Innovations In RTD Signal Conditioning - One Manufacturer's Compilation

Industrial process measurement and control RTD signal conditioner
RTD Signal Conditioning Units
Courtesy Acromag
Temperature measurement may be one of the oldest components of process control and laboratory research. The measurement of temperature has progressed through a variety of methodologies, some of which are still in use today. Modern industrial process control relies heavily on the use of RTDs (resistance temperature detector) for their accuracy and stability.

Some of us have used RTDs in our process designs for many years, maybe without recognizing the innovations that have come about in the signal conditioning portion of our installations. One manufacturer of industrial signal conditioning equipment, Acromag, has compiled the ten most significant recent advances in RTD signal conditioning. I have included their white paper below.

Browse the paper, as it is brief and informative. You will likely see a few improvements of which you were unaware. Share your temperature measurement and signal conditioning challenges with an application specialist. Combining your process experience with their product application expertise will produce positive solutions.



Ethernet I/O Modules Provide Connectivity Advantages

Industrial Ethernet Input and Output Modules on DIN Rail
Industrial Ethernet I/O Modules
Courtesy Acromag
Industrial process control relies on the accurate and timely delivery of process measurements and data to the point of control and decision making. As technology affords more opportunities to measure and transmit process variables, the demand for incorporating the additional information in the control and decision making process expands. The frequency at which data can flow from a process has also increased dramatically, and there is often significant value derived from rapid sampling. Transmitting the voluminous measurement data to the point of control can be accomplished using three basic methods:

  • Point to point wiring from each measurement device to the control point.
  • Wireless linkup from measurement location to controller.
  • Wired network connection between measurement and control devices.
Each of these connection topologies has particular attributes which may better suit a particular application.  For a wired network scheme, Acromag has designed a line of I/O modules that make installation and configuration a smooth operation. Helpful features include:
  • Power wiring options that allow back connected bus power or top mounted screw terminals. You can even provide primary and backup power sources to the two connections.
  • Front facing screw terminals for connections make status checking of inputs a simple operation with your digital volt meter.
  • Modules are rail mounted and can be placed immediately adjacent to one another for high density installation.
  • Modules have a built in webpage for display of operational information. Configuration is accomplished using a front mounted USB port.
  • Operable in temperatures -40 to +70 deg. Celsius.
  • Two Ethernet ports on each unit allow modules to be daisy chained, reducing or negating need for local hubs.
  • Acromag's Priority Channel Technology assures that data update frequencies are maintained, regardless of other network traffic.
The short video below provides additional detail on the useful features of the Acromag line of industrial Ethernet I/O modules. Watch the video. Share your process measurement and control connectivity challenges with a sales engineer specializing in industrial Ethernet I/O. Combine your process knowledge with the state of the art product knowledge of a product specialist for the best solutions.



Flexible Hazardous Gas Detection Monitoring System

Hazardous gas detection monitoring unit
Sentry IT Controller For Hazardous Gas Detection Monitoring
Courtesy Sierra Monitor
Industrial processes, by their scale and nature, are rife with hazards. As a process designer, engineer, or operator, protection of the facility, employees, and surrounding community ranks highest among our many responsibilities. Some hazards are apparent, visible, easily detected. Others are not. Technology and ingenuity play a substantial role in providing acceptable levels of safety in modern facilities.

Properly designing a hazardous gas monitoring system starts with identifying the target elements and their sources. Gaseous hazards can generally be divided into three general classes, all of which can be specifically targeted with a properly configured gas monitoring system.


  • Combustible gas concentrations subject to ignition and explosion.
  • Toxic gas with inherent personnel risk.
  • Insufficient oxygen levels to support human respiration.

The best overall system configuration can be achieved through a combination of detectors, communications, and response that will provide accurate sensing of the target hazard, reliable and predictable transmission of information, and preconfigured response when alarm limits are triggered. Some product features for the detector monitor that may prove useful in a well specified installation:

  • A means to non-intrusively calibrate all sensors at the same time
  • Ability to diagnostically monitor connected sensors for performance.
  • Provision of an easily operable interface for users.
  • Battery backup to maintain operation during a power outage.
  • Network and protocol compatibility with a range of industry accepted standards.
  • Simple means to upgrade operating software.
  • Compatibility with detection devices from a broad array of sources.
  • Input capacity for more sensors than your current requirement.
I have included a bulletin describing such a unit, manufactured by Sierra Monitor. Browse the document and contact a hazardous gas detection application specialist to get more details and discuss your hazardous gas detection challenges. The best solutions come from combining your process knowledge and experience with that of a product application specialist.




Industrial I/O Applications Compilation Provides Answers

Process Measurement and Control Input and Output Devices
Process Measurement and Control I/O Devices
Courtesy Acromag
Process measurement always presents two basic challenges, derive a measured value of the process condition, then transmit or deliver that value to a recording or decision making device. Your knowledge and ingenuity applied to the design and implementation of these measurement and transmission functions are the key to how effectively your control system will function. Acromag, a world class manufacturer of signal conditioning equipment and industrial I/O devices, has produced a compilation of applications that illustrate some creative and best practices for establishing effective connections between control and measurement devices. The applications are drawn from defense, power generation, and manufacturing, but the knowledge shared can be broadly applied to many industries.

Look through the applications and you will find something of value. You can always contact a product and application specialist to discuss your process measurement and control challenges and requirements. Combining their product application expertise with your process knowledge will generate the best solutions.



Rotameters For Flow Measurement - Selecting the Right One

Industrial rotameter flow meters
Industrial Rotameter Flow Meters
Courtesy King Instrument
Applied extensively in industrial process measurement and control, a rotameter is an instrument that uses a float of given density to establish, for any measurable flow rate, an equilibrium position within the fluid stream where the force of the flowing fluid equals the force of gravity. Let's break that down a little. A rotameter has a tapered tube with a float inside. As the measured fluid flows upward through the tube, it pushes the float upward along the length of the tube. As the float rises in the tube, the cross sectional area of the tube increases and more fluid can bypass around the float. At some point, the upward force of the fluid flow acting on the float will balance with the downward force of gravity. The position of the float along the length of the tube correlates with a certain flow rate when certain properties of the fluid are known. Flow rate scale graduations on the tube can be read by the operator.

Rotameters are very specific to each flow measurement application. It's important that you know your fluid properties, ambient conditions, connection and readability specifications. 

Start with these selection parameters:

  • Desired flow rate range
  • Fluid specific gravity
  • Ambient temperature
  • Operating and maximum pressure
  • Line size
  • Connection type
  • Connection orientation
  • With or without a valve
  • Material requirements to accommodate fluid
  • Scale units of measure. Smallest scale divisions needed.
For each application, it's advisable to work closely with a sales engineer to gather all the needed information and coordinate the product selection process.

Here are some things to consider for potential rotameter applications:


  • Simple design and operation provide a modest cost solution.
  • No external power is required for operation. Inherent fluid properties and gravity are used to measure flow rate.
  • Clear glass used for the measuring tube is highly resistant to thermal shock and corrosion.
  • Instrument orientation must be vertical, with fluid flowing upward.
  • Scale graduations are accurate for a given substance at a given temperature, making the devices application specific.
  • Operation of the rotameter may be impacted by changes in the viscosity of the fluid. Consult with a product and application specialist to explore your application.
  • Direct flow indication provides resolution that may not be as good as some other flow measurement methods.
  • Visual reading of the scale is subject to uncertainty due to float oscillation, parallax, and location on the scale.
  • Make sure the fluid turbidity, or another fluid characteristic will not obscure the visibility of the float.

Consult with a product specialist about your flow measurement application. A combination of your process knowledge and their product expertise will produce the best solution.


Analynk Wireless Updated Website

Analynk Wireless company logo
Analynk Wireless has a new website
One of the manufacturers represented by MS Jacobs & Associates, Analynk Wireless, has redesigned and published an updated website. The new site provides access to features, model configurations and datasheets for their entire range of industrial process control and measurement products. Analynk's product line complements those of other manufacturers in the MS Jacobs portfolio of industrial instrumentation and process control products. MSJ employs the Analynk products, often in combination with products of their other manufacturer lines, to provide complete packaged process control solutions for their customers.

Analynk Wireless encompasses three groups of products:

  • Hazalynk® wireless products for hazardous areas, including explosion proof antennas and hazardous area access point enclosures.
  • Sensalynk® single and multi-point wireless transmitters, receivers, and repeaters for industrial wireless networking.
  • Telmar® transmitters, tachometers, signal alarms, power supplies, indicators and meters for process measurement and control.
Take a look at the new Analynk website. Discuss your process improvement ideas with product application specialists and develop a plan to generate better outcomes.

Application Suitability of Ultrasonic Flowmeters

Ultrasonic Liquid Flow Meter
Ultrasonic Liquid Flow Measurement System
Courtesy Flexim America
Industrial process control frequently requires the accurate measurement of fluid flow. There are several widely applied methods for measuring flow, each having particular advantages which may apply to a specific application.

Ultrasonic flow meters measure flow indirectly by calculating transit time of a sound wave through, or reflecting from, a flowing fluid. The velocity of the fluid has an impact on the transit time, from which a flow rate can be calculated. Attributes of ultrasonic flow measurement that may determine suitability for a particular application include:

  • Transducers can be clamped on exterior pipe surface where measurement is needed.
  • Non intrusive measurement technology prevents contact between media and measuring elements.
  • No significant pressure drop associated with measuring device installation.
  • Reduced leak potential.
  • No moving parts.
  • Comparatively higher cost than some other technologies.
  • Fluid characteristics must be well known for proper application.
  • Pipe cross section must be completely filled by media to acquire accurate flow measurement.
Learn more about this process measurement and control technology in the product detail sheet below. Consult with a product application specialist for more detailed product information and tips on how to best apply ultrasonic flow meters to your process.