The importance of Gas Detection in the Waste to Energy industry

Waste is composed of materials that are no longer needed, and thus are discarded. Waste can be classified as solid or liquid according to its form, and further categorised as hazardous and non-hazardous waste. Liquid waste includes municipal wastewater, storm water run-off and industrial wastewater discharge.

Solid waste includes household rubbish, which is also called municipal solid waste (MSW), industrial waste – for example, from agriculture – medical and electronics waste.

The treatment of solid waste is challenging because it may contain one of more contaminants (which may include heavy metals, explosive and flammable materials) and these must be dealt with before the waste can be treated.

What are the gas hazards?

There are many processes to turn waste into energy, these include, biogas plants, refuse collection, leachate pool, combustion and heat recovery, exhaust air scrubber and ash pit. All these processes pose gas hazards to those working in these environments.

Within a Biogas Plant, biogas is produced. This is formed when organic materials such as agricultural and food waste are broken down by bacteria in an oxygen-deficient environment. This is a process called anaerobic digestion. When the biogas has been captured, it can be used to produce heat and electricity for engines, microturbines and fuel cells. Clearly, biogas has high methane content as well as substantial hydrogen sulphide (H₂S), and this generates multiple serious gas hazards. (Read our blog for more information on biogas). However, there is an elevated risk of, fire and explosion, confined space hazards, asphyxiation, Oxygen depletion and gas poisoning (H₂S, ammonia (NH₃)). Workers in a biogas plant must have personal gas detectors that detect and monitor flammable gas, oxygen and toxic gases like H₂S and carbon monoxide (CO).

Within a refuse collection it is common to find flammable gas methane (CH₄) and toxic gases H₂S, CO and NH₃. This is because refuse bunkers are built several metres underground and gas detectors are usually mounted high above them, this makes those detectors hard to service and calibrate. In many cases, a sampling system is a practical solution as air samples can be brought to a convenient location and measured.

Leachate is a liquid that drains (leaches) from an area in which waste is collected, with leachate pools presenting a range of gas hazards. These include the risk of flammable gas (explosion risk), H₂S (poison, corrosion), ammonia (poison, corrosion), CO (poison) and adverse oxygen levels (suffocation). Leachate pool and passageways leading to the leachate pool requiring monitoring of CH₄, H₂S, CO, NH₃, oxygen (O₂) and carbon dioxide (CO₂). Various gas detectors should be placed along routes to the leachate pool, with output connected to external control panels.

Combustion and heat recovery requires the detection of O₂ and toxic gases sulphur dioxide (SO₂) and CO. These gases all pose a threat to those who work in boiler house areas.

Another process that is classed as a gas hazard is an exhaust air scrubber. The process is hazardous as the flue gas from incineration is highly toxic. This is because it contains pollutants such as nitrogen dioxide (NO₂), SO₂, hydrogen chloride (HCL) and dioxin. NO₂ and SO₂ are major greenhouse gases, while HCL and dioxides are harmful to human health.

Additionally, ash pits contain toxic gases as well as oxygen monitoring, through both O₂ and CO.

To read more on the waste to energy industry, visit our industry page.

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How do Electrochemical sensors work?

Electrochemical sensors are the most used in diffusion mode in which gas in the ambient environment enters through a hole in the face of the cell. Some instruments use a pump to supply air or gas samples to the sensor. A PTFE membrane is fitted over the hole to prevent water or oils from entering the cell. Sensor ranges and sensitivities can be varied in design by using different size holes. Larger holes provide higher sensitivity and resolution, whereas smaller holes reduce sensitivity and resolution but increase the range.

Benefits

Electrochemical sensors have several benefits.

Can be specific to a particular gas or vapor in the parts-per-million range. However, the degree of selectivity depends on the type of sensor, the target gas and the concentration of gas the sensor is designed to detect.
High repeatability and accuracy rate. Once calibrated to a known concentration, the sensor will provide an accurate reading to a target gas that is repeatable.
Not susceptible to poisoning by other gases, with the presence of other ambient vapours will not shorten or curtail the life of the sensor.
Less expensive than most other gas detection technologies, such as IR or PID technologies. Electrochemical sensors are also more economical.

Issues with cross-sensitivity

Cross-sensitivity occurs when a gas other than the gas being monitored/detected can affect the reading given by an electrochemical sensor. This causes the electrode within the sensor to react even if the target gas is not actually present, or it causes an otherwise inaccurate reading and/or alarm for that gas. Cross-sensitivity may cause several types of inaccurate reading in electrochemical gas detectors. These can be positive (indicating the presence of a gas even though it is not actually there or indicating a level of that gas above its true value), negative (a reduced response to the target gas, suggesting that it is absent when it is present, or a reading that suggests there is a lower concentration of the target gas than there is), or the interfering gas can cause inhibition.

Factors affecting electrochemical sensor life

There are three main factors that affect the sensor life including temperature, exposure to extremely high gas concentrations and humidity. Other factors include sensor electrodes and extreme vibration and mechanical shocks.

Temperature extremes can affect sensor life. The manufacturer will state an operating temperature range for the instrument: typically -30˚C to +50˚C. High quality sensors will, however, be able to withstand temporary excursions beyond these limits. Short (1-2 hours) exposure to 60-65˚C for H2S or CO sensors (for example) is acceptable, but repeated incidents will result in evaporation of the electrolyte and shifts in the baseline (zero) reading and slower response.

Exposure to extremely high gas concentrations can also compromise sensor performance. Electrochemical sensors are typically tested by exposure to as much as ten-times their design limit. Sensors constructed using high quality catalyst material should be able to withstand such exposures without changes to chemistry or long-term performance loss. Sensors with lower catalyst loading may suffer damage.

The most considerable influence on sensor life is humidity. The ideal environmental condition for electrochemical sensors is 20˚Celsius and 60% RH (relative humidity). When the ambient humidity increases beyond 60%RH water will be absorbed into the electrolyte causing dilution. In extreme cases the liquid content can increase by 2-3 times, potentially resulting in leakage from the sensor body, and then through the pins. Below 60%RH water in the electrolyte will begin to de-hydrate. The response time may be significantly extended as the electrolyte or dehydrated. Sensor electrodes can in unusual conditions be poisoned by interfering gases that adsorb onto the catalyst or react with it creating by-products which inhibit the catalyst.

Extreme vibration and mechanical shocks can also harm sensors by fracturing the welds that bond the platinum electrodes, connecting strips (or wires in some sensors) and pins together.

‘Normal’ life expectancy of electrochemical Sensor

Electrochemical sensors for common gases such as carbon monoxide or hydrogen sulphide have an operational life typically stated at 2-3 years. More exotic gas sensor such as hydrogen fluoride may have a life of only 12-18 months. In ideal conditions (stable temperature and humidity in the region of 20˚C and 60%RH) with no incidence of contaminants, electrochemical sensors have been known to operate more than 4000 days (11 years). Periodic exposure to the target gas does not limit the life of these tiny fuel cells: high quality sensors have a large amount of catalyst material and robust conductors which do not become depleted by the reaction.

Products

As electrochemical sensors are more economical, We have a range of portable products and fixed products that use this type of sensor to detect gases.

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

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What is a Pellistor (Catalytic Beads)?

Pellistor sensors consist of two matched wire coils, each embedded in a ceramic bead. Current is passed through the coils, heating the beads to approximately 230˚C. The bead becomes hot from the combustion, resulting in a temperature difference between this active and the other ‘reference’ bead. This causes a difference in resistance, which is measured; the amount of gas present is directly proportional to the resistance change, so gas concentration as a percentage of its lower explosive limit (% LEL*) can be accurately determined. Flammable gas burns on the bead and the additional heat generated produces an increase in coil resistance which is measured by the instrument to indicate gas concentration. Pellistor sensors are widely used throughout industry including on oil rigs, at refineries, and for underground construction purposes such as mines, and tunnels.

Benefits of Pellistor Sensors?

Pellistor sensors are relatively low in cost due to differences in the level of technology in comparison to the more complex technologies like IR sensors, however, they may be required to be replaced more frequently. With a linear output corresponding to the gas concentration, correction factors can be used to calculate the approximate response of pellistors to other flammable gases, which can make pellistors a good choice when there are multiple flammable gases and vapours present.

Factors affecting Pellistor Sensor Life

The two main factors that shorten the sensor life include exposure to high gas concentration and poisoning or inhibition of the sensor. Extreme mechanical shock or vibration can also affect the sensor life.

The capacity of the catalyst surface to oxidise the gas reduces when it has been poisoned or inhibited. Sensor lifetimes of up to ten years is known in some applications where inhibiting or poisoning compounds are not present. Higher power pellistors have larger beads, hence more catalyst, and that greater catalytic activity ensures less vulnerability to poisoning. More porous beads allow easier access of the gas to more catalyst allowing greater catalytic activity from a surface volume instead of just a surface area. Skilled initial design and sophisticated manufacturing processes ensure maximum bead porosity.

Strength of the bead is also of great importance since exposure to high gas concentrations (>100% LEL) may compromise sensor integrity causing cracking. Performance is affected and often offsets in the zero/base-line signal result. Incomplete combustion results in carbon deposits on the bead: the carbon ‘grows’ in the pores and causes mechanical damage or just gets in the way of gas reaching the pellistor. The carbon may however be burned off over time to re-reveal catalytic sites.

Extreme mechanical shock or vibration can in rare cases cause a break in the pellistor coils. This issue is more prevalent on portable rather than fixed-point gas detectors as they are more likely to be dropped, and the pellistors used are lower power (to maximise battery life) and thus use more delicate thinner wire coils.

What happens when a Pellistor is poisoned?

A poisoned pellistor remains electrically operational but may fail to respond to gas as it will not produce an output when exposed to flammable gas. This means a detector would not go into alarm, giving the impression that the environment is safe.

Compounds containing silicon, lead, sulphur, and phosphates at just a few parts per million (ppm) can impair pellistor performance. Therefore, whether it’s something in your general working environment, or something as harmless as cleaning equipment or hand cream, bringing it near to a pellistor could mean you are compromising your sensor’s effectiveness without even realising it.

Why are silicones bad?

Silicones have their virtues, but they may be more common than you first thought. Some examples include sealants, adhesives, lubricants, and thermal and electrical insulation. Silicones, have the ability to poison a sensor on a pellistor at extremely low levels, because they act cumulatively a bit at a time.

Products

Our portable products all use low power portables pellistor beads. This prolongs battery life but can make them prone to poisoning. Which is why we offer alternatives that do not poison, such as the IR and MPS sensors. Our fixed products use a porous high energy fixed pellistor.

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

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Our Partnership with Point Safety

Background

Point safety Ltd is one of the UK’s leading gas safety consultants with 20 years of experience, knowledge and background in the instrumentation industry. Founded in 2011, it specialises in sectors such as oil and gas, pharmaceutical, utilities and telecommunication, providing a range of industries, supplying, installing and maintaining bespoke solutions and the service and supply of test equipment. Point Safety provide constancy to their customers as they believe that there is no such thing as ‘one size fits all’ nor does one solution have to be ‘fit for purpose.

Views on Gas Detection

Portable gas detection is an essential piece of equipment when detecting toxic or explosive gasses and measuring gas concentration. Point Safety puts customers at the forefront of gas detection; they believe that it protects their customers’ plants and processes and, more importantly, helps prevent injury, thereby helping to ensure the health, safety, and wellbeing of its workers.

Through the supply and support of Crowcon, our portable instruments allow Point Safety’s customers to have the freedom to have reliable, efficient service with the confidence and knowledge that the equipment being provided allows for the protection of workers and their employees. Therefore, turnaround is important to Point Safety; ensuring a quick and effective service turnaround for all units is essential, ensuring minimal downtime and increased customer satisfaction.

As Point Safety provide the supply, installation and maintenance of the bespoke solutions, the implementation and servicing of their fixed systems that are provided nationwide are vital to their customers. Point Safety are confident that the continuous monitoring of these systems ensures that our customers’ and their employees’ lives are safe and that of their surroundings.

Working with Crowcon

Through continuous communication of knowledge and expertise with Point Safety, our partnership will allow for the supply of gas detection instruments to ensure the safety of those working within the oil and gas, pharmaceutical, utilities and telecommunication industries. Additionally, as an approved service centre, Point Safety ensures the highest standards in the maintenance and calibration of Crowcon products.

“We have a long-standing relationship with Point Safety, now a trusted partner in the North. Point Safety offers outstanding service to our end-users and is extremely knowledgeable on Crowcon products” – Katherine Winter, Northern Account Manager. Our partnership, Point Safety, allows for the distributors of Crowcon products throughout the UK in portable and fixed gas detectors/systems. Our partnership has also enabled Point Safety to become a Crowcon calibration site, with all its engineers fully trained and certified to Crowcon standards. “Point Safety Ltd are extremely proud to be associated with Crowcon, the leaders in gas detection systems, not only in the UK but worldwide. Their expertise, knowledge, first-class product range, and total support is second to none.” – Dawn Beever, Head of Sales and Marketing.

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The Benefits of ‘Hot Swappable’ Sensors

What are ‘Hot Swappable’ Sensors?

Hot swappable sensors allow for the replacement or addition of components to a device without the need for stopping, shutting down or rebooting the production process, thus allowing for high productivity and efficiency.

Other benefits of ‘Hot swappable’ sensors

Another benefit is that it eliminates the need for hot work permits. Hot work is regularly undertaken during construction and maintenance projects and is a high-risk activity that requires careful and active risk management. These environments pose a significant risk of fire as well as safety. Hot swappable sensors are designed to avoid these potential problems entirely.

Why are they important?

Some gas detection products are designed to go into zoned areas where there can be flammable (explosive) gas present. Therefore, in environments such as a refinery, if you were to disconnect normal electronics, it usually would cause a small spark, and this is a risk as it could potentially lead to a fire or explosion. However, if the electronics have been designed so there is not a spark and have been approved as “not capable of causing an spark” by the certifying authority, these products can be disconnected and reconnected even in an explosive atmosphere without fear of sparking, ensuring that those working in these environments are kept safe.

It is possible to calibrate hot swappable sensors outside a zoned area and thus allow a rapid swapping exercise instead of a far longer calibration process. Thus, the operator need spend only a fraction of the time in the zoned area substantially avoiding personal risk.

Products with ‘Hot Swappable’ Sensors

XgardIQ is a fixed detector and transmitter compatible with Crowcon’s full range of sensor technologies. Available fitted with a variety of sensors for fixed flammable, toxic, oxygen or H2S gas detection. Providing analogue 4-20mA and RS-485 Modbus signals as standard, XgardIQ is optionally available with Alarm and Fault relays and HART communications. The 316 stainless steel is available with three M20 or 1/2“NPT cable entries. (SIL-2) Safety integrity level 2 certified fixed detector.

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Our Partnership with Sure-Safe

Background

Sure-safe is a gas detection specialist based in Hertfordshire. With an internal team of 18, they provide fixed and portable gas detectors and in-house service and calibration to provide suitable gas detection across many sectors, including automotive, transportation, water treatment, CHP plants and universities.

Views on Gas Detection

Gas detectors are essential for safety and analytical purposes, with site surveys and consultations providing tailor-made risk assessments. Sure-Safe work with customers to implement the most appropriate gas detection solution for their needs. Sure-Safe, fully appreciates the importance of ensuring the equipment required for the task is maintained, calibrated and certified.

Working with Crowcon

Sure-Safe and Crowcon have a long-established relationship working together to provide gas detection solutions for over 25 years. “Crowcon is a reliant manufacturer in which our robust relationship has complemented their supply.”

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Connected safety – Gas Safety Insights for Environmental, Health and Safety (EHS)

In most organisations, roles related to environment, health and safety (EHS) focus heavily on risk reduction. There may be compliance responsibilities interwoven with this − EHS staff are often tasked with implementing hazard controls and may be responsible for enforcing and proving compliance – but above all the focus is on making things safer and healthier, and as productive as possible.

In the not-so-distant past, EHS staff in settings with gas hazards were often responsible for ensuring appropriate gas detection and training, and may have manually collated data from gas detectors, but beyond that they had relatively little data to use. It is hard to proactively drive down incidents or be certain how compliant with safety measures your workforce is, when all you know for sure is whether a detector did or did not sound an alarm.

However, the advent of the internet of things (IoT) has changed all that. Now, EHS staff can connect gas detection systems to the cloud just as they connect a fitness tracker or in-car satellite navigation system, and benefit from the many gas insights this provides. Cloud-based software applications like Crowcon Connect make it easy for EHS staff to identify problems with specific devices (and users!), track and schedule maintenance, automate many aspects of compliance audit and trouble-shoot recurrent problems.

What does connected safety mean for EHS personnel?

In a word: data. Connecting gas monitoring systems to the cloud allows EHS personnel to gather actionable insights (data) from their detector fleet, which they can act upon to improve safety. These include the ‘traditional’ elements such as time in/out of use, exposure levels and alarms sounded, but go far beyond these to include information about individuals’ use of the device (for example, the extent to which an individual/group uses the detector correctly) and where devices are at any given time.

With Crowcon Connect, the ability to use quick user assignment allows EHS staff to optimise their data by linking a specific device with a known user, each and every time, regardless of whether the device is assigned to an individual long term or is part of a pool.

What is quick user assignment?

In this context, quick user assignment is the ability to link or associate a specified user with a specified device, in a swift and straightforward way. For example, Crowcon Connect can use the RFID tags in a user’s ID badge to link them to a given device. This has dual benefits: firstly, the EHS staff know that the information on that device relates to a named individual and secondly, they can trust the data because it is collected and archived automatically, with no risk of human error.

How will connected safety work? Who will it work for?

Connected safety works for the entire organisation; when deployed strategically it can increase safety, improve staff morale and provide a wealth of information about productivity, the working environment and compliance. For EHS staff in particular, a good cloud software package for their gas detector fleet maximises and automates the collection of data while reducing the risk of human error in data capture – this is not only vital to ensure safety, but also makes it far easier to collate the records required at any compliance audit, and reduces the burden of manual (error-prone) documentation. And, when devices are pre-assigned to specific workers, the monitoring of compliance becomes both more accurate and straightforward.

Interested in learning more? Click here to read more about Crowcon’s own cloud software solution.

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Our Partnership with Acutest

Background

Acutest have established themselves as a leading player in test instrument supply, repair and calibration, asset management and bespoke training services. Acutest are a complete solution provider who match to each customer’s need. Their team of external account managers support customers with onsite product demonstration as part of the solution identification process. Serving across sectors including utilities (distribution network operators), sole traders, public sector and white goods. Acutest are a trusted partner to many sectors, who have a diverse customer base including the utilities, street works and rail sectors, facilities maintenance teams, manufacturing, processing and industrial plants as well as individual contractors and electricians.

View on Flue Gas Analysers

Providing workers within these sectors with the correct equipment is vital, therefore providing these workers with an essential tool is key at Acutest. This tool is used every day; therefore, Anton by Crowcon flue gas analysers provide an easy-to-use tool that detects CO (Carbon Monoxide) and NO (Nitrogen Oxide).

Working with Crowcon

Acutest have been a long-term partner in which our gas analysers prevent users from having to store, charge, carry, calibrate and transport multiple devices. Our equipment allows Acutest customers to conduct all critical test measurements with just one high performance, innovative solution. “Our partnership with Acutest has enabled them to supply their customers with a readily available, reliable product as well as customer support. Anton by Crowcon provide innovative tools for every engineer needs and has been a go to on many occasions.”

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The importance of Gas Detection in the Marine Industry

Gas detectors for vessels is a device that detects the presence of gases in ships, often as part of a safety system. SOLAS regulations XI- 1/7 requires that vessels have at least one portable gas monitor on board for oxygen and flammable gas detection. This type of equipment is used to detect a gas leak and interface with a control system so a process can be automatically shut down.

Why is gas detection required?

Gas detection equipment measures a gas concentration against a calibration gas which acts as a reference point. Some gas detection monitors only can detect a single gas, some gas detectors can detect several toxic or combustible gases and even combinations within one device.

Marine applications often generate high humidity and dirty conditions. Detection is required from O2 monitoring in cargo room exhausts, to monitoring flammable and toxic gases within various void spaces, to pump room or cabins, fixed systems with sampling are all commonly used in marine settings.

Gas detection is required within the marine industry due to the high temperature surfaces housed in an engine room, as well as the short circuit in the electrical system. Both factors combine with smoking or other domestic sources of fire or a reaction in the cargo, leave ships extremely vulnerable to fires. Gas detection is therefore a vital piece of equipment in protecting the lives of those who work on these vessels. This is key as many seafarers lose their lives every year due to the toxic working environment, they work in. Therefore, detecting such hazards before they become fatal, is essential to contain the damage which can take the form a disaster, meaning gas detection is one of the most important pieces of equipment on a marine vessel.

What are the gas hazards?

There are several different gas hazards, dependant on the vessel type, such as FPSO (floating, production, storage, and offloading), tankers, ferries, submarines, general or cargo tanks.

FPSO and tankers house flammable gases and hydrogen sulphide. Therefore, there is a gas hazard risk of flammable gas leaks within the pump rooms. Gas hazards in confined spaces are another hazard, as there may be inerted tanks or voids, which therefore may be too much or too little oxygen in these confined space environments and where inerting gases are stored. There are also hydrocarbon oxygen risks during the purging of tanks (from %Volume to %LEL (Lower Explosive Limit)).

Carbon monoxide (CO) and nitrous oxide (NOx) are housed on ferries as a result of the accumulation from vehicle exhausts, as both are poisonous gases, they are both gas hazards to be aware of.
Submarines house hydrogen within battery rooms. Along with CO2 leaks from air conditioning systems.
On general vessels, CO and NOx are present engine rooms. Along with hydrogen sulphide (H2S) and O2 being depleted in bilges, that arise from the on-board sewage treatment plant. Vessels that carry food produce, such as grain, will sometimes be at risk of H2S.
Cargo Tanks house vapour emission control systems which are used to analyse waste vapour gas for oxygen gas content. The system includes a pressure transmitter to monitor the pressure on the waste vapour line.

Marine standards

Products installed on any marine vessel must comply with internationally recognized regulations. Therefore, the international standard that applies to a vessel depend upon where it is registered. It is essential that products sold for use on a vessel comply with the standards relevant to the country in which the ship is registered. For example, products fitted to a European-registered vessel undergoing a re-fit in Singapore must comply with the European MED (Marine Equipment Directive) directive.

There are several different standards that comply to different regions:

EU (European Union) countries: MED (Marine Equipment Directive 96/98/EC).
North America: US Coast Guard (USCG) regulations.
Other countries: SOLAS (Safety of Life at Sea) regulations provide the minimum requirements, however individual countries will require compliance with the standards of their chosen marine insurance body (e.g., BV, DNV etc).

Why use detectors?

Gas detectors measure and specify the concentration of specific gases within the air via different technologies.

Gas meters are also used on-board ships to measure the hydrocarbon content, explosion hazard risk, and the oxygen analysers. Under the current guidelines cargo tanks or any enclosed space on-board the ship must be tested to ensure that the space is gas-free along with ample amount of oxygen for any required personnel to work there. These circumstances include; prior to starting any repair work or before loading as quality control.

To find out more, have a look at our Introduction to the Marine Industry or visit our industry page.

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Connected safety – Fleet Health Monitoring for Multi-Site Fleets

As you are no doubt aware, most gas detectors require periodic maintenance and testing, if their owners are to comply with gas safety regulations and keep their workforce safe. As you are also no doubt aware, some organisations have large numbers of gas detectors (often referred to as a fleet or fleets of devices) and keeping track of the maintenance requirements for each and every one of these can be a major headache. If the business operates from multiple sites, and especially if gas monitors move between those sites, this problem is greatly magnified.

What is Fleet Health Monitoring?

Many companies still manage their device fleets manually, using spreadsheets to track the location, status and calibration schedule of each detector. This is repetitive and often tedious work that takes staff away from more productive tasks. Manual management is also, frankly, inefficient. It may just about suffice for basic elements like tracking which device is where (although even that becomes cumbersome when very large numbers are involved). But when managers also need to know which devices are out of battery so cannot be used on the next shift, and which ones are showing signs of wear and tear (and they should know these things) then the data becomes too overwhelming for manual methods to handle.

In these circumstances, it is all too easy for devices to go missing or for somebody to arrive on shift and find that the detector allocated to them is out of battery. The good news is that now, connected safety initiatives such as cloud software applications can remove these problems entirely and make fleet device management much more straightforward and efficient, even across multiple sites.

How does it work and what are the requirements?

Cloud software applications for gas detector fleets, such as Crowcon Connect, automatically transfer and process the gas data from gas detectors, and store it securely in the cloud in useful formats. This data includes not just exposure information, readings and times, but also more detailed information about the way in which devices are used (i.e., the extent of compliance with regulations) and who was using the device at each point (it is very easy to associate a specific user with a specific device in Crowcon Connect, for example, even if that device is part of a fleet or pool).

Crowcon Connect can also be tailored to suit the specific requirements of a business or site, and authorised users can access the dashboard from any location, at any time. All you need is a connected device (including mobile devices; many people use their smartphones or tablets). Access can also be restricted by fleet or team, to maintain privacy where required.

What are the benefits?

Crowcon Connect has a user-friendly dashboard that displays user information, alarm and exposure data, device locations, dates when calibration/maintenance is due, user information and a host of other data, all in an easy-to-use format. It gives managers a panoramic view of the entire fleet, regardless of where each devices is located or has been used, and that information can be used to make safety, compliance and productivity gains and identify areas for improvement.

This type of cloud software can also drive up safety standards, because now managers can see at a glance which devices are out of battery and cannot be used in the next shift, and/or which require maintenance. That maintenance and calibration can also be planned in ways that minimise downtime, because the dashboard lets users see the relevant dates in advance.

What is more, because the data is collected automatically, the risk of human error is eliminated and Crowcon Connect can deliver trustworthy, complete documents that are ready for use in any compliance or safety audit.

Want to find out more? Click here to read more about Crowcon’s own cloud software solution.

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