Oxygen is an essential gas, as demonstrated in the ongoing pandemic, where the demand for oxygen tanks has been very high. Oxygen occurs naturally in the air, but that is not the purest form. It is combined with other gases like carbon dioxide, nitrogen, innate games, and water vapor. This can cause a challenge when pure oxygen is required, as that will require a unique method to separate all these gases from oxygen. This is where an oxygen concentrator comes in.
What is an Oxygen Concentrator?
One of the side effects of COVID-19 has been oxygen deprivation due to extensive damage to the lungs. If you step into any hospital right now, you will be met with rows of unconscious patients on their beds with ventilators and oxygen tanks beside their beds. These tanks depend on oxygen concentrators to supply pure oxygen to the patients in the safest way.
For the oxygen to be separated from other gasses to make it pure to that level, you will need the help of oxygen zeolite filters that are created for working with oxygen concentrators. These filters isolate the gasses from each other, eliminating nitrogen, carbon dioxide, and water vapor to leave behind clean oxygen for medical use.
Why Oxygen Zeolite Molecular Sieves are Preferred for Oxygen Concentrators
There are many options that can be used in place of zeolite molecular sieves to clean the air off the impurities to leave behind pure oxygen. But oxygen zeolite is preferred due to the following reasons.
They can be used in fine form, increasing their efficiency when it comes to absorbing gas molecules in enlarged amounts. This makes them the best option when running a large-scale operation.
They can be regenerated repeatedly when they beat their saturation limit. This makes them cost-effective as they can be reused for so long without compromising the quality of the consequent oxygen.
They can function in extreme conditions of high temperature and pressure without inducing any side effects. Most other options begin to produce other gases when subjected to high temperatures, contaminating the oxygen.
They are highly porous, making it easy for them to absorb all the other gases. This comes in very handy when dealing with nitrogen, as that’s the most abundant gas that requires good adsorption.
They can be used on materials other than gases. Zeolite is versatile enough for ethanol dehydration and the purification of hydrogen sulfide, among other critical industrial applications used in making essential products.
Zeolites can accurately determine and discriminate the various gas molecules based on their sizes. This is one of the features that make oxygen zeolite molecular sieves a very reliable option for large-scale manufacturers. This decreases the work that would have been needed to keep separating gases through a costly and energy-consuming process.
Speaking of energy, zeolite molecular sieves are very cost-efficient as they don’t need much energy to manage their work sufficiently. This makes them an affordable option for beginners and large-scale gas generators who are dealing with large gas volumes.