gas display screens free sample

Gas stations get very busy, deliver timely messages to gas station patrons while they fuel-up with customer-centric digital signage at the pump. Upsell and cross-sell various fuel additives as well as food items from inside. The dwell time is short, but the ability to provide impactful messages should be incentive enough to install yours at the pump.

Hashtags are the new norm when connecting your gas station customers. Whether they’re talking about prices or deals, the content will be displayed on your signage. Although the visit to the station itself may be short, the conversation in comparing gas prices is one that will go on continuously on Facebook, Twitter and other social media outlets can now be showcased on your network. You will have more control over the conversation, ensuring you maintain brand equity.

Whether the current specials are referring to your gas rates or other items within the adjacent convenient store--such as snacks or sodas--you will want to give customers the updated prices in real-time on your digital signage display. One of the best ways to do this is to position the sign in a conspicuous place like the lobby, or in a position where they can see the screen while they pump gas.

There are many times when your gas stations’ customer service reps will get asked for directions by people passing through. One of the best features of digital signs is the fact that you can display all types of information. You can easily change the display to show current weather conditions in your city and its surrounding areas, and/or put up a map with popular city landmarks on the screen(s).

Gas station signage is quite effective in directing consumer attention. Over the years, several gas outlets have embraced digital signage. Thanks to the ease of drawing attention to any product or service within a business facility. It also engages the customers more profoundly than the traditional signs. Hence it’s best used to convey sensitive messages, for example, warn customers of smoking around the gas station.

If you are interested in deploying digital signage in your gas station, you’ve come to the right place. We’ve covered all you need to know about gas station signage.

The gasoline business is one of the most competitive industries today. And to win over customers, you need a great marketing strategy. Gas station signs give you a means to stand out from your competitors.

Your business visibility is not worth much if it doesn’t leave a positive impression. Superior customer service begins with attracting the customer, then giving them the reason to buy from you. A well-designed gas station signage gives you both – it attracts and retains your customers.

Nothing disappoints customers more than having to guess the location of a gas station, especially when they are running out of gas. Visible, well-placed signage will spare them the frustration. Digital signage has worked well in the garage and car wash businesses, and the fuel industry is no exception.

To make your signage more accessible, put the signage as close to the highway as possible. Also, consider having yourofficial site(website and physical location) as well as your address on GPS and list your gas station withGoogle My Business.

Nearly all the gas stations have a fast-food restaurant and one or more grocery stores (C-stores). Here, you can use the signage to run promotions and draw more customers to the business. The idea is to meet the expectations of your hungry customers and get them to visit next time.

Also, gas stations that offer more than just pump fuel are more convenient for long-distance travelers. Having a food market around is excellent, and promoting it with signage is an added advantage.

According to aCisco IBSG study, more than 40% of shoppers admit that digital displays can change their spending behavior. This means you can leverage signs to ensure customers have the best experience when they stop by your gas pumps.

But to achieve this, you need to know what works in every single location in your gas station. Here is how you can use the best signage solutions in your gas station.

Before automobiles became a necessity for most people, gas stations were few, and there was no need for intense marketing. Nowadays, gas station owners need to market their brand to stay competitive.

Others include tin signs and vintage gas station signs used to display gasoline name brands. When choosing signage for these purposes, it’s best to find one that’s flexible and customizable. For example, gas price flip signs that allow you to change the prices easily.

There are several reasons you would want to use this type of signage. For example, warn everyone coming into the gas station to avoid ignition sources that could cause a fire. Other examples include:An “authorized personnel only” sign keeps unauthorized persons away from oil reserves or protected areas.

Your customers looking to access the washrooms or the c-stores will appreciate well-labeled signage. To ensure you are offering superior customer service, have wayfinding signs throughout the gas stations. Even the simple “Entry” and “Exit” signs will guide new customers. This helps avoid confusion and unnecessary traffic.

The best place to start is by identifying the number of businesses you are running within the premises. What follows is to map those spots that need a decent display. That is, to either stimulate conversion, pass a message or help with wayfinding. Here, you can work with in-house designers to ensure success.

It’s worth noting that the best sign package for your gas business needs a professional design. This is where you need to proceed with caution. Building material details, such as the make and even dimensions, play a critical role.

Oxygen deprivation is a silent killer. Oxygen-depleting gases, such as nitrogen, argon, and helium, are odorless and colorless, making leaks impossible to detect, unless appropriate monitoring is in place.

In contrast, other gas detection companies use depleting, electrochemical sensors. These sensors, because they are depleting, operate for 1-2 years before needing to be replaced. Electrochemical sensors do not offer long-term solutions to companies committed to safety.

Electrochemical sensors offered by other gas detection companies lose accuracy over time and must be calibrated. Calibration recharges and resets the monitor to get an accurate reading. It is important to note that an electrochemical sensor can only be calibrated a finite number of times before it must be discarded.

The oxygen monitor covers an area of approximately 692 square feet when mounted on a wall and should be placed no more than 21 feet from potential leak sources such as gas lines, gas cylinders, or any areas where a gas leak might be expected to occur.

To ensure safety, the maximum distance between two monitors mounted to the same wall, should not exceed 30 feet. However, since cryogenic gases, such as argon, helium, and nitrogen, are unpredictable, we encourage you to contact PureAire for additional guidance specific to your needs.

In most circumstances, PureAire recommends that oxygen monitors be installed 3-5 feet away from gas cylinders or cryogenic gas lines. To enable employees to see the monitor display and verify its performance, PureAire recommends mounting an oxygen monitor 3-5 feet off the ground.

The information in this Safety and Health Information Bulletin (SHIB) provides workers and employers guidance on calibrating and testing direct-reading portable gas monitors (hereafter, "DRPGMs" or "instruments"). These instruments protect workers from unseen workplace gas hazards. Proper maintenance and calibration of the instruments ensures their accuracy in detecting worker exposure to harmful gases in the workplace. Follow the manufacturer"s recommendations with regard to calibrating the instruments.

DRPGMs are designed to alert workers to toxic gases, as well as oxygen-deficient and combustible atmospheres that may exist in their workplace environments, such as permit-required confined spaces, manholes, and other enclosed spaces. Several OSHA standards require the use of gas monitors. See paragraph (c)(5)(ii)(C) of 29 CFR 1910.146 (Permit-required confined spaces); paragraph (c)(6) of 29 CFR 1910.120 (Hazardous waste operations and emergency response); and section 5 (Entry into bins, silos, and tanks) of Appendix A of 29 CFR 1910.272 (Grain handling facilities). OSHA recommends developing standard procedures for calibrating and using DRPGMs that include documentation to verify the proper maintenance and calibration of the instruments.

Instrument inaccuracy due to improper or irregular maintenance and calibration can lead to exposure to hazardous levels of toxic gases or to an oxygen-deficient atmosphere. This exposure can cause workers to suffer serious injuries or illness, and even death. Flammable gas explosions are often catastrophic, resulting in worker injuries and death, or destruction of property.

The best way to verify that a DRPGM detects gas accurately and reliably is to test it with a known concentration of gas. This procedure will verify whether the sensors in the instrument respond accurately and whether the alarms function properly.

Operators use DRPGMs to detect the presence and concentration of toxic and combustible gases, as well as oxygen deficiency or oxygen enrichment (which is a fire and explosion hazard). Workers must not rely solely on their sense of smell to alert them to these hazards. Employers should ensure that workers use these instruments when working in areas with potential hazardous atmospheres.

"Calibration" refers to an instrument"s measuring accuracy relative to a known traceable concentration of test gas. DRPGMs compare the sensor"s response to a known concentration of the test gas. To confirm the validity of this comparison, it is important to ensure the calibration gas has not expired (always check the expiration date of the gas before usage). The instrument"s response to the calibration gas serves as the reference point.

When an instrument"s reference point shifts, the reading will shift accordingly and be unreliable. This is called "calibration drift," and it happens to all sensors over time. An instrument that experiences calibration drift can still measure the quantity of gas present, but it cannot convert this information into an accurate numerical reading. Calibration checks or full calibration2 with a traceable gas concentration will verify or update the instrument"s reference point. Operators should conduct these procedures daily, or more frequently if needed, to ensure that the instrument will continue to produce accurate readings. Calibration drift occurs most often because of:

Operators should validate a DRPGM"s operability when any of these conditions occurs, or is suspected, during use. When attempting to calibrate an instrument after exposure to these conditions, the sensor often will either display a failure message or will not allow the operator to fully adjust the display reading. Harsh operating and storage conditions can affect instrument performance, leading to inaccurate readings or even failure. While a DRPGM may appear undamaged during visual inspection, it actually could be damaged internally. At this point, the operator should replace the damaged sensor or have qualified personnel service the sensor. Be sure to follow the manufacturer"s instructions regarding sensor replacement and servicing.

The primary reason for proper, regular instrument calibration is to provide accurate gas-concentration readings that could prevent worker illness, injury, or death. Correctly calibrating an instrument helps to ensure that the DRPGM will respond accurately to the gases it is designed to detect, thereby warning users of hazardous conditions before the conditions reach dangerous levels. Some DRPGMs have two levels of alarms – warning and danger. The warning alarm alerts the operator and workers that the work environment has a detectable elevated concentration of toxic gas and is, therefore, potentially hazardous. The danger alarm indicates that the toxic-gas concentration exceeds the programmed hazard threshold, and that the toxic gas in the work area is above the warning level and approaching a hazardous level. Whether a DRPGM provides a warning or danger alarm at the proper concentration depends on its detection capabilities, its ability to translate its findings into an accurate reading, and the presence of interfering gases (see "Calibration Drift and Causes" above).

This is a qualitative function check in which a challenge gas is passed over the sensor(s) at a concentration and exposure time sufficient to activate all alarm settings. The purpose of this check is to confirm that gas can get to the sensor(s) and that all the instrument"s alarms are functional. The bump test or function check does not provide a measure of the instrument"s accuracy. When performing a bump test, the challenge gas concentration should trigger the DRPGM"s alarm(s).

A calibration check verifies that the sensor(s) and alarms respond within the manufacturer"s acceptable limits by exposing the instrument to a test gas. The operator compares the reading to the test-gas concentration (as indicated on the cylinder containing the test gas). If the instrument"s response is within the acceptable range of the test-gas concentration (typically ± 10-20% of the test-gas concentration), then the calibration check verified the instrument"s accuracy. (Note: OSHA recommends that operators check with the instrument"s manufacturer for the acceptable tolerance ranges.) An operator should "zero" an instrument (reset the reference point, in some cases "zero air" gas may be needed) before conducting the calibration check to ensure that the calibration check results are accurate. When performing a calibration check, the test-gas concentration should be high enough to trigger the instrument"s alarm(s).

If the calibration-check results are not within the acceptable range, the operator should perform a full calibration. A full calibration adjusts the instrument"s reading to coincide with a known concentration (i.e., certified standard) of test gas. Test gas used for calibration gas should always be certified using a standard traceable to the National Institute of Standards and Technology (NIST).3

In the past, there has been some confusion regarding proper calibration procedures and frequency. To clarify this issue, ISEA updated its position statement on instrument calibration in 2010, stating, "A bump test . . . or calibration check of portable gas monitors should be conducted before each day"s use in accordance with the manufacturer"s instructions." If an instrument fails a bump test or a calibration check, the operator should perform a full calibration on it before using it. If the instrument fails the full calibration, the employer should remove it from service. Contact the manufacturer for assistance or service.

Follow the manufacturer"s guidelines for proper calibration. Operators cannot perform any job, including DRPGM calibration, properly or safely without the right tools. The type and concentration of calibration test gas, sample tubing, flow regulators, and calibration adapters are key links in the calibration chain. Operators should conduct any testing to verify the operation of the gas monitor in an environment that is the same as (or similar to) the working conditions (e.g., temperature, humidity, atmospheric pressure).

Only use a certified traceable test gas, and do so before its expiration date. The instrument can only be as accurate as the test gas used to calibrate it. Be certain that the supplier can provide a certificate of analysis for every test-gas cylinder. The concentration of the test gas, particularly reactive gases such as hydrogen sulfide and chlorine, will only remain stable for a limited period. Never use a test gas after its expiration date.

Many workplaces have a risk of injury, illness, or death from respiratory hazards such as oxygen deficiency and the combustible or toxic gases. DRPGM technology and products exist to minimize such risks. Properly verifying the function and accuracy of instruments before each day"s use will help to ensure that each worker finishes the job safely.

The RKI Instruments EAGLE 2 portable gas monitor features five different sensor technologies: PID, IR, TC, EC, and catalytic, including smart plug and play sensors for toxic gases. Operating modes include standard confined space entry, leak check for low ppm detection, and bar hole mode for underground detection.

The alarming system has a 30 second response time for 90% of range for most gases while using the standard 5 ft hose. The two alarm levels are user adjustable and can be latching or self resetting. While in leak check mode the LED flash and alarm tones increase in frequency as gas concentration increases. Audible alarm silence is available to perform leak investigations without alarming nearby residents.

The EAGLE 2 is ergonomically designed to easily fit into a large gloved hand. It"s weatherproof enclosure is chemical resistant and can operate in two inches of water. The large backlit display and buttons with glow in the dark text are easy to read and navigate even in dimly lit spaces. It can operate continuously up to 20 hours with NiMH batteries or 18 hours with 4 alkaline batteries. The EAGLE 2 communicates in English, French, Spanish, Italian, and German.

Detects combustible gases in LEL and/or volume percentage range, oxygen, carbon monoxide, carbon dioxide, hydrogen sulfide, sulfur dioxide, ammonia, chlorine, VOCs, and many others depending upon sensor configuration.

Grafana provides a wide variety of ways to display your metrics data and includes the following visualisation formats: tables, timelines, time series, stat, gauge, bar and pie charts.

This dashboard displays all of the metrics that are included within Google’s own Lighthouse report and provides a way of being able to dive deeper into these metrics at any time without the need to perform a new audit from scratch.

As well as using Grafana, this dashboard also uses Prometheus to monitor OpenVPN connections. This report displays status, time since status update, data sent and received today alongside the number of users and clients.

This report captures the full performance of your TrueNas devices and displays key metrics including: location, uptime, current disk temperature, available disk space, disk busy and interface traffic levels.

This highly detailed visualisation centralises not only server and network statistics but also displays the gas and electricity costs associated with this comprehensive homelab setup.

The view configured above displays the following essential metrics with clarity: total running containers, total memory usage, total CPU usage, network RX & network TX.

If you already use GitLab CI or wish to get started with this feature then you may soon find the Grafana dashboard we’ve included above useful. This dashboard displays total pipelines, any failures, pipeline runs within the last hour, successfully completed jobs and the average pipeline runtime duration.

When the creator of this dashboard was tired of manually searching for specific alerts through Slack, teams & emails they soon found out that there was a far better way of displaying this information concisely using Grafana and Prometheus.

For another health and wellness-themed addition to this list, we’ve found an example dashboard that displays usage metrics from the popular cycling and running platform Strava.

This report helps to highlight which of your instances are running too slowly, as well as also displaying unresponsive instances that have happened as a result of unresolved bottlenecks.

In standard applications an inert gas supply of 6bar (80-90 psi) is required for operation of the system. Acceptable gasses for system use are Argon, Nitrogen and Helium.

The systems will also need a forming gas supply for regeneration of the purifier column. The gas should be 3%-10% hydrogen with the balance being the working gas used in the system. The forming gas should be supplied with a low range regulator (approx: 0-20 psi) so that flow can easily be adjusted when starting the regeneration process.

Not necessarily, A heat exchanger is integrated into the gas purification system to achieve optimum working temperatures inside the glovebox. In hot climate zones it is recommended to connect the cooling water to the gas purifier to maintain comfortable working environments inside the glovebox. In laboratories equipped with air conditioner units which already maintain constant temperatures it is not needed to hook up cooling water to the gas purification system.

My system displays the alarm "Blower GB1 motor protective switch activated or error frequency controller". What does this mean and how can I remedy it?

To rectify the issue, open the electrical cabinet and locate the frequency controller, it is typically labeled ‘U1’. Note the error displayed on the controller. Then turn circulation off. Verify the box filters are clean and change if needed. With circulation off reset the controller by pushing the appropriate key on the controller. Once the code is cleared turn circulation back on.

You should flush the system to a ppm value of <100ppm O2 with working gas (N2 or Ar or He) before starting the circulation. You will need approximately 11 times the box volume of purge gas to achieve 100ppm O2 (depending on the installation and purge method, the required gas volume may vary). This corresponds to approx. 1 bottle (50 litres) per m3 box volume.

You need approx. 1/3 bottle (50 litres) of regeneration gas with a concentration of 2%-5% H2 in Ar or N2 to carry out the regeneration. The regeneration consumes approx. 3500l from the 50 litre bottle (approx. 70-80 bar). If you have selected the regeneration gas concentration <5%, the required regeneration gas quantity will increase to approx. 7000l.

Please make sure that the box has an O2 value of <100ppm before starting regeneration. If this is not the case, rinse the system to an O2 value of <100ppm. The box gas is used to fill the reactor copper molecular sieve (RKM) after evacuation for cooling and should have a low oxygen value.

When the regeneration is started, a pop-up window appears with the question "Are you sure you want to regenerate? The regeneration can be aborted with "NO". If you have selected "YES", you will subsequently be prompted to check the regenerating gas flow.

Even if the replenishment gas cylinder does not contain the required quantity of replenishment gas or is empty, you must allow the replenishment process to run through.

The system will not be damaged if a regeneration without gas has been started accidentally. The regeneration cycle must be completed, otherwise the corresponding Reactor Copper Molecularsieve (RKM) will be locked.

The analyzers needs a constant gas flow to measure correctly. Without the circulation of the box atmosphere, there is no gas flow across the sensors, which is why they measure incorrect values.

This error means that the electro-pneumatic valves on the top of the filter column (RKM input/output) are not fully open or closed. Usually this is caused by an empty gas cylinder or too low pressure of the working gas supply. Please set the pressure to 6 bar. If this does not help, it will be necessary to change the gas cylinder.

As working gas, you can use nitrogen, argon or helium. The pressure should be at 6bar, an appropriate pressure reducer with an appropriate setting range for reducing the gas cylinder pressure is required.

A concentration of 2%-5% H2 in 95-98% Ar/N2 (depending on the type of working gas) can be used as regeneration gas (mixed gas). The pressure of the regenerating gas should be at 0.3 to 0.4 bar, a corresponding pressure reducer with a corresponding setting range for reducing the gas cylinder pressure is required.

Once the power failure has been rectified, the system reboots to the level of the system at which the power failure has occurred. Depending on the software version, the system can continue in the step it was in during a power failure when regeneration is started. Otherwise it starts the regeneration gas process from the beginning.

It is not necessary to connect cooling water. If possible (heat exchanger installed in the gas cleaning system) it reduces the temperature in the glovebox and results in a more pleasant working temperature.

The system must be connected to an exhaust air system depending on room air and ventilation. In the event of a glovebox operation with a 50l gas cylinder, up to 10,000l of gas can flow into the premises. With a tank supply, however, much more.

If dangerous substances are used, a connection is recommended. The connections should be at the vacuum pump, the purge outlet valve, the regeneration gas outlet, the overpressure protection valves and, if purge valves are used, at their outlet valves. The specification of the exhaust air system is given in the user manual.

Check the frequency converter in the electrical cabinet of the gas cleaning unit. The error code is listed in the user manual. A "reset" on the frequency inverter resets the error message. Another possible cause may be that the fuse or the motor protection switch has tripped it. In this case, please switch on again. If the fault occurs repeatedly, it may be due to dirty box dust filters or a damaged circulation fan.