Inline Refractometers Used in Commercial Food and Beverage Production

in-line process refractometer with control housing
Hygienic process in-line refractometer
with control unit and flow cell
Courtesy Flexim
Refractometry is a measuring technique that evaluates the impact of fluid media on light. There are some variants of the basic technology, but essentially it relies upon the media affecting a change in the way in which light waves propagate through a sample. This refraction caused by the sample can be compared to a known standard and information about the sample can be deduced.

Refractometry is a useful measuring method for many liquid processing operations. It is used for concentration and density analysis of process liquids. Portable sample processing units are available, but high volume continuous flow operations benefit from the use of in-line refractometers that do not require manual sampling and handling of process liquids. The measurements are produced in real time to continuously verify the fluid quality characteristics.

Food and beverage manufacturers use refractometry to determine the concentration of sugar, ethanol, ascorbic acid, pectin, artificial sweeteners and other components in their products. Close control of component concentration is a necessary part of delivering a consistent taste in finished products. Large investments are made to establish brand name products, and delivery of a consistent customer experience each time a product is consumed is key to developing and growing a brand. This is a solid example of a marketing based application of science and technology to industrial processing.

In-line refractometers for food and beverage applications will have specific features and construction to make them suitable for hygienic processing. The avoidance of contamination is first and foremost a requirement. Additionally, design features that reduce maintenance requirements and retain the needed measuring accuracy through extended periods of usage add value to the unit and should be a consideration when selecting an in-line refractometer.

Share your in-line refractometry applications and challenges with product specialists, combining your process experience and knowledge with their product application expertise to develop effective solutions.


Simplex vs. Duplex Strainers For Industrial Liquid Processing

duplex basket strainer
Duplex basket strainer, shown with one basket removed
Courtesy Eaton Friltration
Many industrial and commercial liquid systems have mechanical components that cannot tolerate particulate matter in the liquid. Pumps, valves, sensors, and other specialties can experience accelerated wear and tear due to certain types and sizes of particulate matter.

Good practice dictates that the tolerance of the system for particulate matter should be determined and a properly sized and configured device be put in place to remove particulates larger than greatest allowable size. Considerations for connection size and type, construction material suitability for the process media, flow rate, pressure drop, and filter holding capacity should all be a part of the product selection criteria.

simplex basket strainer with basket removed
Simplex basket strainer with access cover and basket removed
Courtesy Eaton Filtration
One key element of the selection criteria is whether the system can be temporarily shut down for replacement or cleaning of the filtration element. A basket strainer, one of several types of liquid filtration devices, is available in both simplex and duplex variants. A simplex basket strainer functions as a single unit, requiring flow stoppage when the basket becomes clogged with debris. The changeover time may not be long, but some processes cannot tolerate any downtime. A duplex strainer is comprised of two simplex strainers, incorporated into a common housing, with an inlet chamber and diverting valve that selects which strainer basket will process the liquid flow. Changes in pressure drop through the device can be used to signal when it is time to switch operation between the strainer baskets.

Fluid filtration can be an important part of keeping a process in operation, reducing wear and tear on piping system components and equipment. Share your process fluid filtration challenges and requirements with application specialists, combining your process knowledge and experience with their product application expertise to produce effective solutions.

Hybrid Solar TEG Power Systems

hybrid solar PV photovoltaic thermoelectric generator TEG power system
Hybrid system shown in remote installation
Courtesy Gentherm Global Power Technologies
There are remotely located instruments and equipment throughout the world in places without available grid power. A suitable and reliable means to provide electric power is required as a standalone system for each of these instances. Photovoltaics is an obvious choice for power source, but there is another option that may provide substantial benefit for many installations.

A hybrid solar TEG (thermoelectric generator) can overcome some of the shortcomings of a pure PV system by delivering battery charging current during conditions when solar generated power is insufficient. The TEG uses heat from burning fuel to produce electric power, and can deliver charging current when the PV portion of the system fails to provide sufficient output.

  • Extended periods of bad weather. While this scenario can be compensated for with a larger battery array, there is still a limit to the performance period. Larger battery banks increase unit cost, size and weight.
  • Extreme low temperature. Battery capacity decreases during cold weather, requiring a larger battery array to provide design power output and reserve.
  • Low solar exposure during certain times of the year, requiring more solar panels to accomodate the system power requirements during times of reduced sunlight. This increases unit size and capital cost.

Critical power systems must be designed to deliver sufficient power under all environmental conditions that can be experienced at the installation site. This drives pure PV system designers to substantially oversize panel and battery arrays to assure power delivery throughout an entire year. A hybrid solar TEG system does not need to have the enormous headroom built into the design that a pure PV does. The TEG can produce power at a known rate, regardless of the surrounding environmental conditions. The potential benefits from the hybrid power system include: 

  • Reduction in solar panel array size and cost
  • Lower battery count, with reduction in capital cost, replacement cost, unit size and weight
  • Longer battery life
  • Less on-site fuel vs. a conventional fuel-based system
  • No more than once-per-year maintenance visits
  • Increased reliability over a pure PV installation

Share your remote installation power requirements and challenges with a product application specialist and bring the benefits of a hybrid solar TEG power system to your operation.


Switching Inductive Loads With Relays and Solid State Devices in Process Control

control panel interior process automation and control panel
Switching devices must be properly protected for longevity
We connect a lot of black boxes together in our control systems, not really knowing what goes on inside. There is a basic understanding of function, but maybe not enough knowledge to thoroughly assess all aspects of integrating a device into a train of control system components. We range from novice to seasoned expert, so Acromag, manufacturer and global supplier of I/O devices for process control, has provided a useful application note regarding the protection of devices employed to switch inductive loads.

The application paper provides a good explanation of what an inductive load is, and how it can impact the performance and longevity of a switching device. The document further explains how to offset the potentially damaging impact of an inductive load on a connected switching device, with specific examples and recommendations on how to put the protective measures in place. It is useful information.

The paper is provided below. Share your I/O and other process measurement and control challenges with application specialists, combining your own process knowledge with their product application expertise to develop effective solutions.


Selecting the Right Temperature, Pressure, or Differential Pressure Switch

industrial temperature switch pressure switch differential pressure switch
Temperature, pressure, and differential pressure switches come in a wide variety of configurations
Courtesy Ashcroft
Industrial process control applications present dynamic and varied requirements for measuring, monitoring and control. Each point calls for specific evaluation of the information needed from the process point for use in monitoring process performance, or control to be applied at the process point to regulate an outcome. Sometimes, a continuous analog signal is needed to provide indication across a range of values. Other times, it is only necessary to have notification of, or take action when, a certain temperature or pressure related event occurs. In those cases, a simple and reliable device can adequately meet the project requirements.

Temperature, pressure, and differential pressure switches connect to a process and change their switch position when a setpoint condition is reached. The are simple to understand, easy to install, low in cost, and require little maintenance of attention. The switches are available in an extensive array of configurations, with options to fill out almost any application requirement.

Ashcroft, global supplier of temperature and pressure switches, has produced a simplified guide that enables a designer or specifier to quickly focus their search on the right product. It is provided below for your use. Alternately, you can always share your process measurement and control requirements and challenges with product application specialists, combining your own process knowledge with their product expertise to develop effective solutions.



CSB Case Study of Industrial Plant Heat Exchanger Explosion

heat exchangers at industrial plant
Two heat exchangers at chemical plant
Industrial accidents, whether minor or catastrophic, can serve as sources of learning when analyzed and studied. Operators, owners, and technicians involved with industrial chemical operations have a degree of moral, ethical, and legal responsibility to conduct work in a reasonably and predictably safe manner without endangering personnel, property, or the environment. Part of a diligent safety culture should include reviewing industrial accidents at other facilities. There is much to learn from these unfortunate events, even when they happen in an industry that may seem somewhat removed from our own.

The U.S. Chemical Safety Board, or CSB, is an independent federal agency that investigates industrial chemical accidents. Below, find one of their video reenactments and analysis of an explosion that occurred at a Louisiana chemical processing plant in 2013. A portion of the reenactment shows how a few seemingly innocuous oversights can combine with other unrecognized conditions that result in a major conflagration.

Check out the video and sharpen your sense of awareness for potential trouble spots in your own operation.

Improved Level Measurement Contributes to Reduced Heat Rate in Steam Production

Power plant electrical generating plant
Minimizing heat rate and emissions for steam plants
Steam production is a costly operation in any facility, but is of paramount importance in power generation plants. The bottom line of a combustion based power generation facility is sensitive to the cost of input fuel. Measures that can be taken to reduce fuel input for a unit of power output (called heat rate) can translate directly into profitability. An additional benefit of reducing heat rate is a commensurate reduction in emissions.

A major contributor to heat rate reduction is the recovery of heat from the process and transference of that heat into the boiler feedwater. A sizable feedwater preheater of the shell and tube type is used to recover the heat. Shell and tube heat exchanger efficiency can be maximized with accurate control of liquid level.

Magnetrol, globally recognized leader in level measurement technology, makes the case for using guided wave radar level measurement technology as the most advantageous means for this application. The video below describes the process and how the guided wave radar level transmitter can provide the best performance.

Magnetrol has an information kit devoted to heat rate reduction. Share your steam system and level measurement challenges with a product specialist, and ask how you can get the Heat Rate Reduction Kit. Combining your facility and process knowledge with the product application expertise of a specialist will result in effective solutions.