Oxygen generators separate oxygen from air so that the gas can be fed into industrial processes in real-time or stored in pressure tanks. Oxygen

generators are used in dozens of industrial applications ranging from gold mining to aquaculture to life support.


    Normal ambient air is made up of 78% nitrogen, 21% oxygen and other trace gases like argon and CO2. In order to remove the nitrogen and trace gases an

oxygen generator is used.


    The smallest portable oxygen concentrator can be no larger than a

soda can, while industrial oxygen generators can be as large as a bus. However, all oxygen generators have the same purpose: to provide a safe supply of

concentrated oxygen gas.


    Businesses who need bulk oxygen often start by purchasing tanks from other companies who fill those tanks using an industrial oxygen generator. If the

need is large and ongoing, it may be cost-effective for the business to purchase their own oxygen generator and produce oxygen on site. While the up-front

cost of the machinery is significant, the cost per cubic foot of oxygen generated is 1/3 to 1/2 that of purchasing bulk oxygen, so over time the

oxygen concentrator can pay for itself.


    One example of this is hospitals that pipe oxygen into patient rooms. Instead of bottled oxygen, most hospitals have one or more industrial oxygen

generators in the building.


    Types of Oxygen Generators


    Pressure Swing Adsorption Oxygen Generator


    Pressure Swing Adsorption (PSA) is the most common method of producing oxygen at an industrial scale. PSA generators separate nitrogen from ambient

air inside a pressurized tank filled with Zeolite. Zeolite is a natural or man-made mineral that acts as a “molecular sieve.” It is this ability to “

sort” molecules by size that makes zeolite so useful. The larger nitrogen molecules are adsorbed by the sieve material while the smaller oxygen molecules

drift past and are collected. Pressure is then released, the nitrogen molecules are vented to the atmosphere, and the tank is pressurized again.


    Using PSA will result in 90-95% oxygenated gas. Further refinement can be achieved by repeating the process until over 99% “pure” oxygen is generated.


    As a side note, the PSA process can also be used to generate nitrogen by collecting the nitrogen molecules and venting the oxygen. PSA is also used

in the large-scale commercial synthesis of hydrogen used in oil refineries and in the production of ammonia for fertilizer.


    One special kind of oxygen generator is more commonly known as an oxygen concentrator which is used as an alternative to oxygen bottles for

home health care. While the up-front cost of the machine is more expensive than oxygen cylinders, they are safer than bottled oxygen and over time less

expensive than having oxygen tanks delivered to the home.


    Oxygen concentrators are normally sold through medical supply houses and can be purchased with a prescription from a physician.


   
        A nebulizer is a piece of medical equipment that a person with asthma or another respiratory condition can use to

administer medication directly and quickly to the lungs.
   


    A nebulizer turns liquid medicine into a very fine mist that a person can inhale through a face mask or mouthpiece. Taking medicine this way allows it to

go straight into the lungs and the respiratory system where it is needed.


   
        How to use a nebulizer
   


    Before a person starts taking medicine with a portable nebulizer, a doctor or nurse will

explain how the nebulizer works and answer any questions.


    If a person receives their nebulizer from a pharmacy or medical equipment company, someone there will explain how to use it.


    Each nebulizing machine operates a little differently. It is crucial to read the instructions for the particular device that the doctor has prescribed.


    In general, a nebulizer is very easy to use, with only a few basic steps:

            Wash the hands.
 
       
            Add the medicine to the medicine cup, according to the doctor’s prescription.

       
            Assemble the top piece, tubing, mask, and mouthpiece.
       
   
   
       
            Attach the tubing to the machine, according to the instructions.
   
       
            Turn the nebulizer on; they can be battery- or electrically powered.

            While using the nebulizer, hold the mouthpiece and medicine cup upright to help deliver all the medication.

   
       
            Take slow, deep breaths through the mouthpiece and inhale all the medicine.
       


    Please speak with the doctor or call the manufacturer with any questions or concerns about the device.


    Typically, a nebulizer and the medicine it uses require a prescription from a doctor or another healthcare provider.


    It is possible to purchase a nebulizer machine online without a prescription, though a doctor will probably still need to prescribe the

medication.


    However, some medication manufacturers require the use of a specific type of nebulizer with oximeter, so it

is always a good idea to double-check with the pharmacist or doctor before making a purchase.


    There are several types of medication that a person can use with a nebulizer:

       
            Bronchodilators: These are drugs that help open the airways and make breathing easier. Doctors often prescribe bronchodilators to people

with asthma, COPD, or other respiratory disorders.
       

       
            Sterile saline solution: A nebulizer can deliver sterile saline to help open the airways and thin secretions. This may loosen and make it

easier to cough up mucus in the lungs.

       
            Antibiotics: A nebulizer can deliver some types of antibiotics straight into the lungs or respiratory tract when someone has a

severe respiratory infection.
       
       
            Surgical gowns are traditionally worn to protect patients from contamination by the surgical

team, and it works as isolation gowns. Blood routinely covers gowns during surgery and often contaminates

surgeons' undergarments and skin. Because of risks to the surgical team by blood-borne pathogens, disposable and reusable gowns were examined. To

quantify "strike through," 1440 samples of gown fabric were tested against human blood in an apparatus designed to simulate abdominal pressure

during surgery. Representative pressures (0.25 to 2.0 psi) and times (1 second to 5 minutes) were studied. Above 0.5 psi, spun-bond/melt-blown/spun-bond

disposable products were more resistant than spun-lace cloth. New cloth gowns were better than those washed 40 times. Spunbond/melt-blown/spun-bond fabric

exposed to blood twice was more protective than spun-lace cloth challenged once. Gowns currently available exhibit varying resistance to strike through; only

those with an impervious plastic reinforcement offer complete protection.

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