Protecting Against Oxygen Deficiency Risk

 

What is Oxygen Deficiency?

The air we breathe is made up of 78% nitrogen, 21% oxygen, and trace amounts of other gases such as carbon dioxide, neon, and hydrogen. The Occupational Safety and Health Administration (OSHA) defines an environment in which oxygen levels fall below 19.5% as an oxygen-deficient atmosphere, which should be treated as immediately dangerous to health or life.

How is Oxygen Deficiency Dangerous?

Oxygen deficiency is often called a silent killer, because there are no warning signs when oxygen concentrations drop to an unsafe level.

Inhaling just a few breaths of oxygen-deficient air can have immediate negative effects, which may include impaired coordination, accelerated respiration, elevated heart rate, nausea, vomiting, loss of consciousness, convulsions, or even suffocation due to a lack of sufficient oxygen.

Where can Oxygen Deficiency Occur?

Oxygen deficiency can occur in any location where compressed oxygen-depleting gases are used, stored, or may accumulate.

Industries that commonly use these types of gases include, but are not limited to, laboratories, MRI, food and beverage, cryogenic facilities, aerospace, pharmaceutical, research and development, alternative fuel, waste management, semiconductor, additive manufacturing, and the oil and gas sectors.

Manufacturers and other organizations utilizing compressed, oxygen-depleting gases in their operations need to successfully navigate complex working environments in which high concentrations of such gases may be critical to production procedures, but where the risks of oxygen deficiency may pose a potential safety hazard for their employees.

Fortunately, by utilizing a top-quality oxygen deficiency monitor, facility managers can maintain stringent processing requirements, as well as protect the health and safety of their personnel.

What is an Oxygen Deficiency Monitor?

An oxygen deficiency monitor is a device that measures oxygen levels in a particular area. By continuously tracking oxygen levels, oxygen deficiency monitors are designed to detect oxygen-depleting gas leaks before employee health is jeopardized.

A number of oxygen-depleting gases, including nitrogen, helium, carbon dioxide, and argon, among others, are both odorless and colorless. As such, unless they are using a reliable oxygen deficiency monitor, personnel working with such gases would likely be unable to detect a gas leak should one occur in a gas cylinder or line, and they could likewise be unaware that they were breathing oxygen-deficient air.

PureAire Oxygen Deficiency Monitors

    

PureAire Monitoring Systems’ line of Oxygen Deficiency Monitors offers thorough air monitoring, with no time-consuming maintenance or calibration required. An easy-to-read screen displays current oxygen levels for at-a-glance reading by employees, who derive peace of mind from the Monitor’s presence and reliable performance.

Our Monitor continuously tracks oxygen levels and, in the event of a gas leak and a drop in oxygen to an OSHA action level, will set off an alarm, complete with horns and flashing lights, alerting employees to evacuate the affected area.

The Monitor will remain accurate at temperatures as low as -40C. PureAire's durable, non-depleting, long-life zirconium oxide sensor will last for 10+ years in a normal environment without needing to be replaced.

To reduce risk to personnel, PureAire's optional Remote Digital Display may be placed well outside of high risk rooms (up to 250 feet from the Monitor itself), where it will safely exhibit oxygen levels inside the room.

University Environmental Health & Safety Departments: Handling Compressed Nitrogen and Cryogenics

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An explosion at a university research lab in Hawaii last year highlights the dangers of working with compressed gas and the need for safety equipment on campus. Learn the dangers of working with compressed gas, how an oxygen deficiency monitor can help, and campus safety best practices. 

Compressed Gas on Campus: Uses and Dangers

Compressed gases including nitrogen, argon, and oxygen are widely used on campuses. These gases have many practical and educational uses across educational institutions. While the level of risk varies across schools, a few examples will illustrate the benefits and the risks of using compressed gas on campus.

Argon gas is critical in the 3D printing process, which campus design, fine arts, applied arts, and sciences may use. Culinary programs may use liquid nitrogen for cooking and freezing, and chemistry labs may use N2 as well. Autoclaves, which sterilize equipment, are regularly used in scientific, medical, and industrial programs. Sports programs and physical therapy training programs may use cryotherapy for injury recovery. Cryotherapy chambers rely on nitrogen to chill the air. The chambers can turn deadly if a nitrogen leak occurs. These gases may be used by facilities personnel, researchers, faculty members or teaching assistants and students assisting with teaching labs. No matter which gas students are working with, they are at risk if the gas is not handled, used, stored, or transported properly. 

As these few examples illustrate, there are many opportunities for dangerous leaks, explosions, or fires on campus if safety protocol isn't followed. Many schools find the gases are not properly stored, which leaves everyone on campus in danger. A recent safety bulletin from the University of Rochester found that liquid nitrogen was stored without an oxygen sensor, poisonous gas was used with a fume hood that did not adequately vent hazardous fumes, gas cylinders were modified using unacceptable materials, and gas tanks were stored without protective chains, stands, and gas caps. 

Why Schools and Universities Need an O₂ Monitor 

As the incident in the Hawaiian university lab illustrates clearly, compressed gases pose significant health risks in the university setting. Whenever safety protocol is not followed, the tanks are at greater risk of tipping, falling over, or leaking. 

While the lab worker escaped with her life, many others have not been so lucky. A nitrogen (N₂) gas leak causes death via asphyxiation in a matter of minutes. 

Nitrogen gas is both odorless and colorless. If gas leaks from a canister, there is no way for passerby to tell. As the gas leaks, it lowers ambient oxygen levels below safe thresholds. When levels of oxygen in the air fall below 16 percent, people can experience adverse health affects. Additionally, university property can be damaged by fires or explosions. 

All it takes it a couple of breaths of oxygen-deficient air for symptoms including confusion, dizziness, fatigue, muscular aches, lack of consciousness, and even death. 

Given the clear dangers that these gases pose, universities and schools must take steps to protect their students and staff. Fortunately, there is an easy and cost-effective way to detect gas leaks and alert everyone before oxygen is depleted from the air: Installing an O₂ monitor. 

An O₂ monitor, also called an O₂ deficiency monitor, measures levels of oxygen in the air all the time. As long as the air has adequate oxygen, the monitor will stay silent. When levels fall below safe thresholds, the oxygen deficiency monitor will flash lights and sound an alarm. This way, everyone in the vicinity of the leak can escape without suffering adverse health effects. 

An O₂ deficiency monitor should be installed anywhere that these gases are used or stored. Universities and schools may wish to equip labs, storage facilities, equipment rooms, and hallways or corridors that connect storage rooms with labs or classrooms where the gas is used. 

PureAire offers robust oxygen deficiency monitors that feature best in class construction. Made with zirconium oxide sensors, these monitors offer 10 or more years of maintenance-free performance once installed. These monitors can detect leaks of gases including argon, nitrogen, and helium. View PureAire's line of oxygen deficiency monitors at www.pureairemonitoring.com.
 

http://cen.acs.org/articles/94/web/2016/04/Spark-pressure-gauge-caused-University.html