Our company specializes in the design, production, and sales of cubic oxygen concentrators. Cubic oxygen concentrators can be widely used in steel cutting, oxygen-enriched combustion, hospital oxygen, petrochemical industry, electric furnace steelmaking, glass production, papermaking, ozone production, and aquatic products. In industries and fields such as breeding and aerospace, Tianao provides personalized and specialized oxygen production equipment to fully meet the gas usage requirements of different users in different industries.
A series of pressure swing adsorption oxygen production equipment provided by Xinbang (it has the characteristics of low equipment cost, small size, light weight, simple operation, convenient maintenance, low operating costs, fast on-site oxygen production, convenient switching, no pollution, etc. Advantages, it can be applied to steel cutting, oxygen-rich combustion, oxygen use in foreign hospitals, etc.) and cryogenic oxygen production equipment (high oxygen purity, long service life of the equipment, can produce nitrogen, oxygen, and argon at the same time, suitable for oxygen station construction, hospitals Smooth cutting with oxygen, steel).
The models our company can choose are oxygen-generating equipment with an oxygen purity of %, and cryogenic oxygen-generating equipment with an oxygen purity greater than .%.
1. Technical indicators of oxygen production equipment (contact information:)
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2. Working principle of oxygen generating equipment
Pressure swing adsorption oxygen generating machine uses zeolite molecular sieve as the adsorbent, and uses the principles of pressure adsorption and pressure reduction desorption to extract oxygen from the air. Automated equipment that adsorbs and releases oxygen to separate oxygen. Zeolite molecular sieve is a spherical granular adsorbent processed by a special pore processing technology. The surface and interior are covered with micropores. It is white in color. Its pore characteristics enable it to achieve precise kinetic separation. The separation effect of zeolite molecular sieve on gas and gas is based on the slight difference in the kinetic diameter of the two gases. The molecules have a faster diffusion rate in the micropores of the zeolite molecular sieve, and the molecular diffusion rate is slower. The diffusion of water and nitrogen in compressed air is not much different from that of nitrogen. What is finally enriched from the adsorption tower is oxygen molecules.
Pressure swing adsorption oxygen production utilizes the selective adsorption characteristics of zeolite molecular sieves, using a cycle of pressure adsorption and decompression desorption, so that compressed air enters the adsorption tower alternately to achieve air separation, thereby continuously producing high-purity Product Oxygen.
The oxygen generator is based on the principle of pressure swing adsorption and uses high-quality zeolite molecular sieve as the adsorbent to produce oxygen from the air under a certain pressure. The purified and dried compressed air is adsorbed under pressure and desorbed under reduced pressure in the adsorber. Due to the aerodynamic effect, the diffusion rate of nitrogen in the pores of the zeolite molecular sieve is much greater than that of oxygen. Nitrogen is preferentially adsorbed by the zeolite molecular sieve, and oxygen is enriched in the gas phase to form finished oxygen. Then the pressure is reduced to normal pressure, and the adsorbent desorbs the adsorbed nitrogen and other impurities to achieve regeneration. Generally, two adsorption towers are set up in the system. One tower adsorbs and produces oxygen, and the other tower desorbs and regenerates. The program controller controls the opening and closing of the pneumatic valve, so that the two towers cycle alternately to achieve the purpose of continuous production of high-quality oxygen. The entire system consists of the following components: compressed air purification components, air storage tanks, oxygen and nitrogen separation devices, and oxygen buffer tanks. If cylinders are needed, an oxygen booster and bottle filling device are installed at the end.
Compressed air purification unit
The compressed air provided by the air compressor is first passed into the compressed air purification assembly. The compressed air first removes most of the oil, water and dust through the pipeline filter, and then is freeze-dried. The machine further removes water, the fine filter removes oil, and dust, and is followed by a super-fine filter for deep purification. According to the system working conditions, UEG Gas specially designed a set of compressed air oil remover to prevent possible trace oil penetration and provide sufficient protection for the molecular sieve. Rigorously designed air purification components ensure the service life of the molecular sieve. The clean air processed by this component can be used as instrument air.
. Air storage tank
The function of the air storage tank is to reduce air flow pulsation, act as a buffer to reduce system pressure fluctuations, and allow compressed air to pass smoothly through the compressed air purification component to fully remove oil and water impurities. , reducing the load on the subsequent oxygen and nitrogen separation device. At the same time, when the adsorption tower switches work, it also provides the oxygen and nitrogen separation device with a large amount of compressed air required for rapid pressure increase in a short time, so that the pressure in the adsorption tower quickly rises to the working pressure, ensuring reliable and stable operation of the equipment. .
Oxygen and nitrogen separation device
There are two adsorption towers equipped with special molecular sieves, B. When the clean compressed air enters the inlet end of the tower and flows to the outlet end through the molecular sieve, it is adsorbed by it, and the product oxygen flows out from the outlet end of the adsorption tower. After a period of time, the molecular sieve adsorption in the tower is saturated. At this time, the tower automatically stops adsorption, and the compressed air flows into Tower B to absorb nitrogen and produce oxygen, and regenerate the tower-joined molecular sieve. The regeneration of molecular sieves is achieved by rapidly lowering the adsorption tower to normal pressure to remove the adsorbed ones. The two towers alternately perform adsorption and regeneration to complete the separation of oxygen and nitrogen and continuously output oxygen. The above processes are controlled by programmable controller (). When the oxygen purity at the outlet end reaches the set value, the program takes effect and the automatic vent valve opens to automatically vent unqualified oxygen to ensure that unqualified oxygen does not flow to the gas point. When the gas is vented, use a muffler to silence it so that the noise is less than B.
Oxygen buffer tank
The oxygen buffer tank is used to balance the pressure and purity of oxygen separated from the nitrogen and oxygen separation system to ensure a stable continuous supply of oxygen. At the same time, after the adsorption tower switches work, it will recharge part of its own gas into the adsorption tower. On the one hand, it helps to increase the pressure of the adsorption tower, and on the other hand, it also plays a role in protecting the bed. It plays a very important role in the operation of the equipment. Supporting role.
, Oxygen filling system
Oxygen filling includes oxygen balloon, oxygen booster, and oxygen filling row to fill the finished oxygen into cylinders.
3. Technical indicators of low-temperature air separation oxygen production equipment
< . > 4. Working principle of low-temperature air separation oxygen production equipment
Oxygen, nitrogen and argon can be produced by separating air through low-temperature distillation process gas.
Air compression, cooling and purification
The raw air is compressed by a multi-stage centrifugal turbine compressor (the air compressor is equipped with a suction air filter and an intermediate aftercooler), and the heat generated by the compression is intermediately cooled It is taken away from the cooler and aftercooler, and then further cooled to the required temperature by polluted nitrogen and chilled water in the air cooling tower. A demister is used to remove moisture from the air, and a water separator is also installed.
The pre-cooled air passes through the double-bed adsorber, and the activated aluminum and molecular sieves filled in the adsorber remove moisture, carbon dioxide and hydrocarbons in the air. After the air passes through the bed, it enters the dust filter to remove molecular sieve powder that may be contained in the air. A small stream of air is extracted after the dust filter as instrument air for the air separation equipment.
One of the two adsorbers is used, and the other is regenerated with polluted nitrogen from the cold box. The regeneration gas (contaminated nitrogen) is heated by an electric heater in the regeneration heating cycle.
After the air leaves the purification system, the clean air is divided into two streams. One stream (medium-pressure air) enters the main heat exchanger in the cold box, and the other stream is compressed to high pressure by a multi-stage centrifugal air booster and then sent to the cold box. The medium-pressure air and high-pressure air are cooled by exchanging heat with the reflux liquid oxygen through the main heat exchanger in the cold box to produce product oxygen, product nitrogen and waste nitrogen.
Air Distillation
Air distillation is carried out in the cold box of the air separation equipment. The cold box is equipped with main heat exchanger, nitrogen heater, lower tower, upper tower, main condenser, argon condenser, argon tower, turbine expander, cryogenic pump, etc.
The medium-pressure air () close to the dew point enters the lower tower for primary separation.
A part of the high-pressure air is extracted from a certain position of the main heat exchanger and sent to the turbine expander for expansion to obtain the required cooling capacity. The expanded air is fed into the medium pressure column (bottom of the lower column). Another part of the high-pressure air is further compressed in the booster coupled with the expander to increase the pressure, evaporate the liquid oxygen in the main heat exchanger, expand through the expansion valve, and then sent to the medium-pressure tower (bottom of the lower tower). Oxygen and nitrogen are separated from the air through low-temperature distillation in the cold box. In order to produce argon gas, the argon fraction in the middle of the upper tower is sent to the refined argon tower to remove the nitrogen component. Send the pure liquid argon obtained at the bottom of the tower into the storage tank.
100 cubic oxygen generator