Power Specialties Carries an Extensive Range of Products Engineered for Process Control Applications in Every Sector of the Industrial Market

Power Specialties, founded in 1967, was based on the principle that customer service is of the utmost importance. Our Sales Engineers have received extensive training in the application and selection of instrumentation and control products. Power Specialties offers a diverse range of industrial control products, instrumentation, and equipment to a wide range of industries, including ethanol/biofuel, agricultural and specialty chemical, power, pharmaceutical, manufacturing, and oil and gas production. Flow, level, pressure, temperature, analytical instrumentation, recorders, data acquisition, annunciators, loop controllers, steam jet vacuum systems, process weighing, and instrument communications are among the products available.

https://powerspecialties.com
(816) 353-6550

Yokogawa Instrumentation Services

A measurement instrument isn't a one-time purchase. It is a long-term life cycle investment. Yokogawa knows they are often operating critical processes, processes where safety is paramount. That is why Yokogawa offers high-quality life cycle services to keep Yokogawa's instruments in top condition. Yokogawa goes above and beyond to make customer satisfaction. They offer these services at Yokogawa's manufacturing facility in Newnan, Georgia, where highly trained technicians perform a complete assessment, calibrate repair, clean upgrade, and produce a comprehensive service record. 

Yokogawa's full service includes calibration, repairs, cleaning, upgrades, and comprehensive service records. Even on competitor models! White glove inspection process and repair, from simple touchups to sandblasting and repainting, are part of the Yokogawa difference.

Yokogawa's full instrumentation services includes:

• Calibration and Certification 
• Installation / Loop Check / Startup 
• Preventative and Corrective Maintenance Services 
• Emergency Repair 
• Programming and Troubleshooting 
• Factory Repair / Flow Testing

Additional Yokogawa Instrument Services

• On-site Calibration and Certification (All Manufacturers' Equipment)
• Emergency Repair, Programming, and Troubleshooting
• Preventative and Corrective Maintenance Services

For more information in Iowa, Nebraska, Kansas and Missouri contact Power Specialties. Call (816) 353-6550 or visit https://powerspecialties.com.

Hygienic and Sanitary Pressure Transmitters: The Yokogawa EJA565E and EJA564E

The food & beverage and pharmaceutical industries must maintain a high degree of flexibility to meet shifting market demands while at the same time, retaining the highest level of product quality and regulatory compliance.

Yokogawa’s hygienic & sanitary transmitters provide the performance and certifications for these growing and dynamic industries.

EJA565E (Gauge Pressure/Tank Level)

The EJA565E is a high-performance hygienic & sanitary transmitter for pressure and level applications requiring compliance with Food & Beverage and Pharmaceutical industry regulations.

EJA564E (Gauge Pressure)

The EJA564E is a hygienic & sanitary transmitter for pressure applications requiring compliance with Food & Beverage and Pharmaceutical industry regulations.

DOWNLOAD THE EJA565E AND EJA564E BROCHURE HERE

For more information in Nebraska, Iowa, Missouri, or Kansas contact Power Specialties, Inc. Call them at (816) 353-6550 or visit their website at https://powerspecialties.com.

US Power Grids, Oil and Gas Industries, and Risk of Hacking

A report released in June, from the security firm Dragos, describes a worrisome development by a hacker group named, “Xenotime” and at least two dangerous oil and gas intrusions and ongoing reconnaissance on United States power grids.

Multiple ICS (Industrial Control Sectors) sectors now face the XENOTIME threat; this means individual verticals – such as oil and gas, manufacturing, or electric – cannot ignore threats to other ICS entities because they are not specifically targeted.

The Dragos researchers have termed this threat proliferation as the world’s most dangerous cyberthreat since an event in 2017 where Xenotime had caused a serious operational outage at a crucial site in the Middle East. 

The fact that concerns cybersecurity experts the most is that this hacking attack was a malware that chose to target the facility safety processes (SIS – safety instrumentation system).

For example, when temperatures in a reactor increase to an unsafe level, an SIS will automatically start a cooling process or immediately close a valve to prevent a safety accident. The SIS safety stems are both hardware and software that combine to protect facilities from life threatening accidents.

At this point, no one is sure who is behind Xenotime. Russia has been connected to one of the critical infrastructure attacks in the Ukraine.  That attack was viewed to be the first hacker related power grid outage.

This is a “Cause for Concern” post that was published by Dragos on June 14, 2019. 

“While none of the electric utility targeting events has resulted in a known, successful intrusion into victim organizations to date, the persistent attempts, and expansion in scope is cause for definite concern. XENOTIME has successfully compromised several oil and gas environments which demonstrates its ability to do so in other verticals. Specifically, XENOTIME remains one of only four threats (along with ELECTRUM, Sandworm, and the entities responsible for Stuxnet) to execute a deliberate disruptive or destructive attack.

XENOTIME is the only known entity to specifically target safety instrumented systems (SIS) for disruptive or destructive purposes. Electric utility environments are significantly different from oil and gas operations in several aspects, but electric operations still have safety and protection equipment that could be targeted with similar tradecraft. XENOTIME expressing consistent, direct interest in electric utility operations is a cause for deep concern given this adversary’s willingness to compromise process safety – and thus integrity – to fulfill its mission.

XENOTIME’s expansion to another industry vertical is emblematic of an increasingly hostile industrial threat landscape. Most observed XENOTIME activity focuses on initial information gathering and access operations necessary for follow-on ICS intrusion operations. As seen in long-running state-sponsored intrusions into US, UK, and other electric infrastructure, entities are increasingly interested in the fundamentals of ICS operations and displaying all the hallmarks associated with information and access acquisition necessary to conduct future attacks. While Dragos sees no evidence at this time indicating that XENOTIME (or any other activity group, such as ELECTRUM or ALLANITE) is capable of executing a prolonged disruptive or destructive event on electric utility operations, observed activity strongly signals adversary interest in meeting the prerequisites for doing so.”

Level Measurement White Paper

This paper, courtesy of Yokogawa Corporation of America, covers level measurement using differential pressure (DP) level transmitters. A DP level transmitter uses the head pressure and specific gravity of the media to infer the level in the vessel. It is a widely-used level technology having the advantage of being based on a well-understood principle. It is an excellent selection for clean liquids but also works well with viscous liquids and slurry/sludge; but, is not recommended for solids. The disadvantage is the limited temperature operating envelope of the transmitter. Adding a remote diaphragm seal system to the DP transmitter overcomes this limitation.

DOWNLOAD THE FULL WHITE PAPER HERE

For Over 50 Years Customers Have Trusted Power Specialties

Established in 1967, Power Specialties was founded on the concept that customer service is of primary importance. Our staff of Sales Engineers are well trained in the application and selection of instrumentation and control products. Call us with your next process instrumentation, process weighing, or process equipment requirement.

Power Specialties, Inc.
https://powerspecialties.com
(816) 353-6550

Advanced Laser Level Measurement for Liquids

The Hawk Measurement Systems OptioLaser S300 Laser is a new product that can be used for the detection of all types of liquids, regardless of their dielectric properties.

This laser level detection system can accurately and reliably measure highly reflective liquids, clear liquids and even turbulence liquids. Due to its narrow beam divergence, it can be used to measure through grates and narrow passages, and even next to flat walls.

Principle of Operation

The Hawk OptioLaser S300 are user configurable and can be tuned to your specific application. The device uses an infrared, low-gain GaAs laser diode, which allows light energy of 905 nm. to travel to the surface of any liquid and is reflected back. This time-off-light (the time the laser pulse took to travel to the liquid and back) is then calculated into a distance. The low-gain diode allows for accurate measurement of even highly reflective, clear liquids, irrespective of the media dielectric properties. The narrow beam divergence of 3 milliradians (equal to 3ft at 1000ft) allows for easy installation, even near walls or thru narrow passages.

The OptioLaser S300 has strong appeal and wide application in the water, waste water, chemicals processing, food and beverage industries.

Read more about the OptioLaser S300 Laser measurement system by reviewing the embedded document below or you can download the "Optio S300 Liquid Laser Series for Fluid Level Measurement" PDF here.

For questions or application assistance, contact Power Specialties by visiting https://powerspecialties.com or by calling (816) 353-6550.

Optio S300 Liquid Laser Level Series Fluid Level Measurement from Power Specialties, Inc.

Power Specialties: Trust, Experience, Knowledge

In today’s industrial marketplace, it’s all about trust. Power Specialties earns your trust every day. From providing strong technical sales professionals who get your project done on time and on budget, to offering a select group of the most trusted and respected names in process control, Power Specialties continuously exceeds customer expectations.

https://powerspecialties.com
(816) 353-6550

Moisture Measurement in Sugar Production

Moisture detection in sugar production.

The sugar industry processes sugar cane and sugar beets to manufacture edible sugar. To achieve high quality sugar, improve efficiency and keep production cost in check, moisture detectors are employed to deliver accurate moisture analysis during several stages of the process.

Typical processes are as follows;

Washing/Preparation/Extraction

Sugar cane:

• Milling with water, extracting raw juice -> purification

Sugar beet: 

• Diffusing with hot water, extracting raw juice -> purification. 

Purification / Refining

• Crystallized sugar after purification is called "raw sugar". Raw sugar is then dried and may be further refined before bagging for shipment. 

CHINO's IM Series online system can measure moisture to maintain product consistency as well as energy efficiency at the following parts of the sugar manufacturing process.

Moisture measurement of "Bagasse" (fiber residue of the canes).

• 10% - 40% (Accuracy: +/- 0.5%) 
• Bagasse is mainly used as a biofuel, renewable resource in the pulp, paper products and building materials.

Moisture measurement of "used cossettes" (sliced beets used for diffusion).

• 30% - 70% (Accuracy: +/- 0.5%)
• Used cossettes are dried and sold as animal feed

Moisture control of raw sugar and during refinery

• IM Series is equipped w/ 4-20mA analog output which can be easily incorporated with existing process control systems.

For more information, visit Power Specialties at https://www.powerspecialties.com or call (816) 353-6550.

Process Control Experts - Power Specialties, Inc.

Established in 1967, Power Specialties was founded on the concept that customer service is of primary importance. Our staff of Sales Engineers are well trained in the application and selection of instrumentation and control products. Specializing in providing instrumentation and control solutions for industry:

• Ethanol / BioFuel
• Agricultural and Specialty Chemical
• Power
• Pharmaceutical
• Manufacturing
• Oil and Gas Production

Visit http://www.powerspecialties.com or call (816) 353-6550.

Magnetic Flowmeters: Principles and Applications

Magnetic flowmeter (Yokogawa)

Crucial aspects of process control include the ability to accurately determine qualities and quantities of materials. In terms of appraising and working with fluids (such as liquids, steam, and gases) the flowmeter is a staple tool, with the simple goal of expressing the delivery of a subject fluid in a quantified manner. Measurement of media flow velocity can be used, along with other conditions, to determine volumetric or mass flow. The magnetic flowmeter, also called a magmeter, is one of several technologies used to measure fluid flow.

In general, magnetic flowmeters are sturdy, reliable devices able to withstand hazardous environments while returning precise measurements to operators of a wide variety of processes. The magnetic flowmeter has no moving parts. The operational principle of the device is powered by Faraday's Law, a fundamental scientific understanding which states that a voltage will be induced across any conductor moving at a right angle through a magnetic field, with the voltage being proportional to the velocity of the conductor. The principle allows for an inherently hard-to-measure quality of a substance to be expressed via the magmeter. In a magmeter application, the meter produces the magnetic field referred to in Faraday's Law. The conductor is the fluid. The actual measurement of a magnetic flowmeter is the induced voltage corresponding to fluid velocity. This can be used to determine volumetric flow and mass flow when combined with other measurements.

The magnetic flowmeter technology is not impacted by temperature, pressure, or density of the subject fluid. It is however, necessary to fill the entire cross section of the pipe in order to derive useful volumetric flow measurements. Faradayís Law relies on conductivity, so the fluid being measured has to be electrically conductive. Many hydrocarbons are not sufficiently conductive for a flow measurement using this method, nor are gases.

Magmeters apply Faradayís law by using two charged magnetic coils; fluid passes through the magnetic field produced by the coils. A precise measurement of the voltage generated in the fluid will be proportional to fluid velocity. The relationship between voltage and flow is theoretically a linear expression, yet some outside factors may present barriers and complications in the interaction of the instrument with the subject fluid. These complications include a higher amount of voltage in the liquid being processed, and coupling issues between the signal circuit, power source, and/or connective leads of both an inductive and capacitive nature.

In addition to salient factors such as price, accuracy, ease of use, and the size-scale of the flowmeter in relation to the fluid system, there are multiple reasons why magmeters are the unit of choice for certain applications. They are resistant to corrosion, and can provide accurate measurement of dirty fluids ñ making them suitable for wastewater measurement. As mentioned, there are no moving parts in a magmeter, keeping maintenance to a minimum. Power requirements are also low. Instruments are available in a wide range of configurations, sizes, and construction materials to accommodate various process installation requirements.

As with all process measurement instruments, proper selection, configuration, and installation are the real keys to a successful project. Share your flow measurement challenges of all types with a process measurement specialist, combining your process knowledge with their product application expertise to develop an effective solution.

Fieldbus Equipped Process Control Instrumentation: Part One of Two

(Image courtesy of Lessons in Industrial Instrumentation
and Tony R. Kuphaldt and shared under Creative Commons
4.0 International Public License).

Autonomous control and digital instrumentation are two capabilities enabling highly precise or complex execution of process control functions. FOUNDATION fieldbus instrumentation elevates the level of control afforded to digital field instrumentation where, instead of only communicating with each other, instruments involved in particular process control systems can independently facilitate algorithms typically reserved for instruments solely dedicated to controlling other instruments. Fieldbus capable instrumentation has become the standard instrumentation for many process industry installations due to the fact the FOUNDATION design principle streamlines process systems. A large contributor to FOUNDATION's success has been faster installation as opposed to operational controllers which do not feature the fieldbus configuration. Newer process companies, or process control professionals seeking to establish a new system, have gravitated towards fieldbus due to the combined advantages of system conciseness and ease of implementation.

In a typical digital control system, dedicated controllers communicate with field instrumentation (the HART protocol is a prime example of digital communication at work in the industry). The host system controls configuration of instruments and serves as a central hub where all relevant control decisions are made from a single dedicated controller. Typically, these networks connect controllers and field devices through coupling devices and other "buses" which streamline many different instruments into a complete system.

FOUNDATION fieldbus approaches the same network scheme with an important difference. Whereas in a legacy or more conventional system, either algorithmic or manual decisions would need to be implemented via the dedicated system level controllers, instruments utilizing FOUNDATION fieldbus architecture can execute control algorithms at the local device level. The dedicated controller hub is still present, so that operators can view and monitor the entire network concurrently and make status changes. Algorithmic execution of control functions becomes entirely device reliant thanks to the FOUNDATION protocol. Additionally, even though FOUNDATION implements an advanced configuration, some operators use the capabilities introduced in the fieldbus upgrade to implement specific algorithms via each device while concurrently maintaining algorithms in the central controller. This dual algorithmic configuration allows for several advantages, including the ability for increased system precision.

Since individual devices in the control process are calibrated and able to execute their own control functions, issues in the process with particular devices can be isolated and dealt with in a more specified manner by technicians using the instruments in the field. The central operator retains the capacity to use the control hub to alter and direct the control system.

Stay tuned for Part Two.

Contact Power Specialties with any process instrumentation, or field device communication question you may have. Visit http://www.powerspecialties.com or call (816) 353-6550.

Basics of Pressure Measurement: Hydrostatic Pressure

Pressure transmitter
(Yokogawa)

Pressure measurement is an inferential way to determine the height of a column of liquid in a vessel in process control. The vertical height of the fluid is directly proportional to the pressure at the bottom of the column, meaning the amount of pressure at the bottom of the column, due to gravity, relies on a constant to indicate a measurement. Regardless of whether the vessel is shaped like a funnel, a tube, a rectangle, or a concave polygon, the relationship between the height of the column and the accumulated fluid pressure is constant. Weight density depends on the liquid being measured, but the same method is used to determine the pressure.

A common method for measuring hydrostatic pressure is a simple gauge. The gauge is installed at the bottom of a vessel containing a column of liquid and returns a measurement in force per unit area units, such as PSI. Gauges can also be calibrated to return measurement in units representing the height of liquid since the linear relationship between the liquid height and the pressure. The particular density of a liquid allows for a calculation of specific gravity, which expresses how dense the liquid is when compared to water. Calculating the level or depth of a column of milk in a food and beverage industry storage vessel requires the hydrostatic pressure and the density of the milk. With these values, along with some constants, the depth of the liquid can be calculated.

Tank level transmitter
(Yokogawa)

The liquid depth measurement can be combined with known dimensions of the holding vessel to calculate the volume of liquid in the container. One measurement is made and combined with a host of constants to determine liquid volume. The density of the liquid must be constant in order for this method to be effective. Density variation would render the hydrostatic pressure measurement unreliable, so the method is best applied to operations where the liquid density is known and constant.

Interestingly, changes in liquid density will have no effect on measurement of liquid mass as opposed to volume as long as the area of the vessel being used to store the liquid remains constant. If a liquid inside a vessel that’s partially full were to experience a temperature increase, resulting in an expansion of volume with correspondingly lower density, the transmitter will be able to still calculate the exact mass of the liquid since the increase in the physical amount of liquid is proportional to a decrease in the liquid’s density. The intersecting relationships between the process variables in hydrostatic pressure measurement demonstrate both the flexibility of process instrumentation and how consistently reliable measurements depend on a number of process related factors.

Contact Power Specialties at (816) 353-6550 or visit http:powerspecialties.com with any industrial pressure measurement application of requirement.

Wireless Instrumentation In Process Measurement and Control

Wireless Instrumentation (Yokogawa)

In process control, various devices produce signals which represent flow, temperature, pressure, and other measurable elements of the process. In delivering the process value from the measurement point to the point of decision, also known as the controller, systems have traditionally relied on wires. More recently, industrial wireless networks have evolved, though point-to-point wireless systems are still available and in use. A common operating protocol today is known as WirelessHART^TM, which features the same hallmarks of control and diagnostics featured in wired systems without any accompanying cables.

Wireless devices and wired devices can co-exist on the same network. The installation costs of wireless networks are decidedly lower than wired networks due to the reduction in labor and materials for the wireless arrangement. Wireless networks are also more efficient than their wired peers in regards to auxiliary measurements, involving measurement of substances at several points. Adding robustness to wireless, self-organizing networks is easy, because when new wireless components are introduced to a network, they can link to the existing network without needing to be reconfigured manually. Gateways can accommodate a large number of devices, allowing a very elastic range for expansion.

In a coal fired plant, plant operators walk a tightrope in monitoring multiple elements of the process. They calibrate limestone feed rates in conjunction with desulfurization systems, using target values determined experientially. A difficult process environment results from elevated slurry temperature, and the associated pH sensors can only last for a limited time under such conditions. Thanks to the expandability of wireless transmitters, the incremental cost is reduced thanks to the flexibility of installing new measurement loops. In regards to maintenance, the status of wireless devices is consistently transmitted alongside the process variable. Fewer manual checks are needed, and preventative measures may be reduced compared to wired networks.

Time Synchronized Mesh Protocol (TSMP) ensures correct timing for individual transmissions, which lets every transmitter's radio and processor "rest" between either sending or receiving a transmission. To compensate for the lack of a physical wire, in terms of security, wireless networks are equipped with a combination of authentication, encryption, verification, and key management. The amalgamation of these security practices delivers wireless network security equal to that of a wired system. The multilayered approach, anchored by gateway key-management, presents a defense sequence. Thanks to the advancements in modern field networking technology, interference due to noise from other networks has been minimized to the point of being a rare concern. Even with the rarity, fail-safes are included in WirelessHART^TM.

All security functions are handled by the network autonomously, meaning manual configuration is unnecessary. In addition to process control environments, power plants will typically use two simultaneous wireless networks. Transmitters allow both safety showers and eyewash stations to trigger an alarm at the point of control when activated. Thanks to reduced cost, and their ease of applicability in environments challenging to wired systems, along with their developed performance and security, wireless industrial connectivity will continue to expand.

For more information on wireless instrumentation, review the document below. Please feel free to call Power Specialties at (816) 353-6550 to speak with an applications specialist.

Yokogawa Field Wireless Solution from Power Specialties, Inc.

New Power Specialties Company Video

Here is a new, short, introductory video about Power Specialties.

Celebrating our 50th year in business, Power Specialties was founded on the concept that customer service is of primary importance. Our staff of Sales Engineers are well trained in the application and selection of instrumentation and control products. Specializing in providing instrumentation and control solutions for industry:

• Ethanol / BioFuel 
• Agricultural and Specialty Chemical 
• Power 
• Pharmaceutical 
• Manufacturing 
• Oil and Gas Production

Yokogawa Pressure Handbook: A Basic Guide to Understanding Pressure

Pressure, temperature, level and flow are the four common plant measurements. Of the four, pressure is the most fundamental and common. The three remaining measurements can be inferred from pressure-flow (orifice plates, pitot tube, venturi), level (hydrostatic ‘Head’ pressure), and temperature (pressure thermometer). It can even be used to infer density (pressure for a given volume) and weight (load cells). If you cannot measure it, you cannot control it.

The ability to quickly, accurately, and reliably measure pressure is invaluable when trying to control a process.

Each of these types of transmitters measures pressure. The ow transmitter, liquid level transmitter, and pressure thermometer use the measured pressure to infer another process parameter.

Read the handbook below to garner a great understanding of industrial pressure measurement.

Yokogawa Pressure Handbook: A Basic Guide to Understanding Pressure from Power Specialties, Inc.

For more information on any industrial pressure requirement, visit http://www.powerspecialties.com or call (816) 353-6550.

Dynamic Compensation for Static Pressure Effects in Differential Pressure Measurement

Yokogawa DPharp

Attaining the best available performance and accuracy from any measuring device utilized in an industrial process is always advantageous. The scale of most industrial processes is such that even small inaccuracies in process measurement produce financially tangible impact. Differential pressure measurement, with wide application in the industrial process sphere, can be improved with the addition of a means to compensate for the real world effects of static pressure upon instrument performance.

Yokogawa Corporation has developed a means to dynamically compensate for static pressure effects in field measurements. The brief technical presentation below will help you understand how static pressure effects can impact your field measurements, as well as how Yokogawa’s Real-time Dynamic Compensation works to offset its impact.

More detailed product and application information is available from your Yokogawa specialist.

Yokogawa DPharp EJX and EJA from Power Specialties, Inc.

Improve Your Operations: Partner with Power Specialties

And now for a little harmless self-promotion ...

Power Specialties Intro Video

Here's a new video introducing Power Specialties, Inc.

Fundamentals of pH Control in Industrial, Municipal, and Commercial Applications

Handheld pH Meter & Sensor
(courtesy of Yokogawa)

Analytical measurement and control of pH within a system is necessary for many processes. Common applications include food processing, wastewater treatment, pulp & paper production, HVAC, power generation, and chemical industries.

To maintain the desired pH level in a solution, a sensor is used to measure the pH value. If the pH is not at the desired set point, a reagent is applied to the solution. When a high alkaline level is detected in the solution, an acid is added to decrease the pH level. When a low alkaline level is detected in the solution, a base is added to increase the pH level. In both cases the corrective ingredients are called reagents.

Accurately applying the correct amount of reagent to an acid or base solution can be challenging due to the logarithmic characteristics a pH reaction in a solution. Implementing a closed-loop control system maintains the pH level within a certain range and minimizes the degree to which the solution becomes acidic or alkaline.

An example of an automatic pH level control system is a water treatment process where lime softened water is maintained at a pH of 9, using carbon dioxide as a reagent. As the untreated water (or influent) enters the tank, the pH is continuously monitored by the pH sensor. The sensor is the feedback device to the controller where the setpoint is compared to the control value. If the values are not equal, the controller sends a signal to the control valve that applies carbon dioxide to the tank. The reagent is applied to the tank at varying rates to precisely control the pH level. With the pH level at 11 detected by the sensor, the controller commands the control valve to open and introduce more carbon dioxide. As the increased carbon dioxide mixes with the influent, the pH is lowered in a controlled manner. Reaching the setpoint, the carbon dioxide flow is minimized and the process is continually monitored for variation. The effluent is the treated water that is discharged out of the tank. The process continues to provide the lime softened water at the desired pH level.