Our Partnership With Teksal 

Background

Crowcon has been working with Australian-based industrial safety supplier Teksal Safety for more than 10 years, so we thought we’d share some of the ways it helps support our gas detection solutions. 

Founded in 2002, Teksal Safety provides industrial safety solutions for process and pressure safety, machine and automation safety, and operations and maintenance safety applications in industrial, mining, and oil and gas sectors. They work with safety professionals, engineers, plant operators, and maintenance personnel to deliver optimal solutions and minimise risk. Focused on providing industrial safety solutions that help protect people, plant, process, Teksal Safety sources and supplies a range of Crowcon’s portable and fixed gas detectors for diverse applications. 

Views on Gas Detection  

While oil and gas operators and teams working in environments with flammable and toxic gases are exposed to some level of risk, Teksal Safety strives to provide proven industrial safety solutions to help mitigate this risk, including Crowcon’s suite of gas detection products. 

By focusing firstly on awareness of risk, then embedding best practice and innovative solutions, Teksal Safety helps industrial operators provide a safe work environment for their people, and safe ways of working, through its distribution and maintenance of Crowcon gas detection products. 

Teksal Safety’s goal is to “protect people, plant and process. Safety culture often emphasises administrative controls and things like PPE. While these play a key role within a wider HSE programme, we focus on engineered controls to mitigate risk at a high level. While we have solutions that tackle administrative issues that capture residual risk, our main aim is to mitigate the risks further up the chain.” – Joe Hischar, Managing Director.  

Working with Crowcon 

While oil and gas operators and teams working in environments with flammable and toxic gases are exposed to some level of risk, Teksal Safety strives to provide proven industrial safety solutions to help mitigate this risk, including Crowcon’s suite of gas detection products. Our collaboration allows Teksal to source and supply a range of personal gas detectors to meet diverse applications and requirements. “Working on remote sites in Australia can be challenging. As its products are designed with safety in mind, Crowcon allows us to provide proven safety solutions and help protect our customers’ people, plant and process.” – Joe Hischar, Managing Director.  

Did you know about the Sprint Pro Tightness Tester?

Pressure testing is all in a day’s work for many gas engineers, but the right equipment can make all the difference.  

Did you know that you can use the Sprint Pro flue gas analyser to carry out tightness testing, with no need for additional U gauges or other bulky equipment? In this post we’ll explore how and why you can tightness test with the Sprint Pro. 

What is tightness testing? 

Tightness testing is a type of pressure test, applied to a gas supply system at the meter. Other forms of pressure testing include the let-by test (which checks for leaks in the emergency control valve [ECV]), temperature stabilisation test, standing pressure at the meter test (a measurement of the gas when it’s stationary), and working/operating pressure at the meter test (which assesses the flow and pressure of gas when appliances are being used). 

Tightness testing measures the pressure in gas pipes, in order to find evidence of leaks. A tightness test is generally carried out after a let-by test and temperature stabilisation test. The tightness test is sometimes followed by a purge and then a standing pressure test, followed by a working/operating pressure at the meter test. This allows the engineer to make a full assessment of the system.  

Using the Sprint Pro to conduct a tightness test 

All Sprint Pro models except the Sprint Pro 1 can be used to tightness test. To begin, go into the pressure menu and select let-by/tightness. You will need to attach the pipe and matching pressure relief valve to the Sprint Pro’s positive pressure inlet – the valve makes setting the desired pressure, and adjusting it if required, very easy.  

As you scroll through the Sprint Pro’s pressure menu, you’ll find that tightness testing follows let-by testing and temperature stabilisation. Full instructions for tightness testing are given in the Sprint Pro manual (click here for a PDF version).  

It is very important to note that the parameters for tightness testing, and any increases/drops in pressure that are permitted, depend on many variables, such as the age and size of the pipework, whether appliances are attached and several others. Ultimately, you as the engineer must decide whether to pass or fail the tightness test when the analyser displays the results. 

Once the test is completed, you can either print the results immediately (although this erases them from the system) or save them to the log (and they can always be printed from there). Alternatively, if you have the Sprint Mobile/Crowcon HVAC Companion app, you can Bluetooth directly to your tablet or smartphone. 

Why use a Sprint Pro for tightness testing? 

Using a Sprint Pro for pressure testing means less to carry around (no bulky water gauges, for example) and the clarity of results displayed digitally. The Sprint Pro also creates an audit trail in the form of digital logs, which can provide great peace of mind in case of any dispute or query.

Our Partnership with Pass Ltd 

Background  

Founded in early 2001 and based in Stockton-On-Tees, PASS Ltd is a leading supplier of test equipment, training, and calibration. Built on delivering an exceptional customer experience, they have grown to offer one of the most comprehensive catalogues of test and measurement, thermal imaging, and industrial safety products, as well as a broad calibration scope. In 2014, their calibration and repair laboratories gained UKAS accreditation. PASS Ltd pride themselves on offering a fast, affordable service; therefore, they have developed an online asset management portal for larger businesses to provide 24/7 access to asset details and service tracking. Additionally, as an accredited training provider specialising in low and high voltage courses, PASS Ltd offers an ever-expanding range of classes including City & Guilds and MCA accredited programmes.   

Views on HVAC 

PASS Ltd understand that confined spaces can be extremely dangerous and this is what makes these areas such a cause for global concern. They acknowledge that not all confined spaces are fully enclosed but point out that these locations may still pose a significant risk due to hazardous substances or conditions within or nearby the space, for example, a lack of oxygen. It is therefore critical to provide education and training on dangerous gases and environments to those working in the HVAC industry.    

Working with Crowcon  

PASS Ltd have been a long-term partner of Crowcon. For over seven years our partnership has enabled new areas of growth within the HVAC and portables industries. PASS Ltd attest that “our partnership has allowed us to supply a range of gas detection products and services that are reliable and diverse, improving the safety of our customers working within the Gas, HVAC, and Plumbing sectors. Crowcon’s quality and values align well with PASS’ ethos; they are the perfect partner to support our mission of raising end-users’ and businesses’ awareness of gas exposure.” 

International Women in Engineering Day  

The Building Engineering Services Association (BESA) has announced that the number of women moving into engineering professions is increasing and with it bringing ‘crucial’ skills needed to tackle major challenges. Women now make up 16.5% of the UK’s engineering workforce compared to just 10.5% in 2010. The number of women working in engineering roles has risen to 936,000 from 562,000, according to research carried out by EngineeringUK. On a global scale, women make up only 28% of all engineering graduates. 

For International Women in Engineering Day this year we have asked a member of our Research and Development (R&D), Trainee Software Engineer, Neha Singh from our team in India to tell us about her role here at Crowcon and her views on the importance of encouraging more women to get into engineering. 

When did you realise you wanted to get into engineering? 

In my childhood, I used to read in newspapers about people clearing engineering exams and getting into it, and that inspired me a lot, and became my dream. Since then, I have always wanted to be an engineer. 

Tell us about what you do. What does your day-to-day look like? 

I am a software engineer at Crowcon, and I have been working at the company for more than 3 years. I work on software development. A typical day at work involves solving problems, developing new features, and learning new technologies. 

What’s the most difficult part of your job? 

There’s no “difficult” part as such, solving complicated tasks has both ups and downs. If we solve it, we learn, and even if can’t solve, we learn, and that’s the best thing. 

What do you like most about your job? 

The best part is being able to solve the many challenges that come in the way of a project that I’m working on. This is through the digitalisation of our portable products. 

Was it difficult for you, (especially as a woman), to get into engineering? 

No, it wasn’t. I was fortunate to being supported by my wonderful parents, who always stood by me and helped me in achieving what I wanted to become. 

Women now make up 16.5% of the UK’s engineering workforce compared to just 10.5% in 2010. On a global scale, women make up only 28% of all engineering graduates. Why is it important for women to pursue careers in engineering? 

Women are doing good in all aspects of life, and it’s good to see more and more women joining science and engineering, and I am confident that this number is going to increase a lot in years to come. 

What advice do you have for women students who are considering the profession or women currently working in engineering? 

You are awesome, keep rising and keep up the good work! 

The Benefits of MPS Sensors 

Developed by NevadaNano, Molecular Property Spectrometer™ (MPS™) sensors represent the new generation of flammable gas detectors. MPS™ can quickly detect over 15 characterised flammable gases at once. Until recently, anyone who needed to monitor flammable gases had to select either a traditional flammable gas detector containing a pellistor sensor calibrated for a specific gas, or containing an infra-red (IR) sensor which also varies in output according to the flammable gas being measured, and hence needs to be calibrated for each gas. While these remain beneficial solutions, they are not always ideal. For example, both sensor types require regular calibration and the catalytic pellistor sensors also need frequent bump testing to ensure they have not been damaged by contaminants (known as ‘sensor poisoning’ agents) or by harsh conditions. In some environments, sensors must frequently be changed, which is costly in terms of both money and downtime, or product availability. IR technology cannot detect hydrogen – which has no IR signature, and both IR and pellistor detectors sometimes incidentally detect other (i.e., non-calibrated) gases, giving inaccurate readings that may trigger false alarms or concern operators. 

The MPS™ sensor delivers key features that provide real world tangible benefits to operator and hence workers. These include: 

No calibration  

When implementing a system containing a fixed head detector, it is common practice to service on a recommended schedule defined by manufacturer. This entails ongoing regular costs as well potentially disrupting production or process in order service or even gain access to detector or multiple detectors. There may also be a risk to personnel when detectors are mounted in particularly hazardous environments. Interaction with an MPS sensor is less stringent because there are no unrevealed failure modes, provided air is present. It would be wrong to say there is no calibration requirement. One factory calibration, followed by a gas test when commissioning is sufficient, because there is an internal automated calibration being performed every 2 seconds throughout the working life of the sensor. What is really meant is – no customer calibration. 

The Xgard Bright with MPS™ sensor technology does not require calibration. This in turn reduces the interaction with the detector resulting in a lower total cost of ownership over the sensor life cycle and reduced risk to personnel and production output to complete regular maintenance. It is still advisable to check the cleanliness of the gas detector from time to time, since gas can’t get through thick build ups of obstructive material and wouldn’t then reach the sensor. 

Multi species gas – ‘True LEL’™  

Many industries and applications use or have as a by-product multiple gases within the same environment. This can be challenging for traditional sensor technology which can detect only a single gas that they were calibrated for at the correct level and can result in inaccurate reading and even false alarms which can halt process or production if another flammable gas type is present. The lack of response or over response frequently faced in multi gas environments can be frustrating and counterproductive compromising safety of best user practices. The MPS™ sensor can accurately detect multiple gases at once and instantly identify gas type. Additionally, the MPS™ sensor has a on board environmental compensation and does not require an externally applied correctional factor. Inaccurate readings and false alarms are a thing of the past.  

No sensor poisoning  

In certain environments traditional sensor types can be under risk of poisoning. Extreme pressure, temperature, and humidity all have the potential to damage sensors whist environmental toxins and contaminants can ‘poison’ sensors, leading to severely compromised performance. Detectors in environments where poisons or inhibitors may be encountered, regular and frequent testing is the only way to ensure that performance is not being degraded. Sensor failure due to poisoning can be a costly experience. The technology in the MPS™ sensor is not affected by contaminates in the environment. Processes that have contaminates now have access to a solution that operates reliably with fail safe design to alert operator to offer a peace of mind for personnel and assets located in hazardous environment. Additionally, the MPS sensor is not harmed by elevated flammable gas concentrations, which may cause cracking in conventional catalytic sensor types for example. The MPS sensor carries on working. 

Hydrogen (H2)

The usage of Hydrogen in industrial processes is increasing as the focus to find a cleaner alternative to natural gas usage. Detection of Hydrogen is currently restricted to pellistor, metal oxide semiconductor, electrochemical and less accurate thermal conductivity sensor technology due to Infra-Red sensors inability to detect Hydrogen. When faced with challenges highlighted above in poisoning or false alarms, the current solution can leave operator with frequent bump testing and servicing in addition to false alarm challenges. The MPS™ sensor provides a far better solution for Hydrogen detection, removing the challenges faced with traditional sensor technology. A long-life, relatively fast responding hydrogen sensor that does not require calibration throughout the life cycle of the sensor, without the risk of poisoning or false alarms, can significantly save on total cost of ownership and reduces interaction with unit resulting in peace of mind and reduced risk for operators leveraging MPS™ technology. All of this is possible thanks to MPS™ technology, which is the biggest breakthrough in gas detection for several decades. The Gasman with MPS is hydrogen (H2) ready. A single MPS sensor accurately detects hydrogen and common hydrocarbons in a fail-safe, poison-resistant solution without recalibration.

For more on Crowcon, visit https://www.crowcon.com or for more on MPSTM visit https://www.crowcon.com/mpsinfixed/  

Clean Air Day 2022

This year’s Clean Air Day is taking place today, Thursday 16th June 2022.

Now in it’s sixth year, Clean Air Day is organised by the Global Action Plan charity and is the UK’s largest air pollution campaign, with the goal of bringing together businesses, the health sector, communities and schools to raise awareness of air pollution and find practical solutions to this global issue.

This year’s theme is based around the impact of air pollution on health, with the tagline “Air pollution dirties every organ in your body. Take steps to improve your health this Clean Air Day.”

Air pollution is considered by many to be the world’s largest environmental health threat and it is easy to see why. All of the most common air pollutants, including nitrous and sulphur oxides and particulate matter, can have a severe impact on our physical health.

These harmful pollutants can have a wide range of effects from coughing and breathing difficulties to reduced lung function, heart and lung disease as well as dementia and strokes. Exposure to air pollution can also aggravate pre-existing conditions such as asthma. Studies have shown that long-term exposure to air pollution reduces life expectancy, largely due to respiratory and cardiovascular diseases and lung cancer. Whilst the more vulnerable members of our community are at increased risk of these harmful effects, air pollution has the capacity to harm all of us. Public Health England estimates that long-term exposure to air pollution has an effect which is equivalent to 28,000 – 36,000 deaths annually, clearly showing the need for action.

This year, the Clean Air Day campaign is promoting three key actions:

  • Talking to someone about the harms of air pollution
  • Walking those short distance trips and leaving the car at home, where you can
  • Asking local and national decision makers for what would make it easier for you to walk more and have clean air in your community.

These are three things everyone can do to make a difference this Clean Air Day.

Education is a key part of Clean Air Day and Global Action Plan’s Clean Air Hub is great place to increase your understanding of air pollution, as well as the Clean Air Calculator to see how you can reduce your personal contribution air pollution. Further educational resources are also available from Public Health England and the Department for Environment Food & Rural Affairs.

A great way to take part in Clean Air Day is to make a pledge to take action such as walking or cycling to work or school on the day, pledge cards are available on the Clean Air Day website and you are encouraged to share your pledge on social media using the hashtag #CleanAirDay.

Following the recent launch of our air quality solution, we are excited to be involved in this day of awareness, keep an eye on our social channels for more content throughout the day!

Carbon Dioxide: What are the dangers in the Food and Beverage Industry? 

Almost all industries must monitor gas hazards, with the food and beverage industry no exception. Although, there is a lack of awareness regarding the dangers of carbon dioxide (CO2) and the dangers those working in the industry face. CO2 is the most common gas in the food and beverage industry because it is used in the carbonation of drinks, to propel beverages to the tap in pubs and restaurants and to keep food items cold during transportation in the form of dry ice. It is also naturally produced in beverage manufacturing processes by leavening agents like yeast and sugar. Although CO2 may seem harmless at first glance as we exhale it with every breath, and plants need it for survival, the presence of carbon dioxide becomes a problem when its concentration rises to dangerous levels.

The Dangers of CO2

Carbon dioxide occurs naturally in the atmosphere (typically 0.04% in air). CO2 is colourless and odourless, heavier than air, and tends to sink to the floor. CO2 collects in cellars and at the bottom of containers and confined spaces such as tanks or silos.

Since CO2 is heavier than air, it quickly displaces oxygen at high concentrations can result in asphyxiation due to a lack of oxygen or breathable air. Exposure to CO2 is easy, especially in a confined space like a tank or a cellar. Early symptoms of exposure to high levels of carbon dioxide include dizziness, headaches, and confusion, followed by loss of consciousness. Accidents and fatalities occur in the food and beverage industry due to a carbon dioxide leak. Without proper detection methods and processes in place, everyone at a facility could be at risk.

Gas Monitors – what are the benefits?

Any application that uses carbon dioxide puts workers at risk, and the only way to identify high levels before it’s too late is to use gas monitors.

Gas detection can be provided in both fixed and portable forms. Installation of a fixed gas detector can benefit a larger space such as plant rooms to provide continuous area and staff protection 24 hours a day. However, a portable detector can be more suited for worker safety in and around the cylinder storage area and in spaces designated as a confined space. This is especially true for pubs and beverage dispensing outlets for the safety of workers and those unfamiliar with the environment, such as delivery drivers, sales teams or equipment technicians. The portable unit can easily be clipped to clothing and will detect pockets of CO2 using alarms and visual signals, indicating that the user should immediately vacate the area.

Personal gas detectors continuously monitor the air in workers’ breathing zone when worn correctly,  to give them better awareness and the information they need to make smart decisions in the face of danger. Not only can gas monitors detect carbon dioxide in the air, but they can also alert others if an employee is in danger. Carbon dioxide can be monitored using a single gas monitor or by using a multi-gas monitor with a dedicated carbon dioxide sensor. It is important to note the carbon dioxide can escalate to dangerous levels before an oxygen sensor would alarm.

What is IR Technology? 

Infrared emitters within the sensor each generate beams of IR light. Each beam is measured by a photo-receiver. The “measuring” beam, with a frequency of around 3.3μm, is absorbed by hydrocarbon gas molecules, so the beam intensity is reduced if there is an appropriate concentration of a gas with C-H bonds present. The “reference” beam (around 3.0μm) is not absorbed by gas, so arrives at the receiver at full strength. The %LEL of gas present is determined by the ratio of the beams measured by the photo-receiver. 

Benefits of IR technology 

IR sensors are reliable in some environments that can cause pellistor-based sensors to function incorrectly or in some cases fail. In some industrial environments, pellistors are at risk of being poisoned or inhibited. This would leave a worker on their shift unprotected. IR sensors are not susceptible to the catalyst poisons so significantly enhance safety in these conditions. 

Pellistor technology is considerably less expensive than IR technology, reflecting the comparative simplicity of the detection technology. However, there are several advantages of IR over pellistors. These include IR technology provides fail-safe testing. The mode of operation means that if the infrared beam failed, this would register as a fault.  In normal pellistor operation, conversely, a lack of output is ordinarily an indication that no flammable gas is present, but this could also be the result of a fault. Pellistors are susceptible to poisoning or inhibition; a particular concern in environments where compounds containing silicon, lead, sulphur and phosphates, even at low levels. IR instruments don’t, themselves, interact with the gas.  Only the IR beam interacts with the gas molecules, so, IR technology is immune to poisoning or inhibition by chemical toxins. In high concentrations of flammable gas, pellistor sensors can burn out. As with poisoning or inhibition, this would probably only be picked up by testing.  Again, IR sensors are not affected by these conditions. Low levels of oxygen mean that pellistor sensors won’t work. This can be the case in recently purged tanks, but also in confined spaces generally, where pellistors may be ineffective.  IR technology is effective in areas where oxygen may be reduced or absent. 

Factors that affect IR technology  

Exposure to high levels of flammable gas can cause “sooting” of pellistors, reducing their sensitivity and potentially leading to failure. Pellistors require oxygen to function, however, IR sensors can be relied on in applications such as fuel storage tanks where there is little or no oxygen, due to flushing with inert gas prior to maintenance, or which still contain high levels of fuel vapours. The fail-safe nature of IR sensors, which automatically alert you to any fault, provides an additional layer of safety. Gas-Pro IR measures in %LEL and has been certified for use in hazardous areas as defined by both ATEX/IECEx and UL. 

Knowing when the technology has failed  

IR sensors are reliable in environments that can cause pellistor-based sensors to function incorrectly or in some cases fail. In some industrial environments, pellistors are at risk of being poisoned or inhibited. This leaves workers on their shifts unprotected. IR sensors are not susceptible to these conditions, so significantly enhance safety. 

Problems with IR sensors 

IR sensors do not measure hydrogen, and they usually don’t measure acetylene, ammonia of some complex solvents either except for some specialist sensor types. 

If nothing is done to prevent it, moisture can build up inside IR sensors on the optics scattering the IR light and causing a fault.  

The fail-safe nature of IR sensors, which automatically alert you to any fault, provides an additional layer of safety, and this results in a fault if there isn’t enough light getting through the system e.g., if the light is being scattered form the beam. 

IR sensors have very high resistance to interference or inhibition by other gases and are suitable for both high gas concentrations and use in inert (oxygen free) backgrounds where catalytic pellistor sensors would perform poorly. 

Products  

Our portable products such as Our Gas-Pro IR and Triple Plus+ help customers to detect potentially explosive gases where traditional, “pellistor,” catalytic sensors will struggle – especially in low oxygen or ‘poisoning’ environments. And allow for the measurement of hydrocarbons at both % LEL and % Volume ranges making this instrument ideal for tank and line purging applications. 

To explore more, visit our technical page for more information. 

Intrinsic Safety – What does it mean? 

Intrinsic safety is an explosion prevention technique used to ensure safe operation of electrical equipment in a hazardous area. This technique uses a low-energy signalling technique that reduces the energy within the equipment to below that required to initiate an explosion, whilst maintaining an energy level this is an be used for its operation.  

What is a hazardous area? 

A hazardous or explosion-prone relates to an environment that has vast amounts of flammable substances such as combustible particles, gases, vapor. Hazardous industrial areas include oil refineries, mining, distilleries and chemical plants. The main safety issue in these industrial scenarios is that of flammable vapours and gases. This is because when they are mix with oxygen within the air, they can establish an explosion-prone environment. Food processing factories, grain handling facilities, recycling operations, and even flour mills generate combustible dust, which is why these are classed as too hazardous locations. Hazardous places are classified in terms of zones on the basis of the frequency and duration of the occurrence of an explosive atmosphere. Areas subject to flammable gas hazards are classified as either Zone 0, Zone 1 or Zone 2. 

How does it work? 

Intrinsic safety prevents sparks and heat from being generated from any electrical equipment, devices or instruments that otherwise ay have initiated an explosion in a hazardous area. Hazardous spaces may belong, but are not limited to, to the following: petrochemical refineries, mines, agriculture grain storage, wastewater, distilling, pharmaceutical, brewing, and utilities. 

Intrinsic safety is achieved with the use of a Zener Diodes which limits voltage, resistors that limit the current and a fuse to cut off electricity. Equipment or devices that may be made intrinsically safe must first be approved for use in an intrinsically safe system through a competent authority, such as the National Fire Protection Agency (NFPA), the Canadian Standards Association (CSA), Underwriters Laboratories (UL), Factory Mutual (FM), National Electric Code (NEC), and the Instrument Society of Measurement and Control (ISA). 

The advantages of Intrinsic Safety 

The main advantage is that it provides a solution to all problems that occur in a hazardous area regarding equipment. It prevents the cost and bulk of explosion proof enclosures, with additional cost savings as a result of the ability to use standard instrumentation cables. Additionally, the maintenance and diagnostic work can be performed without shutting down production and ventilating the work area. 

Levels of protection  

Intrinsic safety relates to three levels of protection, ‘ia’, ‘ib’ and ‘ic’ that aim to balance the probability of an explosive atmosphere, assessing the probability of whether that is an ignition capable situation that may occur. 

‘ia’  

Offers the highest level of protection and any equipment that is given this level is generally considered adequately safe for use in the most hazardous locations (Zone 0) with two faults.  

‘ib’  

This level is considered adequately safe with one fault is considered safe for use in less frequently hazardous areas (Zone 1).  

‘ic’  

This level is given for ‘normal operation’ with a unity factor of safety is generally acceptable in infrequently hazardous areas (Zone 2). 

Level of protection 
Countable faults 
ATEX Category 
Normal Zone of use 
ia 2 1 0
ib 1 2 1
ic 0 3 2

 

To note, although it is normal for a whole system to be allocated a level of protection, it is also possible for different parts of the system to have different levels of protection.  

World Hydrogen Summit 2022

Crowcon exhibited at the World Hydrogen Summit & Exhibition 2022 on the 9th – 11th May 2022 as part of the event designed to advance development in the hydrogen sector. Based in Rotterdam and produced by the Sustainable Energy Council (SEC), this year’s exhibition was the first Crowcon has attended. We were excited to be part of an occasion which fosters connections and collaboration between those at the forefront of the heavy industry and drives the hydrogen sector forward.

Our team representatives met various industry peers and showcased our Hydrogen solutions for gas detection. Our MPS sensor offers a higher standard of flammable gas detection thanks to its pioneering advanced molecular property spectrometer (MPS™) technology that can detect and accurately identify over 15 different flammable gases. This showcased an ideal solution for hydrogen detection due to hydrogen having proprieties that allow for easy ignition and higher burn intensity compared to that of petrol or diesel, therefore poses a real explosion risk. To find out more read our blog.

Our MPS technology had interest due to this not requiring calibration throughout the life cycle of the sensor, and detects flammable gases without the risk of poisoning or false alarms, thereby having a significant saving on total cost of ownership and reduce interaction with units, ultimately providing peace of mind and less risk for operators.

The Summit allowed us to understand the current state of the hydrogen market, including key players and current projects, allowing for potential developed a greater understanding of our product needs in order to play a major role in the future of hydrogen gas detection.

We look forward to attending next year!