PureAire Oxygen Analyzer for 3D Printers: How Argon is used and Why O2 Detection is Required

Thanks to new technologies, the 3D printers that have been used to create plastic three-dimensional objects can now print metal. Titanium 3D printing is possible thanks to a technique called DMLS, or Direct Metal Laser Sintering. While the potential to use titanium 3D printing is groundbreaking for many industries, the new advances could pose a health hazard if volatile gases used in the printing process are not contained. Learn more about the role of argon in 3D printing and how an oxygen analyzer can safeguard your employing while printing. 

What Happens in Direct Metal Laser Sintering? 

3D printing of plastics uses an additive process in which objects are constructed layer by layer or fused together cross section by cross section. These basic techniques need rethinking for titanium 3D printing. With Direct Metal Laser Sintering, a laser follows a computer-aided design (CAD) file to melt titanium powder, rendering the object. The process is similar to sculpture, in which pieces of the raw material are carved away to create or reveal a three-dimensional object or figure. 

Because titanium is such a strong metal, the resulting objects are highly durable. For something like medical devices or three-dimensional replacement joints or bones, this means that individuals can get greater use out of the replacement part. Aviation professionals greet these new developments, estimating that titanium parts can cut the weight of an airplane by as much as 1,000 pounds, saving fuel on every flight. 

Since the titanium powder (Or other metal powders) used in this additive manufacturing process is created from manufacturing remnants, the materials are highly cost-effective. 

What are the Risks of 3D Printing? 

The 3D printer operates in an inert environment, where argon prevents any unwanted chemical reactions from taking place and maintains the purity of components. The inert environment in the 3D printing machine keeps the oxygen content low, to reduce oxidization in the manufactured part. It also reduces the fire hazard by rendering combustible dust inert. Since thermal stress is controlled and titanium powder clumping is reduced, the argon improves the consistency of the final product and reduces deformities. 

While there are many benefits to using argon in the printing process, and argon is harmless when contained, it does pose a health risk should the argon escape the additive manufacturing environment. 

Argon is known as an oxygen displacer. This means that when argon gas leaks into the air, it physically displaces the levels of oxygen in the air. In extreme cases, staff can asphyxiate due to the lack of oxygen in the environment. 

This gas is colorless, tasteless, and odorless. Were argon to leak out of the 3D printer, staff would be unable to see or smell it. As soon as oxygen begins to deplete from the room, it cause symptoms including dizziness, shortness of breath, and confusion. Even if staff suspect that something is wrong, they may be unable to escape from the area before it is too late. 

When you have a poorly ventilated manufacturing space with several 3D printers going at once, the potential for oxygen displacement by argon gas increases.

How Can an O₂ Analyzer Reduce Risks? 

An O₂ Analyzer helps keep levels inside the 3D printing environment low, to ensure the printer works optimally. Without the analyzer, there would be no way to ensure that the ppm concentration of oxygen remained at a steady state for the duration of the printing process. The oxygen analyzer checks levels of oxygen ranging from 0 to 1,000 parts per million (ppm). 3D printers using the DMLS process need to keep the oxygen under 1% or less for product manufacturing. A 0 to 25% oxygen range detector is also available. The oxygen analyzer can make sure that the air inside the chamber meets the low levels needed. Meanwhile the air outside is safe for staff to breath. PureAire's oxygen analyzers are easy to install and easy to use. Once set up, they require no maintenance and will work as promised for a set period of time.

At PureAire, we have just developed a new oxygen analyzer that works with 3D printers. To learn more about our new oxygen analyzer, please visit www.pureairemonitoring.com or send an email to info@pureaire.net. 

Source

http://nj.gov/health/eoh/rtkweb/documents/fs/0151.pdf

http://3d-printing-titanium.com/titanium-3d-printer-everything-you-need-to-know/

Air Separation Plants and the Use of Oxygen Monitors

Air separation plants are critical for many different industries, from clean energy to manufacturing. Nowadays, cryogenic is the most common type of distillation used to separate air into its component gases - nitrogen, oxygen, and inert gases including helium and argon. If your industry relies on air separation for product development or manufacturing, then knowing how the process works is an important part of operational safety. Learn about air separation plant operation and safety protocol to be informed. 

How Air Separation Plants Work

In the cryogenic air separation process, air is chilled to the liquid stage. At this point, nitrogen and oxygen can be separated out from the inert gases in the air. Each compound can then be distilled at boiling temperature, thereby returning the liquid to a vapor state. The resulting nitrogen and oxygen gases are highly pure. 
To get the air ready to be separated, plant employees first filter the air to remove particles, such as dust. Next, the air is pressurized and then filtered up to several times to remove carbon dioxide, which can freeze the distilling equipment. 

Using a still and heat exchanger, workers heat and cool the gas, turning it into a highly pure liquid. The oxygen liquefies and falls to the bottom, while the highly pure nitrogen gas floats above the oxygen since it is lighter. 
Once separated, the gases can be kept in gaseous state or returned to a liquid state via chilling. Many air separation plants have elaborate pipe systems, whereby the oxygen or nitrogen gas can be transported directly to production lines. 

Air separation plants have many diverse uses. Pure oxygen gas is a basic component of metalwork including steel manufacturing. Nitrogen gas helps preserve edible oils from oxidizing and is used as a safeguard against combustion in shipping and cargo transit. 

The cryogenic process is effective and efficient at separating air; however, it does pose some safety risks. Air is safe to breathe when nitrogen and oxygen are together in the appropriate ratio. As nitrogen and oxygen are separated two distinct hazards emerge. 

Pure oxygen increases the fire danger in an environment. If not controlled, this could turn dangerous. 
Pure nitrogen depletes oxygen and can cause death via asphyxiation. Since nitrogen is colorless and odorless, workers may not know if the distilled nitrogen has escaped the still and infiltrated the environment. Argon acts in a similar manner, yet is a less common hazard since it is present in trace levels in oxygen. 
Without a safeguard of an oxygen monitor, staff may be exposed to toxic gases. In a worst-case scenario, staff could die. 

How an Oxygen Monitor Protects Staff

Between 1992 and 2002, 80 workers died from nitrogen exposure. Workers may fall unconscious after even a single breath of oxygen deficient air. If individuals do not receive oxygen in a matter of minutes, the consequences are grave. 

Educating staff about the dangers of these gases is a first step toward operational safety. Installing an oxygen or O₂ monitor is the next step to keeping everyone safe. 

An O₂ monitor measures the levels of oxygen in the air at any given time. The device takes sample readings of the air and remains silent as long as there is sufficient oxygen in the environment. Since argon and nitrogen deplete oxygen, the level of oxygen in the room will decrease if a gas leak occurs. When oxygen levels fall below the minimum safety level, the O₂ detector will sound an alarm. Trained staff will then know to evacuate the premises until emergency assistance arrives. 

Oxygen deficiency monitors from PureAire are guaranteed to perform for 10 years. These oxygen deficiency monitors have a zirconium oxide sensor, which accurately measures air oxygen levels in temperatures as low as -40 Celsius. The O2 monitor from PureAire is an efficient, cost-effective way for plants using nitrogen, helium, or argon to keep staff safe from the known health hazards of these gases.

If you seek an oxygen monitor that needs no maintenance, no calibration, and is guaranteed to last, you may be interested in PureAire's line of products. Learn more at www.pureairemonitoring.com or by emailing info@pureaire.net for more information. 

Chlorine Safety and Prevention: How to Protect Yourself from Chlorine Leaks

While chlorine gas is widely used in swimming pools, water treatment facilities, cleaning products, pharmaceutical products, and in many other industries, the gas is highly toxic when handled improperly. Training your workers on how to safely use chlorine is one part of health and safety best practices; monitoring your workplace for chlorine leaks is another. Learn about the hidden dangers in this common substance and how you can stay safe. 

The "Hidden Dangers" of Chlorine 

So many everyday things that you see and touch have come into contact with chlorine. The substance is a common cleaner and disinfectant because it is easy to use and inexpensive. Chlorine is also used in agricultural pesticides, in the manufacturing of drugs, in wastewater treatment facilities and the sanitizing of everyday drinking water, in paper manufacturing, in hospitality swimming pools and spas, and in many other products. No matter where it is being used, chlorine must be properly handled by all staff at all times. 

At room temperature, high chlorine levels are toxic. If chlorine gas comes into contact with substances including ammonia, ether, hydrogen, and turpentine, it can combust. Since this gas can cause breathing problems, it is dangerous to individuals with respiratory problems including asthma. 
The gas is yellowish at room temperature and has a distinct odor, so staff will be able to see and smell the substance. While this does aid in awareness of chlorine leaks, it is not sufficient to trust that your staff will see or smell leaked chlorine and leave. 

Employees exposed to chlorine can experience eye damage, coughing, choking, frostbite on the skin, and respiratory problems. In a worst case scenario, staff can die from suffocation due to sustained chlorine exposure. 

Fortunately, fixed gas monitors are an efficient way to protect staff from a chlorine leak. 

How PureAire Universal Gas Detectors Protect You From Chlorine Leaks

At PureAire, we offer universal gas monitors that protect against chlorine and other gases. PureAire's universal gas detectors are compact and designed for wall mounting in areas where you store or work with gases. Once installed, these detectors continually performs gas detection and monitoring. The maximum acceptable level of chlorine that workers can be exposed to, per OSHA regulations, is 1.0 parts per million (ppm). Chlorine is considered to be "Immediately Dangerous to Life and Health" when levels reach 10 ppm. As long as levels of chlorine remain below the acceptable safe level of 1.0 ppm, the detector is silent. Yet if gas leaks out and levels rise above the maximum acceptable level, the PureAire gas detector will sound an alert and flash a light so that staff will see or hear the alarm. 

Staff can then have enough time to stop what they are doing, exit the premises, and wait for emergency responders to contain the chlorine leak. When staff are alerted as soon as levels exceed those deemed safe, they can get out of the building before succumbing to chlorine-related health hazards. 

The universal gas monitor from PureAire protects against toxic gases including chlorine, hydrogen chlorine, ammonia, hydrogen fluoride, and other gases. Once installed, the PureAire detector will last for more than seven years without requiring any maintenance. If you seek a safe solution that delivers peace of mind and effective protection from chlorine leaks, PureAire's fixed gas monitor is a cost-effective, reliable option. 

Capable of chlorine gas detection in temperatures as low as -25 Fahrenheit up to to 22 Fahrenheit (-32 C to 50 C), these gas detectors offer flexible gas monitoring for visible and invisible toxins. PureAire's universal gas monitor is also water resistant and capable of detecting gases within a 30-foot range. 

Since PureAire's detectors have such a long lifespan, they are a convenient way to address gas leaks in the workplace. An optional long life renewable sensor extends the lifespan of these gas monitors by recharging the battery. 

After you install the gas monitor, your staff can work with chlorine and other gases with the certainty of knowing that their safety is protected. To protect your workers and your business assets, look to PureAire. View their fixed gas monitor or learn more at http://www.pureairemonitoring.com. 

PureAire Universal Gas Detector Offers Protection Against Toxic Levels of Ammonia

In March of 2016, an ammonia gas leak at a seafood processing plant in Boston left one worker dead. The fumes at the plant were so powerful that firefighters could not promptly enter the scene to mitigate the gas leak and try to save the staff member until much later. Reports show that 5,300 pounds of ammonia gas leaked out of the plant. If you work with ammonia at your facility, learn why this gas is so dangerous and one simple thing that you can do to prevent a tragedy like this from affecting your workers. 
The Hidden Dangers of Ammonia 
Ammonia is commonly used in refrigeration of dairy, meat, food processing, and cold storage. In fact, almost everything you can buy at your local grocery store has passed through an ammonia refrigeration site before making its way to your local store. 
A mixture of nitrogen and hydrogen, ammonia has been used in refrigeration since the 1800's. It is energy-efficient, inexpensive, more environmentally friendly than chlorofluorocarbon (Freon) refrigerant, and widely available via commercial manufacturing. While it may have started off as a refrigerant of food, ammonia is also used today for ice and water chilling in office buildings. In Europe, ammonia has additional applications in air conditioners in public buildings including hospitals and airports. The substance is also used in industries as diverse as semiconductor manufacturing, environmental emission monitoring, agricultural fertilizer, and chemical manufacturing.
As useful as ammonia is, it is also a dangerous substance when not properly stored. It can combust at high heat. While colorless, ammonia gas has a noxious odor. 
When workers are exposed to ammonia gas, they can experience skin and eye irritation. If concentrations of ammonia are high, burning and injury can result. In some cases permanent eye damage or blindness can occur. 
Workers will immediately know they are exposed to a harmful substance from symptoms including respiratory and nasal burning. Even though staff have a warning due to ammonia's odor, the substance causes adaptation. Workers may perceive a slight ammonia odor at low levels of exposure, and adjust to the scent so they can't tell when concentration has surpassed acceptable levels. 
In a worst case scenario, those exposed to ammonia will experience respiratory failure and die. The good news is, there are ways to protect staff from ammonia exposure using universal gas detection tools. 
How PureAire Universal Gas Detectors Protect Staff from Ammonia Exposure
PureAire's universal gas monitors protect against not only ammonia, but bromine, chlorine, hydrogen chloride, hydrogen fluoride, hydrides and other gases. Once installed, the monitor continually checks levels of gases and provides a visual and aural alert if levels of any substance exceed safe levels. 
This is a simple solution for round the clock gas monitoring for ammonia and many other hazardous gases. While ammonia has an odor, many other dangerous gases do not. Gas monitoring protects workers against substances they can smell as well as "silent killers" they cannot see or smell. With a universal gas monitor installed, workers can perform their duties secure in the knowledge that they will be alerted if ammonia or another substance leaks into the environment. 
After installation, the universal gas detector will work for over seven years with no maintenance. PureAire's gas monitor are built to outlast the competition to provide improved peace of mind for management and staff. 
If an ammonia leak were to happen, the gas monitor would sound an alarm so that workers can safely evacuate before succumbing to respiratory damage or failure. With staff outside the premises, everyone is thereby safe until first responders can deal with the leak. For example, in the Boston incident, the worker would have been able to escape the seafood plant with his life, resulting in an ammonia leak with no fatalities. 
Not only is gas detection the right thing to do for peace of mind, it can safeguard your business assets and personnel from dangers. To learn more about PureAire's line of universal gas detectors, please visit http://www.pureairemonitoring.com. 

Source

http://www.bostonherald.com/news/local_coverage/2016/03/worker_dies_in_ammonia_leak_at_plant_in_seaport

https://www.health.ny.gov/environmental/emergency/chemical_terrorism/ammonia_tech.htm

PureAire Universal Gas Monitor Receives UL Listing

PureAire is pleased to announce that its PureAire Universal Gas Monitor received the UL/CUL listing for models 99030 and 99031. PureAire’s Universal monitors comply with national and international safety standards, including UL 61010-1, CSA C22.2 NO. 61010-1-12-CAN/CSA, and IEC/EN 31010-1. 

Designed to protect against toxic gases including ammonia, bromine, chlorine, hydrogen chloride, hydrogen fluoride, hydrides and other gases, the universal gas monitor from PureAire offers continuous monitoring against unsafe gas levels. A universal gas monitor provides an easy and cost-effective solution for consistent monitoring for those organizations that need to work with these potentially toxic gases, yet wish to safeguard their workers. 

PureAire universal gas monitors are recommended for settings as diverse as cold food storage, chemical plants, semiconductors, manufacturing plants, pharmaceutical operations, and laboratory settings. PureAire's line of universal gas monitors allow facilities to work with these gases in a safe and responsible manner. The renewable sensor lasts for more than 7 years, longer than those of competitors. A built-in alarm sounds when gases surpass safe levels, allowing workers to take notice even when they cannot otherwise see, smell, or taste the gases. PureAire's universal gas monitors also have a 4-20 mA signal and 2 user-selectable relays, which can signal external horns, strobes, or fans. 

About PureAire

PureAire, which was founded in 1997, offers a line of oxygen monitoring devices and universal gas monitors for use in commercial, retail, educational, laboratory, and other settings. PureAire's line of universal gas monitors have sensors guaranteed to last for 7 years without maintenance, offering superior performance and reliability. The universal gas monitors run on a UL listed 24 VDC power supply. To learn more about PureAire or view their line of universal gas monitors, please visit www.Pureairemonitoring.com.

Fertility Clinics and Egg Freezing: Nitrogen Use and How to Remain Safe

For women who want to have children when the time is right, egg freezing is a viable option and one that has become more popular in recent years. As an abundance of fertility clinics pop up nationwide, it is important to consider the safety implications of IVF, egg freezing, and fertility clinics. Dive into the world of fertility clinics to understand how eggs remain viable -- sometimes for years after harvesting -- and what risks the environment holds.

How Do Fertility Clinics Harvest and Store Eggs?

During the monthly menstrual cycle, women release a viable egg. In the fertility harvesting process, IVF clinicians administer hormones that increase egg production so they can harvest and store multiple eggs in a one-time procedure.

Doctors first administer hormone injections to inflate egg production prior to harvesting and storage. Three days after the final injection, the eggs are ready for harvesting. At this point, female patients then have eggs harvested from their ovaries using needles. Now the patient's role is simply to leave the eggs at the IVF facility until she wishes to be inseminated.

Traditionally, eggs were frozen for long-term storage, then thawed out when patients wanted to use the eggs. This method worked, but had a suboptimal success rate during IVF.

A new method, termed vitrification, increases the success rate of egg freezing for in vitro fertilization. Vitrification uses a flash freezing process to quickly freeze the eggs for long-term storage. After the eggs have frozen, they are then stored inside tanks of liquid nitrogen until they are needed. The new method reduces the formation of ice crystals, which can damage the egg during the thawing out.

The main risk that doctors counsel patients on is the chance that some or all of the eggs will perish in the process. Freezing of eggs is still a relatively new procedure. However, there is a greater risk involved. One that could affect female patients, their eggs, and fertility clinic staff: The risk of liquid nitrogen exposure.

Nitrogen Warnings in the Fertility Clinic Setting

Liquid nitrogen is perfectly safe as long as it remains in storage tanks. If even a single tank were to develop a leak, and the substance were to spill out into the fertility clinic, a lot more would be at stake than the viability of stored eggs for in vitro fertilization.

Nitrogen has the potential to deplete oxygen from an environment. At first, this may cause discomfort, dizziness, or confusion. As the leak continues and displaces more oxygen from the room, staff can asphyxiate. Since the gas cannot be seen or smelled, employees will not know something is wrong until it is too late and lives are lost.

For the safety of clinic staff, an oxygen deficiency monitor can be installed near the liquid nitrogen tank. This monitor takes periodic readings of the oxygen levels in the room. When everything is working properly and the oxygen is within the normal range, the monitor remains silent yet vigilant. In a worst case scenario where a nitrogen leak does develop, the O2 monitor will sound an alert once the oxygen in the room falls below acceptable levels. The alarm gives staff enough notice to escape the premises before being overcome by the lack of oxygen.

Like a carbon monoxide detector, an oxygen deficiency monitor does not really do anything until something goes wrong but can save lives in the event of an emergency. As with a carbon monoxide detector, it is important to select and install a quality O2 monitor.

The latest generation of oxygen monitors from PureAire come with a zirconium sensor, which requires no calibration or maintenance. Staff can install the O2 monitor in the IVF facility and remain assured that it will work for a period of 10 years with no maintenance of any kind.

For a reliable oxygen deficiency monitor, look to PureAire, a company with over 15 years of experience in the field. Learn more about PureAire's products at www.pureairemonitoring.com.

Nitrogen Generators: Where are they Installed and How to Stay Safe?

Used in a range of industries, nitrogen generators ensure a steady supply of 99.5% pure, commercially sterile nitrogen from a compressed air storage tank. From an industrial standpoint, nitrogen generators are seen as preferable to cylinders of nitrogen as they are more reliable, more compact, and easy to use and install. However, these generators are not without risk. Learn about nitrogen generator installation best practices and how to stay safe when using these devices in your facility. 

Where are Nitrogen Generators Installed? 

Since nitrogen generators have such a wide array of end use cases, they wind up getting installed in different commercial environments. Nitrogen generators may exist in: 

• Brewing operations - To sparge and mix the wort 
• Food processing and packaging plants - In the food packaging process  
• Industry - To test and clean tanks and vessels
• Engineering facilities - For use in manufacturing, testing, and product development
• Automotive plants - In paint booths 

These generators offer a steady supply of nitrogen at a lower cost than using gas cylinders. One generator takes up less room than several cylinders, saving floor space where it is needed most. A generator is easy to install and simpler for employees to use (since it requires less maintenance) than cylinders, so many manufacturers have switched from using cylinders of nitrogen to using generators. 

Nitrogen generators are most often operated indoors, as these typical use cases show. In the event of a leak or other problem with the generator, escaping gas has nowhere to go other than inside the building. In some cases, the building may be set up so that nitrogen generators vent to the outside, thus offering a buffer from the harmful gas; however, it is not always possible to vent the generator to plain air. 

That said, these units do post a risk. Nitrogen is a colorless, odorless gas that creates an oxygen deficient state. If the generator were to develop a leak, nitrogen gas could leak out undetected into the work environment. In a matter of minutes, nitrogen gas from a leaking tank can deplete the workspace of oxygen. To protect the health of your employees, it is necessary to only use nitrogen generators in conjunction with an oxygen monitor, which alerts staff to low levels of oxygen. 

Why You Need an Oxygen Monitor With Nitrogen Generators

An O₂ monitor, or oxygen monitor, continually monitors the level of oxygen in the room. When there is enough oxygen, the detector stays silent. A normal oxygen value is 21 percent by volume.  If something unexpected happens -- such as a nitrogen leak -- and the amount of oxygen in the room begins to fall, the monitor sounds an alarm and flashes to grab staff attention. This way, staff have advance knowledge and can leave the work space before oxygen levels fall too low. 

Oxygen monitors can alert staff if levels fall too low (19.5 percent or less) or too high (23.5 percent or above). Low levels of oxygen pose a severe health hazard for individuals, while high levels of oxygen pose a fire and combustion hazard. 

Without an O₂ monitor in place, staff would have no knowledge of a nitrogen problem until it was too late. When oxygen levels fall below the acceptable threshold, staff can become disoriented and fatigued, while succumbing to a euphoria that can dissuade them from noticing that something has gone wrong. Loss of coordination and mental processing skills, followed by poor judgment, vomiting, nausea, and eventually death by asphyxiation as oxygen levels continue to fall. 

An additional consideration for large facilities is that nitrogen gas is often used far from the actual location of the generator. Thus, even if the generator you have purchased comes with an O2 monitor of its own, the monitor may not be able to test working conditions where the nitrogen is actually in use. A facility may need multiple oxygen monitors to make sure that all areas where nitrogen gas is used have acceptable air quality. 

PureAire offers O2 monitors that work in conjunction with nitrogen generators. PureAire's line of oxygen detectors rely on zirconium sensors, which are guaranteed to work for at least 10 years without calibration. When it comes to protecting your staff, it's the wise choice. Explore PureAire's lineup of oxygen detectors at http://www.pureairemonitoring.com.