1. Equipment selection: laying a solid foundation
First, in the equipment selection stage, the actual needs and long-term planning of the hospital should be fully considered. It is key to select equipment with advanced oxygen production technology, high efficiency and low energy consumption. At the same time, the equipment should have complete protection functions, such as automatic shutdown protection for overpressure, overheating, overcurrent, overtemperature, water shortage, short circuit, etc., as well as built-in pressure relief devices and pressure detection devices to ensure rapid response in abnormal situations and avoid safety accidents.

2. Daily maintenance: ensuring equipment health
Daily maintenance is the cornerstone to ensure the long-term stable operation of Hospital Oxygen Generator. A complete maintenance plan should be established to regularly inspect, maintain and repair the equipment. Specifically including but not limited to:

Cleaning and disinfection: Regularly clean dust and dirt on the surface of the equipment to prevent contamination and overheating of the equipment. For parts in contact with oxygen, appropriate disinfectants should be used for disinfection to avoid the growth of microorganisms.
Filter replacement: Regularly replace air filters and precision filters to prevent dust, bacteria and other pollutants from entering the system and affecting the quality of oxygen.
Lubrication and tightening: Regularly add lubricating oil to parts that need lubrication (such as compressors, valves, etc.) to maintain good lubrication; at the same time, check all fasteners to ensure that there is no looseness.
Electrical inspection: Check whether all electrical connections are firm to ensure that there is no corrosion or short circuit. Test whether the control system functions normally, including sensors, displays, alarm systems, etc.
Performance testing: Regularly perform performance tests on the equipment, record key parameters such as oxygen flow and concentration, and ensure that the equipment performance meets the specified standards.
3. Safety management: Building multiple lines of defense
Safety management is the key to ensuring the safety performance of Hospital Oxygen Generator. A complete safety management system should be established, including equipment operating procedures, emergency plans, personnel training, etc. At the same time, take the following measures to build multiple lines of defense:
Pressure control: Ensure that the pressure of the oxygen storage tank is within the safe range and avoid being too high or too low. Install pressure relief valves and safety valves to ensure that pressure can be quickly relieved in overpressure conditions.
Fire prevention measures: Anti-backfire devices should be installed inside the equipment to quickly seal and extinguish the flame when backfire occurs. At the same time, sufficient fire-fighting equipment should be equipped around the equipment, and fire drills should be conducted regularly.
Personnel training: Regular professional training should be conducted for operators to enable them to master the operating procedures, emergency response methods and safety precautions of the equipment.
IV. Intelligent upgrade: Improve management efficiency
With the continuous advancement of medical technology, intelligent management has become an important means to improve the operating efficiency and safety performance of Hospital Oxygen Generator. By introducing advanced technologies such as the Internet of Things, big data, and cloud computing, functions such as remote monitoring, data analysis, and fault warning of equipment can be realized.

Remote monitoring: Through the Internet of Things technology, remote monitoring and management of equipment can be realized, and potential faults can be discovered and handled in time.
Data analysis: Using big data technology, equipment operation data is analyzed and mined to provide a scientific basis for equipment maintenance and management.
Fault warning: Through intelligent algorithms, equipment operation data is monitored and analyzed in real time, possible equipment failures are predicted, and measures are taken in advance to prevent them.