The Safety and Performance of your Printing Line: Flame Temperature

The flame temperature analyzer measures the amount of heat given off by a pilot flame as it burns in an explosion-proof measuring chamber. The small, well-regulated flame heats the tip of a temperature sensor suspended directly above it.

The Safety and Performance of your Printing Line: Infrared Absorption

Combustible gases absorb infrared radiation at certain characteristic wavelengths. A typical non-dispersive infrared (NDIR) detector passes a source of infrared energy through the sample and measures the energy received by one of two detectors. The active detector responds to wavelengths in the same band as the sample gas, while the other detector measures a reference to compensate for changes within the instrument.

The Safety and Performance of your Printing Line: Catalytic Sensors

Catalytic-bead sensors are constructed of two small wire coils covered with a catalyst. One coil is “active” while the other is rendered inert and acts as a reference. A flow of electrical current through the internal coils heats the catalytic coating to a temperature at which the active coil will react with many flammable vapors and gases. This reaction occurs in the form of surface combustion which in turn causes an increase in the sensor’s temperature. The resulting temperature change is converted into an LFL reading.

The Safety and Performance of your Printing Line: Sensor Choices and How to Decide

Although several different types of sensors are employed as LFL monitors, each has an appropriate application to which it is best suited.

Fires and explosions in what was thought to be “protected” equipment can occur without warning when a sensor is not capable of doing the job that had been assigned to it.

This is most often caused by a misunderstanding of the different available technologies.

The Safety and Performance of your Printing Line: Application Examples

Typical Flexographic Application Examples Include:

  • Drying systems for printing lines
  • Abatement systems such as oxidizers

Processes that use flammable solvents can develop explosive concentrations due to failure of coating, metering, ventilation or heating systems, adverse chemical reactions, and human error.

LFL monitors are used for safety as well as process efficiency, protecting the system from fire and explosion while also allowing operating at higher vapor concentrations to save costs.

The Safety and Performance of your Printing Line: Failsafe

There are important considerations when choosing an LFL monitor: Response Accuracy, Response Speed, Condensation Issues and Failsafe.

The Safety and Performance of your Printing Line: Condensation Issues

There are important considerations when choosing an LFL monitor: Response Accuracy, Response Speed, Condensation Issues and Failsafe. We've discussed response accuracy and response speed, let's look at condensation issues:

The Safety and Performance of your Printing Line: Response Accuracy: Response Speed

There are important considerations when choosing an LFL monitor:

The Safety and Performance of your Printing Line: Response Accuracy

There are important considerations when choosing an LFL monitor:

  • Response Accuracy
  • Response Speed
  • Condensation Issues
  • Failsafe

First let's look at response accuracy.

There are several technologies used to measure flammability, and few react the same way to all substances. 

A sensor or analyzer calibrated to accurately read one substance may be significantly inaccurate for another process component. This variance from perfect accuracy (error) is known as the Response Factor. 

The Safety & Performance of your Printing Line: Process Temperatures

Most published LFL values are calculated at room temperature.

However, as a given mixture is heated, its flammability increases and thus the concentration required to achieve 100% LFL is less. This source of increased danger is often overlooked.

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