DETECTING HAZARDOUS AMMONIA LEAKS IN REFINERIES AND PRODUCTION PLANTS
Leaking ammonia (NH3 ) gas, no matter the industrial process, application, or type of plant, is a potential danger to
employees, plant equipment, and surrounding communities. Fortunately, today’s newest ammonia fixed gas sensor technologies, including infrared (IR), electrochemical, laser, and ultrasonic, provide highly effective point and area monitoring solutions to help prevent accidents.
are today protected with a mix of NH3 sensing technologies
matched to specific hazards to provide point, perimeter, and personal protection.
Ammonia Exposure
No matter the production process or end-use application, ammonia gas is toxic and dangerous in lower concentrations and lethal in higher ranges. NH3
is well known for its pungent
odor, and most people can smell it right away unless they’ve had prolonged exposure. The trouble is with longer periods of exposure, or repeated exposure, a person’s sense of smell becomes immune to NH3
and leaves one vulnerable to the toxic effects of this gas. Fig 1. Ammonia Gas Production
The production of ammonia around the globe relies primarily on natural gas (less polluting) as a feedstock or coal (Fig. 1). In addition, the petrochemical industry and other heavy industries rely on ammonia for nitrous oxide (NOx) control in stacks or flues to prevent air pollution. The demand for ammonia production is expected to continue growing in the near term as a fertilizer, refrigerant and potentially a hydrogen-carrier gas to reduce reliance on carbon-based energy1
. As a potential carrier gas for carbon-free hydrogen (H2 ) fueled
energy, ammonia production could rise dramatically as the world embraces it as part of the solution to de-carbonize the economy and reduce global warming2
handling, and storing H2 NH3
, which can be converted to H2
to power emission-free fuel cells or turbines, is expected to gain traction.
About Ammonia
Ammonia is a colorless gas that is naturally found in nature in trace quantities. This gas is lighter than air, which means it can form clouds that travel beyond a refinery or industrial plant’s perimeter in the wind during an accidental release. If there is water vapor in the gas mixture, then a cloud can form and often remains lower to the ground, which poses a great risk to employees.
In addition to being a toxic gas, ammonia is potentially combustible. While not highly flammable, ammonia in containers is explosive under high heat. The lower explosive limit of NH3
is
in the range of 15 percent, and the upper explosive limit is 28 percent. Refineries, NH3
production plants, and storage facilities
. Due to the challenges of producing, , the comparatively stabile nature of near or at the source of use
For ammonia, the U.S. Occupational Safety and Health Administration (OSHA) specifies an 8-hour exposure limit of 25 ppm and a short-term (15-minute) exposure limit of 35 ppm in the workplace. Recommendations and regulations vary globally and are updated periodically as more information becomes available, so limit values should be confirmed with respective national agencies and/or organizations before proper usage.
Detecting Ammonia Leaks
Ammonia can be difficult to detect, depending on the plant layout and environment. Oil and gas refineries, NH3
production plants,
and storage facilities are often crowded with equipment where the gas could be present, resulting from leaking valves or elbows and other production equipment, such as pumps. For these reasons, plant safety teams typically rely on a mix of portable detectors worn by employees and fixed gas detection systems.
When evaluating ammonia sensors for use in occupational exposure assessment, there can be several competing types from which to choose. For process and plant engineers responsible for fixed gas detection systems, a best practice for plant safety is to follow a multi-sensor layered approach with strategic NH3
Fig 2. Electrochemical Cell Sensing (Graphic)
solution on the working electrode, a reaction occurs (Fig.2). This reaction causes a release of electrons, whereby the flow of the electrons is measured as current within the sensor. The current is proportional to the gas concentration and is measured in parts per million (ppm) of the gas.
Most traditional ammonia electrochemical sensors have a 1-2 year life, but actual lifetimes can be on the order of months or weeks when ammonia concentrations are high or where extremes in temperature or humidity are encountered. It can be difficult to predict when an ammonia sensor will begin to lose sensitivity, so frequent calibration may be needed to ensure an accurate reading.
They also often degrade at a faster rate when exposed to heavily polluted conditions. Another limitation of traditional EC sensors is cross-sensitivity to interfering gases, or non-targeted gases, which will also be detected by the sensor resulting in skewed measurements of the desired gas.
detector
positioning that provides a highly secure web of coverage to guard against accidental gas releases.
Electrochemical Cell Sensors
Target gas-specific electrochemical (EC) sensors are available for many of the most common toxic gases, including ammonia. This sensing technology functions on principles similar to those found in batteries. Ammonia gas enters the sensor inlet and then generates a chemical reaction with a catalyst that is in contact with an electrode. When the target gas encounters an electrolyte
MSA’s patented XCell® technology utilizes the same principles
found in traditional electrochemical sensors but employs a number of significant physical design advancements for better performance and longevity. Instead of a typical water-based electrolyte, XCell sensors employ a unique class of ionic electrolyte liquids that features an evaporation-resistant profile capable of withstanding extreme environments with large humidity and temperature fluctuations (-40 to +60°C).
Another differentiator is the choice of catalyst in the electrode material. Unlike traditional electrochemical sensors, the XCell catalyst is not consumed by the gas reaction. Contact with ammonia has virtually no effect on the lifespan of the sensor.
WWW.PETRO-ONLINE.COM
Page 1 |
Page 2 |
Page 3 |
Page 4 |
Page 5 |
Page 6 |
Page 7 |
Page 8 |
Page 9 |
Page 10 |
Page 11 |
Page 12 |
Page 13 |
Page 14 |
Page 15 |
Page 16 |
Page 17 |
Page 18 |
Page 19 |
Page 20 |
Page 21 |
Page 22 |
Page 23 |
Page 24 |
Page 25 |
Page 26 |
Page 27 |
Page 28 |
Page 29 |
Page 30 |
Page 31 |
Page 32 |
Page 33 |
Page 34 |
Page 35 |
Page 36 |
Page 37 |
Page 38 |
Page 39 |
Page 40 |
Page 41 |
Page 42 |
Page 43 |
Page 44
