Wednesday, November 15, 2017

The Benefits of Nitrogen and Carbon Dioxide for Food Processing



A blend of gases -- carbon dioxide, oxygen, and nitrogen -- help preserve packaged food by reducing the amount of oxygen inside the sealed package. Gas flushing or Modified Atmosphere Packaging, as the process is called, also reduces the amount of processing that food must undergo. This preserves the quality and nutrient content of meats, vegetables, and other foods.

Estimates suggest that 25-40 percent of fresh food does not reach consumers due to spoilage in transit. Modified Atmosphere Packaging enables fresh food to stay fresh by slowing down the food spoilage process, reduces food waste, and allows consumers to store purchased foods for longer. 

Without Modified Atmosphere Packaging, oxygen levels inside food packages would be 20.9 percent. By introducing nitrogen into the package, facilities strive to lower oxygen levels, sometimes as far as zero. With no oxygen inside the package, bacteria will be unable to grow and the food will not oxidize. Carbon dioxide also inhibits bacteria growth and lowers the pH of preserved food. Carbon monoxide is often used in meat packaging, as it can preserve the red color. Packing plants use either low-barrier, breathable film that allows fruits and vegetables to breathe, or high-barrier film that prevents gas inside packaged meat, fish, or cheese from seeping out. 

As oxygen is flushed out of the package, the blend of nitrogen and carbon dioxide or carbon monoxide is piped in and the package is sealed, trapping the inert gases inside.


While the process of Modified Atmosphere Packaging revolutionized food packing, it isn't without risk. Nitrogen gas, a critical component of the gas flushing blend, has the potential to create an oxygen deficient environment if a leak occurs. As nitrogen leaks, it physically displaces oxygen, often in a matter of minutes. As employees breathe air that does not have enough oxygen, they may become tired and confused or experience difficulty breathing. Within minutes, employees could die from asphyxiation as a result of breathing oxygen-deficient air. 
Since nitrogen gas has no color or odor, secondary measures must be used to detect a leak before staff experience life-threatening symptoms. One simple and cost-effective way to monitor the food packing facility for leaks is by using an oxygen monitor. 

How an Oxygen Monitor Protects Workers in Food Packing Plants

While it's critical to maintain the right blend of gas in packaged foods, it's also important to ensure that gas used in food packing equipment does not leak out of the machines. Gases used in food packing, including nitrogen, are colorless and odorless, so staff would be unable to detect a leak visually. By installing an oxygen monitor in the food packing facility, employers can detect leaks before workers' health is adversely affected. 
Since nitrogen gas depletes oxygen, it's easy to tell whether nitrogen is leaking by taking continual measures of oxygen. The secure, wall-mounted oxygen monitor checks the levels of oxygen in the room and remains silent as long as oxygen is above the minimum amount. 

The oxygen monitor will sound an alarm if oxygen falls to 19.5% or 18.0%. The 90 db alarm is designed to be heard over the sound of the equipment, and there's also a flashing light to warn employees of a drop in oxygen levels. Employees can then leave the room before the oxygen falls below the acceptable threshold and staff begin to experience health problems. 


In addition to using oxygen monitors on the food packing line, facilities should also use oxygen monitors wherever inert gases are stored. Oxygen deficiency monitors from PureAire are designed to last for a minimum of 10 years with no maintenance or annual calibration. The monitors feature a digital display that's easy to read, and do not drift as a result of barometric pressure. If you're looking for an oxygen monitor that's low maintenance, accurate, and easy to use, consider PureAire. Visit www.pureairemonitoring.com to learn more.

Nitro Beer Tastes Better


If you've ever remarked on the smooth creaminess of a pint of Guinness, you've picked up on the key difference in its carbonation: Nitrogen rather than carbon dioxide. Such "nitro" beers have become a trend in recent years, with major U.S. breweries and small startups alike offering nitro products. Nitrogen keeps bitterness in check and balances out the hops to make drinkable craft brews, but it also increases the risk for breweries. 

How Nitro Beer Works 

CO2 is a natural byproduct of the beer brewing process, occurring when the yeast consumes the natural sugars in the wort. Breweries often add additional CO2 when kegging or bottling the beer. The carbon dioxide gas adds flavor, aroma, and those bubbles that fizz against your tongue. CO2 is also slightly acidic, so it can intensify the bitter flavors in a brew. While this might be desirable in a hop-bomb IPA or citrusy hefeweizen, it isn't always complementary to the flavor of the brew. 

Nitrogen gas adds carbonation without the bitterness, allowing the beer's natural flavors to remain. It delivers a new drinking experience with favorite brews. Nitrogen is harder to dissolve than carbon dioxide, so the resulting bubbles of carbonation are smaller. The mouth feel of a nitro beer is smoother or creamier. Dark beers -- stouts and porters -- pair well with nitrogen gas, but the nitro technique can also present a new take on a classic IPA or wheat ale. 

While the process of adding nitrogen to beer is similar to carbon dioxide, breweries must take some extra precautions. Nitro beers must be stored in tanks rated to a higher psi, 25 rather than 15. Breweries must also take precautions to ensure that nitrogen isn't leaking out of the supply lines or canisters and onto the brewery floor. Nitrogen gas displaces oxygen from the air, so if it did leak, the room would soon become oxygen deficient. Breathing oxygen deficient air causes confusion, dizziness, respiratory distress, and death via asphyxiation. Since nitrogen gas has no color or odor, breweries need a tool to check for leaks by measuring ambient oxygen levels. 

How an Oxygen Monitor Protects Brewery Staff 

Since staff cannot tell if there is a leak -- there's nothing to see or smell -- there is no way they can protect their health if a leak occurs. Oxygen monitors provide a safeguard against respiratory distress by measuring oxygen levels. As long as there is no leak, the oxygen in the brewery should remain constant. If nitrogen gas starts to leak, oxygen levels will fall. Before oxygen levels fall to a critical threshold, an oxygen monitor will sound an alarm. There's also a flashing light to get the attention of staff. 

When the alarm goes off, workers can exit the brewery floor before the lack of oxygen poses a threat to their health. Emergency personnel can then come and contain the leak. 
PureAire offers a robust oxygen monitor with two alarm levels: 19.5 percent and 18 percent, a 90 db alarm, and a bright flashing light. The oxygen deficiency monitor is designed to mount on the wall and features an easy-to-read digital interface, so workers can tell at a glance whether there's a problem.

PureAire's monitors use zirconium sensors, which deliver reliable performance even during thunderstorms, sudden barometric shifts, and other weather incidents. These O2 monitors are designed to last for 10 or more years with no maintenance or calibration, unlike other products that need regular maintenance to remain effective.  

Breweries should place one oxygen monitor in the area where beer is bottled and kegged and another where nitrogen is stored. This ensures the entire facility is protected from leaks. 


Left Hand Brewery, a pioneer of the nitro beer trend, relies on PureAire products for workplace safety.  Learn more about the oxygen monitor form PureAire at www.pureairemonitoring.com.

Monday, October 2, 2017

What is a -150C Nitrogen freezer and who uses them?


A -150 C freezer, also known as a nitrogen freezer, is used in cryo preservation. While you might think of Ted Williams being frozen on ice for a future in which he can be brought back to life, the cryo preservation method can be used to keep any type of cell alive in a suspended state. Learn how nitrogen freezers are used and how PureAire can keep your facility safe. 

Who Uses Nitrogen Freezers? 

Nitrogen freezers use liquid nitrogen to freeze biological material in extremely cold temperatures. While they are known as -150 C freezers, they actually run closer to -200 C. When living cells are stored at such low temperatures, they go to sleep rather than die. Decades or even centuries later, the frozen cells can be safely thawed with no loss of life or degradation of DNA due to their long storage. 

Compared with other methods of cryo preserving materials, a liquid nitrogen freezer offers the most stable freezing environment using ultra-low temperatures. An electric freezer is incapable of maintaining temperatures below -135 C.  

Environmental researchers are interested in cryo preservation to preserve the last stock of endangered species. Rather than lose, say, the critically endangered black rhino species, the rhino's cells can be cryogenically frozen for the future. Coral reefs are also considered desirable candidates for cryo preservation due to their high rates of die-off from ocean acidity. 

Animal breeders are interested in cryo preservation to keep a desired bloodline alive, and fertility specialists see the potential for helping women delay childbirth through cryogenic preservation of fertilized embryos or eggs. 

The cryo preservation industry is not without its challenges. To ensure the viability of the frozen material, the cells must be slowly brought to the -150 C temperature and thawed in the same manner. If the temperature drops too quickly per minute, the cell membrane could rupture, causing cell death. 

Any time liquid nitrogen is used, there is a risk of oxygen displacement should the nitrogen storage tank leak or spill. Nitrogen gas has no color or odor, so employees would not notice that a leak had occurred. 



As nitrogen leaks into the atmosphere, it displaces oxygen. Levels can fall so low that the ambient air will not have enough oxygen for safe respiration. In an oxygen deficient environment, workers can experience respiratory distress, cognitive deficiencies, and death via asphyxiation simply by taking a few breaths in an oxygen deficient environment. 

Any facility that relies on nitrogen freezers to preserve biological material must take safeguards to detect and mitigate nitrogen leaks. One simple, effective solution is an oxygen monitor, such as that offered by PureAire.

How PureAire Can Help 

An oxygen monitor measures the levels of oxygen in the room. As long as there is enough oxygen, the monitor remains silent yet alert. If a spill occurs and levels fall close to the OSHA threshold, the alarm flashes a light and sounds an alarm to notify all personnel there is a leak. Employees can then leave the room before they are harmed by the oxygen deficient air. 

PureAire's oxygen monitor features a robust zirconium sensor, which can take accurate reading without maintenance for 10 or more years. The monitor provides steady readings when barometric pressure changes or thunderstorms occur. The O2 monitor functions accurately in temperature extremes, and is suitable for use in cryogenic facilities and freezers.


If you're interested in a reliable oxygen monitor that's accurate, cost-effective, and fuss-free, you may want to partner with PureAire. Learn more at www.pureairemonitoring.com.

Friday, August 25, 2017

Nitrogen Tank or Cryogenic Dewar? Not Sure Where they are Installed? Here's the List!


Liquid nitrogen is used in a broad range of industries, from steelmaking and pharmaceutical to health care and ceramics. The inert gas is also used in laboratories, breweries, fine cooking, and more. Wherever liquid nitrogen is used, it must be stored securely so as not to mingle with air. Learn why nitrogen must be so carefully contained and where and how N2 gas is stored. 

Bulk Nitrogen Tank Storage 

Liquid nitrogen is stored in a bulk nitrogen tank, also known as a nitrogen dewar. Nitrogen dewars exist wherever nitrogen is used, including in: 
  • Labs
  • Research universities 
  • Restaurants, bars, and hotels 
  • Freezers
  • Hospitals 
  • Flash freezing facilities
  • Food processing facilities
  • Cryotherapy facilities 
  • Manufacturing plants 
The nitrogen dewar features a vacuum stopper, which protects the substance inside and prevents the nitrogen from boiling off. Dewars must have pressure release valves to prevent a bulk nitrogen tank explosion, which can occur when pressure builds up inside the tank. Since liquid nitrogen vaporizes at room temperature, it's critical that the tank stay sealed at all times.

Nitrogen and other insert gases, including argon, displace air when they are released into the environment. As oxygen is displaced, the air becomes oxygen deficient. Breathing oxygen deficient air causes respiratory distress and death via asphyxiation. Since nitrogen is colorless and odorless, there is no way to tell that a leak occurs unless you use an oxygen monitor, which samples oxygen levels. 

Given the risks posed by the material, bulk nitrogen tanks must be stored and transported safely and securely. Workers must bleed out pressure before transporting the tanks, for example, to reduce the risk of incident during transport. 

A robust ventilation system should be installed where the nitrogen is kept, so escaped nitrogen can be vented away, and fresh air should be circulated into the storage room several times per hour. 
Other safety measures include checking that fittings are appropriate, wearing gloves to prevent the nitrogen from burning the skin, and never filling dewars more than 80 percent full. 

While liquid nitrogen can be transferred from the bulk nitrogen tank into a smaller tank for small scale use, it must only be transferred into approved container. If you use the wrong container, it could shatter, leaking nitrogen into the air and decreasing available oxygen. 

Wherever nitrogen is stored or used, signs warning of the risks associated with the material should be posted as a warning to employees. When working with nitrogen, staff should wear eye protection, cryogenic gloves, and other safety equipment. 

Anyone who handles or works with the gas should be trained in safe use, storage, and handling of bulk nitrogen tanks as well. The valves, gauges, and other components of the nitrogen storage tank should be inspected regularly for safety, and replaced whenever you notice wear and tear. 

Why You Need an Oxygen Monitor Where Nitrogen is Stored

By placing an oxygen monitor wherever nitrogen is used, you can protect worker safety and prevent injury or fatality onsite. Oxygen monitors continually sample oxygen levels in the room, making sure that oxygen falls within acceptable levels. Should nitrogen gas leak from the dewar, ambient oxygen levels will start to tumble as the air is displaced by nitrogen. 

When oxygen levels fall to the threshold set by OSHA, which is 19.5 percent, the oxygen deficiency monitor will sound and flash alarms to notify workers onsite. Staff can exit the room before they begin to experience the adverse effects of being in an oxygen deficient atmosphere, then call 911 so emergency personnel can respond to the threat. 

PureAire offers a robust oxygen deficiency monitor capable of withstanding low temperatures of -40 Celsius. Once installed, the oxygen monitor works as intended for 10+ years with no annual maintenance or calibration. An ultra-loud alarm is audible throughout the premises, while a flashing light provides a secondary alert for employees. The unit easily mounts on the wall with brackets and comes with a 3-year warranty. Learn more about oxygen monitors from PureAire at www.pureairemonitoring.com. 
               

Tuesday, August 1, 2017

Oxygen Monitors now Required for Nitrogen, Argon, Helium, and CO2 use in Denver


Oxygen Monitors now Required for Nitrogen, Argon, Helium, and CO2 use in Denver

The Colorado city of Denver recently passed a new law that requires facilities that use insert gas to install oxygen deficiency monitors wherever these gases are used in excess of 100 pounds. Learn what the new law requires from businesses and how an oxygen sensor protects your employees, your business, and your peace of mind. 

What Denver's New Law Requires 

The law specifically applies to Colorado commercial, industrial, or manufacturing facilities that use inert gases, including nitrogen, argon, carbon dioxide, and helium. Facilities covered by the new law include water treatment plants, laboratories, and food processing plants. 
Fire suppression systems and medical gas systems are not covered by the Denver law. 
Under the new law: 
  • Inert gas storage tanks must be placed in approved locations, whether stored inside or outside of the building 
  • Storage containers must be secured to prevent tip-overs
  • All valves and tubing used with the gas system must meet applicable standards
  • Gases must vent outside the building
  • All areas where gas is used must either have an oxygen deficiency monitor or continuous ventilation system, which keeps the oxygen levels in the room steady 
  • Oxygen alarms should be visually inspected daily by trained staff members
  •  Storage tanks, piping, and other parts of the system must be checked on a monthly basis 
  • Tests of the system must be conducted regularly with either air or an inert gas
The Denver law sets out regulations for the type of oxygen deficiency monitor, plus where and how to use them. Acceptable monitors must be installed in any location where an inert gas leak could result in an oxygen deficient environment where public health could be at stake. 
Oxygen detectors must be on an approved device list and directly connected to the electrical supply and fire alarm system for the site. The oxygen detectors must be permanently mounted to the wall at a height which is consistent with the given gas's vapor density, so they can work properly. The devices must be located within their specified ranges of operation, in order to ensure the monitors can work as intended. 

The law prohibits self-zeroing or auto calibrating devices, unless they can be spanned or zeroed to check that the oxygen monitor is working as it should be. All installed oxygen monitors must be calibrated regularly to ensure safe and reliable operation. 

Alongside mounted alarms, companies must place signage that notifies employees of the oxygen monitor and gives instructions for what to do in the event of an alarm. Typical instructions tell staff to leave the building and call 911 if the alarm is going off. 

Signs notifying employees of the risk for oxygen deficiency must be posted anywhere inert gas is stored or used.

To further protect employees, the Denver law mandates that gas be transported, filled, or moved only by qualified individuals who follow protocol. All equipment, including piping systems, must be inspected for competency and the organization must maintain records for a period of three years. 

Why an Oxygen Monitor is a Practical Suggestion 

Oxygen deficient environments occur when an inert gas, such as helium, nitrogen, or argon, escapes into the environment and begins to displace oxygen. Since these gases have no odor or color, there is no way that staff working in the room can tell something is leaking. As the oxygen levels fall, employees can experience confusion and respiratory distress, resulting in death by asphyxiation. 
An oxygen monitor tracks ambient levels of oxygen and sets off an alarm when oxygen levels fall below the safe threshold, thus protecting employee safety. Since employees can both hear and see the alarm, they will know there is a problem even if they are operating loud equipment that overrides the noise of the sensor. 

Oxygen monitors are simple solutions to pressing problems faced by organizations that rely on inert gases and want to mitigate their risk. 

PureAire's oxygen sensors are cost-efficient and high quality. They are designed with a zirconium sensor, which is capable of lasting for as long as 10 years. PureAire's oxygen sensor is accurate in diverse environments, from storage freezers to basements. The sensor functions between -40 and 55 C. While PureAire's oxygen monitors do not need to be calibrated, they are capable of calibration, thus eligible for use in Denver. 

PureAire's monitors need little maintenance to work reliably once they are installed using the included wall-mounting brackets, and they are not affected by changes in the barometric pressure, a known problem with other types of oxygen sensors. PureAire's products can be set to measure oxygen levels of either 18 percent or 19.5 percent (which is the OSHA action level), to comply with standards. 

To learn more about oxygen monitors from PureAire, and view specifications, go to www.pureairemonitoring.com.

Wednesday, June 14, 2017

Storing Liquid Nitrogen in Laboratories: Which Safety Precautions and Sensors Will Protect your Employees?



Liquid nitrogen is frequently used in scientific research, chemistry classes, and even culinary arts nowadays. The substance is safe when properly stored, and as long as everyone follows safety protocols while handling the liquid nitrogen. As part of an environmental health and safety review (EHS review), learn safety considerations regarding storing liquid nitrogen in the lab setting. 

EHS Review: Understand Liquid Nitrogen Risks

Liquid nitrogen is known for its cryogenic properties. It can freeze things incredibly quickly. This property also applies to people, so staff must take safety precautions when handling liquid nitrogen. Even seconds of exposure can damage skin and eye tissue, and may cause frostbite. 
Staff should never transport liquid nitrogen in open containers. They should never reach directly into vats of the substance. 
The main health risk with liquid nitrogen occurs when the liquid vaporizes into gas, which happens if it leaks into the atmosphere. Nitrogen expands in volume when it turns into gas, and depletes oxygen from the air. The gas has no odor or color, so there is no way staff can tell a leak has occurred without an alarm system. If a nitrogen leak occurs, oxygen levels will fall below safe thresholds. This causes severe cognitive and respiratory problems, as well as death by asphyxiation. 
Liquid nitrogen, like other cryogenic liquids, needs a pressure-relief valve during storage. Without such a valve, internal pressure could cause the storage tank to explode. Liquid nitrogen should be stored in a room that has proper ventilation as a precaution around leaks. If a leak occurs, the ventilation system can help shunt gases outdoors, protecting the health of workers. 
How to Protect Your Employees' Environmental Health and Safety With an Oxygen Monitor 

Facilities must install, calibrate, and maintain oxygen sensors to comply with safety policies regarding the storage of liquid nitrogen in the lab setting. These units act as a secondary precaution against the dangers of a nitrogen leak. An oxygen deficiency monitor or O2 sensor measures the levels of oxygen in the environment at all times. These devices provide labs with a cost-effective and reliable way to make sure there are no leaks in nitrogen storage areas. 
For safety precautions, install one oxygen deficiency monitor anywhere liquid nitrogen is stored, handled, or used. These monitors mount to the wall quickly and provide continuous sampling of oxygen levels. As long as there is no leak, and the room contains enough oxygen, the monitors stay silent. If nitrogen leaked it would cause a decline in oxygen levels, eventually triggering an alarm and flashing light. The oxygen monitor would provide enough time for anyone working in the area to vacate the premises and avoid being harmed or killed. 
While there are several styles of O2 sensor on the market, those from PureAire are preferred for their high quality and cost efficiency. PureAire's O2 sensors feature zirconium, which lasts for 10+ years on average with no maintenance and no calibration. Once the monitor in installed, there's nothing more that needs to be done. Since PureAire's oxygen monitors are reliable once installed, and require less maintenance than the competition, they make it easier and cheaper for labs to protect worker safety. Learn more about PureAire's products by visiting www.pureairemonitoring.com.

Monday, May 22, 2017

Titanium Demand on Rise for Additive Manufacturing Printing: How it’s Made? Titanium Plasma Atomization


                                                                                                                                      Link to oxygen sensors
Plasma atomization is used in many applications, including 3D printing. First developed in 1998, this technique has risen to become the industry standard process for creating reactive metal powders suitable for 3D printing. Learn how plasma atomization works and why you need an oxygen monitor to stay safe with plasma atomization. 

How Plasma Atomization Works

Plasma atomization is used not only in 3D printing, but in any circumstance where powder metallurgy is needed. Other uses include spray coating, cold spray, and metal injection molding. 
To pulverize metal, wire is fed through a tube, then hit by three plasma torches capable of reaching temperatures of 10,000 degrees Celsius. As the wire liquefies and melts, individual droplets shear off and fall into a chamber filled with argon gas and cooled by water. When the drops of metal hit the argon, they solidify into spherical droplets. This process produces a fine, uniform metal powder. After the wire has been transformed into droplets, the powder is sieved to ensure uniformity. This is key to the success of the 3D printing process, which relies upon fine grade, uniform powder. 

Titanium (Ti), Nitinol, Niobium, Aluminum, and other reactive metals and their alloys can all successfully be atomized through this process. Variables in the plasma atomization process allow workers to create droplets of different sizes, for different end uses.  

PureAire offers an oxygen analyzer, which many 3D printing manufacturers utilize. This device helps monitor the levels of oxygen in ppm, from 0 to 1000, while the atomization process takes place. 
It's important to keep oxygen levels low while the Ti and other base metals are being turned into powder, as this ensures the purity of the final product. Oxygen analyzers provide a continuous readout of oxygen levels inside the chamber, so your workers can ensure the highest levels of purity at a glance. 

Argon gas is used during plasma atomization because it helps ensure the purity of the powdered metal by reducing the chance for chemical reactions that might happen if oxygen interacted with the metal during the atomization. As long as the argon gas remains in the chamber where the aluminum or titanium powder is being made, plasma atomization is quite safe. Like other inert gases, argon depletes oxygen from the atmosphere. Were the argon gas to leak out of the plasma atomization chamber, employees' wellbeing could be at risk. 

Why You Need an Oxygen Monitor with Plasma Atomization

When argon escapes into the environment, it displaces oxygen molecules. Since the gas is both odorless and colorless, there is no way to detect an argon leak by sight or smell. If there are several atomization stations creating Ti or titanium powder at once, the risk increases exponentially. 
Once oxygen levels begin to drop, worker safety becomes a concern. If oxygen levels fall below the minimum set by OSHA, workers can suffer respiratory and cognitive impairment. Symptoms include dizziness, confusion, fatigue, and shortness of breath. Even a brief exposure to an oxygen deficient environment can prove deadly. 

Fortunately, an oxygen deficiency monitor can continually weigh oxygen present in the room, alerting staff before oxygen levels plunge below the OSHA threshold. This provides sufficient notification via flashing lights and loud alarms for staff to exit the room to safety. 

PureAire offers an oxygen monitor with a zirconium sensor. Unlike other sensors, this lasts with no maintenance and no calibration once the O2 monitor is installed. The O2 monitor and oxygen analyzer, when used together, allow for precise manufacturing of powdered metals with low risk to workers. Businesses prefer PureAire products, which are low-maintenance, cost-effective, and reliable for 10+ years. Visit www.pureairemonitoring.com to learn more about our oxygen analyzers and monitors.