communication with the turbine and being situated between the turbine and the reservoir, fluid passage being in fluid communication between the valve and the outlet, the valve being structured to operate responsive to a number of instructions received from the control apparatus to divide the stream responsive to the number of instructions between the fluid passage and the generation apparatus. 2. The system of claim 1 wherein the deployment system further comprises a heat exchanger comprising a number of flow channels that are in fluid communication with the reservoir and that are situated in heat exchange relation with the interior region, the number of flow channels being structured to receive therethrough at least a portion of the stream and to transfer to it heat from within the interior region, the deployment system further comprising another valve that is in fluid communication with the turbine and the fluid passage, the another valve being situated downstream of the turbine and being structured to operate responsive to a number of other instructions received from the control apparatus, the another valve being structured to receive from the turbine and the fluid passage the stream and to divide it responsive to the number of other instructions between the outlet and the heat exchanger. 3. A system structured for use in conjunction with an interior region of a nuclear environment, the interior region being at least partially enclosed, the system comprising: a reservoir having stored therein breathable gas whose stored condition is at least one of at a temperature less than the ambient temperature at the exterior of the reservoir and at a pressure greater than the ambient pressure at the exterior of the reservoir, the reservoir being structured to output a stream of the breathable gas responsive to a command a control apparatus connected with the reservoir and structured to provide the command to the reservoir in a predetermined situation; a deployment system that is structured to receive the stream, the deployment system comprising at least one of: a heat exchanger comprising a number of flow channels that are in fluid communication with the reservoir and that are situated in heat exchange relation with the interior region, the number of flow channels being structured to receive therethrough at least a portion of the stream and, to transfer to it heat from within the interior region, and a generation apparatus comprising a turbine and an electrical generator that are mechanically connected together, the turbine being in fluid communication with the reservoir and being structured to receive therethrough at least a portion of the stream and being operable therefrom to cause the electrical generator to generate electrical power, and wherein the control apparatus comprises an equipment set, and wherein at least a portion of the electrical power is generated in order to operate at least a portion of the equipment set. 4. The system of claim 3 wherein the control apparatus comprises a battery bank, and wherein at least a portion of the electrical power is supplied to the battery bank to charge at least a portion of the battery bank. 5. The system of claim 4 wherein the battery bank is at least partially situated within another interior region of the nuclear environment, the another interior region being at least partially enclosed, and wherein the deployment system further comprises an ambient evaporator that is in heat exchange relation with the atmosphere inside the another interior region, the ambient evaporator being structured to receive as an input from the reservoir the stream in a first condition and being further structured to provide as an output the stream in a second condition, the stream in the second condition being one having relatively less liquid content and relatively more gaseous content than the first condition. 6. The system of claim 5 wherein the deployment system further comprises a pump that is in fluid communication with the reservoir and is structured to increase the pressure of the stream provided to turbine via the ambient evaporator. 7. The system of claim 3 wherein the equipment set is at east partially situated within another interior region of the nuclear environment, the another interior region being at least partially enclosed, and wherein the deployment system further comprises an ambient evaporator that is in heat exchange relation with the atmosphere inside the another interior region, the ambient evaporator being structured to receive as an input from the reservoir the stream in a first condition and being further structured to provide as an output the stream in a second condition, the stream in the second condition being one having relatively less liquid content and relatively more gaseous content than the first condition. 8. The system of claim 7 wherein the deployment system further comprises a pump that is in fluid communication with the reservoir and is structured to increase the pressure of the stream provided to the ambient evaporator. 9. The system of claim 3 wherein the deployment system further comprises a delivery system having an outlet that is in fluid communication with the interior region, the outlet being in fluid communication with the reservoir and being structured to deliver to the interior region as an output at least a portion of the stream to provide breathable gas to the interior region. 10. The system of claim 9 wherein the outlet is an eductor that is structured to recirculate the atmosphere within the interior region by providing as at least a portion of the output at least a portion of the atmosphere that is situated within the interior region, and wherein the deployment system further comprises a filter apparatus that is structure to receive the output and to filter contaminants therefrom before discharging the output into the interior region.