The air that we breathe is 78% N2, 20.9% Oxygen and the remainder is Argon, CO2, Water vapor and other trace gases. Separating air has been done cryogenically for over a hundred years. The cryogenic process involves fractional condensation of the gases into their separate components. Oxygen Generation System
liquefies at -297F (-183C) whereas Nitrogen liquefies at -320F (-195C), so by maintaining air at -297F, all the oxygen will liquefy out of the mixture, then by holding the remaining gas at -320F, the nitrogen is separated as a liquid. The nitrogen liquid is then pumped into insulated trucks for delivery to the point of use. Needless to say, old technology is very energy intensive.
Nitrogen generation is a more modern means of separating air. There are two means of separating gases non cryogenically. One is with hollow fiber membranes and one is with pressure swing adsorption.
Hollow fiber membranes are very interesting fibers. They are extruded through a spinneret like many fibers are, but a stream of dry nitrogen fills and creates an inner annulus to make a fiber with a center bore, much like a drinking straw, hence the name hollow fiber. The outer surface of the fiber is non-porous, but permeable as its thickness is less than 40 nanometers. Compressed air travels down the center bore while oxygen permeates through the permeable membrane wall about 3-4 times as fast as nitrogen, so by passing compressed air through the hollow fiber, oxygen permeates and the nitrogen does not. Thus, by the time the air reaches the end of the fiber, most of the oxygen has been depleted. Bundle hundreds or thousands of fibers together and arrange them like a shell and tube heat exchanger and you can create a product that can handle thousands of cubic feet per hour.
Pressure swing adsorption (PSA) works much differently. A special material about the size of a grain of rice, called carbon molecular sieve (CMS), is able to hold on to adsorb oxygen under high pressure, then release it under low pressure. This sieve is poured into cylindrical towers. One tower operates to remove the oxygen under pressure, while the other tower is held at low pressure where the oxygen is released. Then, on a predetermined cycle, the towers switch so that the one that was at high pressure holding oxygen is re-generated at low pressure while the other tower takes on the job of capturing the oxygen under pressure. This cycle progresses back and forth for many years.
As a leader in the nitrogen generator industry, our company offer different styles of Nitrogen Generation System
and oxygen generators with standard systems and custom systems to meet your pressure, flow, and OEM needs.