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TechNewsBites 2 - 2023   The TOP 5 CODESYS Corporation TechNewsBites 2-2023 are an opportunity to share – with your team, colleagues, and customers. Our new ‘TechNewsBites' format includes exciting new features of CODESYS products and exclusive information from CODESYS Corporation. And today we have the pleasure to introduce two new CODESYS System Partners. CODESYS System Partners are experts helping to program your CODESYS project.

NEW CODESYS SYSTEM PARTNER IO AUTOMATON LLC - specialized in the Process Automation

IO Automation LLC is a trusted system integrator and service provider based in Fishers, IN. IO Automation LLC is specialzed in the Process Industry. They partner with clients through each development stage of the system, providing deep expertise in CODESYS system integration, training, maintenance, and overall support. For more information on IO Automation LLC, please visit I/O. CODESYS System Partners provide the following services: Consulting Training Application Development System Integration Please visit our WEB site to learn more about CODESYS System Partners and what they can do for you.

NEW CODESYS SYSTEM PARTNER   NOA - specialized in Robotics

NOA is a trusted system integrator and service provider based in Aguascalientes, MEXICO. Specializing in the Robotic Industry, NOA partners with clients through each development stage of the system, providing deep expertise in CODESYS system integration, training, maintenance, and overall support. For more information on NOA, please visit NOA. CODESYS System Partners provide the following services: Consulting Training Application Development System Integration Please visit our WEB site to learn more about CODESYS System Partners and what they can do for you.

CODESYS Safety SIL2 Extensive update for CODESYS Safety SIL2 New CODESYS Safety products according to IEC 61508: Pre-certified solution for Infineon CPU Aurix TC 39x and J1939 protocol library

The CODESYS IEC 61131-3 automation suite is well-established in numerous industrial sectors, including the fields of mobile machines and automated embedded systems. With the CODESYS Safety SIL2 add-on, manufacturers are able to certify their CODESYS-based control units, ECUs and PLCs for safety applications according to IEC 61508 for SIL2 or EN ISO 13849 up to PLd with significantly reduced effort. A new feature is a pre-certification of the safety software for the Infineon CPU Aurix TC39x. With this solution, the safety application can be processed separately from the functional part on its own CPU core.  The package includes: CODESYS Control Toolkit for implementing the runtime system on the target device, add-on for the IDE, fully customized and certificated project files for the Aurix platform, safety documentation including integration testing to verify compliance with the functional safety requirements during final certification. The PSP for the Aurix TC39x is able to save device manufacturers up to 4 years of development work when implementing a safety controller. Another new feature of CODESYS Safety SIL2 is the CAN communication of safety-critical data in accordance with SAE J1939 Safety. CODESYS J1939 Safety is the world's first implementation of CAN safety protocol for ECUs, including for use in mobile machines. The protocol stack was implemented in the form of a device-independent CODESYS library. It is compiled together with the control project for the specific target system. The data is transferred to other participants by explicitly calling POUs within the application. This makes the use more flexible.  (Courtesy of Codesys)

Operationalizing Engineering Statistics: Why Apply Statistical Analysis in Process Control?

Statistical analysis empowers process manufacturers to spend less time preparing data and more time acting on the right issues.

Many process manufacturers today are fixing their gaze on two modern focal points—overall equipment effectiveness (OEE) and sustainability. OEE is driven by improved reliability, quality, and production yield, and sustainability is driven by efficient supply chains, minimal energy usage, and reduced emissions. While improving each of these key metrics requires time and effort, advanced analytics tools involving statistics, process control, and monitoring—collectively referred to as statistical analysis—make this more achievable.

Statistical analysis enables teams to standardize their approach to data and decision-making by detecting anomalies early and often to minimize waste and limit the cost of poor production quality. These tools can also identify ideal operating ranges to maximize yield and reduce raw material and energy usage.

When applied properly, statistical analysis empowers manufacturing teams to spend less time preparing data and more time acting on the right issues, helping meet production and sustainability goals. In a recent webinar, we discussed four methods for operationalizing engineering statistics using Seeq, which are summarized below.

1. Build Statistical Process Control (SPC) Charts

The greatest challenge organizations encounter when creating SPC charts is implementing automatic updates across numerous product operations. Whether this entails multiple modes of operations or multiple product types, the calculation of statistical boundaries is highly variable, making the segmenting, or “slicing-and-dicing,” of data a headache for data analysts and process experts.

Seeq simplifies this process by empowering users to perform these calculations using its live data source connectivity. SPC charts are created in a dynamic fashion, with the ability to add context, segment data sets, apply correct limits to correct operating modes, and create aggregated signals for monitoring control parameters.

As a best practice, users should check for normalcy amongst the data prior to creating charts. Seeq’s histogram tool provides data visualization, making it easy to check the frequency of distribution for sample values. With different modes of operation, users can leverage capsules to embed the grade code context into the histogram to gain a better understanding of its distribution.

Once normalcy is verified amongst the data set, users can begin calculating statistical boundaries based on periods when the process is in-control. One way to do this is by specifying in-control time periods and using that data to calculate the averages and standard deviations.

 

Users can create standard deviation limits for their SPC charts.

Leveraging these calculations, users can create control limits using Seeq Formula, and deploy them in near-real time to monitor current process performance. 

2. Create Run Rules & Identify Violations 

The next step is operationalizing SPC run rules, which can identify anomalies and alert teams when data is outside of control limits. This provides production teams with a method for interpreting near real-time data in a uniform way. 

The best way to create run rules is with the User Defined Formula Functions Editor Add-on in Seeq. This Add-on enables users to create custom formulas so they can scale run rules more easily across product operations, and create better uniformity in decision-making processes. 

Add-on tools can be found in the Seeq Add-on Gallery for use in Seeq Workbench and Seeq Data Lab, with installation instructions and user guides also available. 

Users can view run rule violations within an Organizer Topic.

Once run rules are defined, users can view violations within a Seeq Organizer Topic where several different trends, tables, and histograms from the Workbench analysis can be compiled into a single dashboard that automatically updates. Manufacturers can monitor current run progress in addition to historical performance by viewing the Topic. 

3. Process Capability Analysis: Cpk and Ppk

In many organizations, capability analysis is performed infrequently due to the considerable time required by process engineers and data analysts to make associated calculations. But Seeq asset groups can be set up to automatically calculate Cpks and Ppks, making frequent analyses more feasible.  

With the Cpk calculated, users can view a graphical representation within Workbench. 

Seeq asset groups can be used to correlate assets with different product types. Users can perform a Cpk calculation on one product grade, then rapidly scale it across multiple product grades. The use of rolling conditions ensures the data is updated in near-real time for continuous analysis.

 Users can perform Cpk calculations on one product grade, then rapidly scale it across multiple product grades.

With the most up-to-date information, teams can leverage the data to inform business decisions.

4. Analysis of Variance (ANOVA) 

Users can also create statistical analyses and plots, such as an ANOVA to compare variances across means, in Seeq Data Lab. Traditionally, data preparation for statistical analysis was static. Configuring it properly was extremely time-consuming, and updating analyses as new information became available was near-impossible. 

Seeq’s connection to disparate data sources and automated data alignment simplifies the data preparation process so users can more easily view time periods of interest. It also empowers engineers, data scientists, and production groups to collaborate more easily across functional teams and among multiple data repositories. This results in less time spent gathering and preparing the data, providing more time spent pursuing valuable business objectives. 

Seeq Data Lab, which brings Python and Seeq together using Jupyter Notebooks, provides the option to use the custom SPy or Seeq Python library to push, pull, and manipulate data. Using Data Lab, users can build out statistical analyses using their desired Python libraries, and can create their own Add-on tools to simplify commonly used workflows and create seamless collaboration. 

To begin, users open a Jupyter Notebook and import the custom SPy library to pull in data and manipulate it. Spy.search is used to find data, and spy.pull is used to pull in signal and condition data during the desired timeframe. Asset groups can then be created in Workbench to organize and contextualize data prior to processing in Data Lab. 

Once data is loaded into Data Lab, the data frame can be formatted, in this case using the Pandas library, for use in creating an ANOVA plot and table. By creating a simple Add-on in Workbench, users can operationalize the workflow and send it to an Organizer Topic. 

ANOVA Plot viewed in Organizer Topic.

Start Operationalizing Your Engineering Statistics

So, what are you waiting for? Download the full webinar today to view these methods in action, and begin operationalizing your engineering statistics to meet organizational objectives, like improved OEE and sustainability.

(Courtesy of Seeq and Written by: Katie Pintar)

Yokogawa Releases OpreX Magnetic Flowmeter CA Series

- New user-friendly functions that enhance maintainability and operational efficiency -

Yokogawa Electric Corporation (TOKYO: 6841) announces the release of the OpreX^TM Magnetic Flowmeter CA Series. This new product series succeeds the ADMAG CA Series and is being released as part of the OpreX Field Instruments family. The products in this new series are all capacitance-type magnetic flowmeters that are capable of measuring the flow of conductive fluids through a measurement tube without the fluids coming into contact with the device's electrodes. In addition to this non-wetted electrode construction, this series features new functions that improve user-friendliness, maintainability, and operational efficiency.

The new series is available from today in most major markets such as Japan, Southeast Asia, North and South America, Oceania, the Middle East and Africa, and will also be launched in Europe and China after qualifying for CE marking and obtaining the relevant certification for explosion-proof standards.

OpreX Magnetic Flowmeter CA Series
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Development Background

In plants, inspection is required for each instrument in order to maintain stable operation and product quality, so the efficiency of such inspections is an ongoing issue for production sites. As magnetic flowmeters have no structural components that hinder the flow of fluids and cause a loss in fluid pressure, they are widely used in plants to measure fluids with conductive properties. Large chemical plants and other such facilities can have hundreds of these instruments, and so it is important that their inspection and replacement as well as the collection of the data from each of these devices can be carried out efficiently. In response to these needs, Yokogawa has revamped the ADMAG CA lineup of flowmeters, which were first released in 1995 and have been widely adopted by customers mainly in Japan, and developed the OpreX^TM Magnetic Flowmeter CA Series, equipped with features to improve operational efficiency and maintainability, for release in a wide range of regions. This will help reduce the person-hours required for customer instrument inspections and contribute to improved plant operational efficiency.

Features of the OpreX Magnetic Flowmeter CA Series

Capacitance-type magnetic flowmeters utilize electrodes that are mounted outside a ceramic measurement tube to measure the electromotive force generated by fluids passing through the tube, eliminating all direct contact between the electrodes and the fluid. This ensures stable flow measurement of fluids containing minerals that generate electrical noise when they collide with an electrode; fluids such as latex, a sticky insulating fluid that can adhere to the inside surfaces of pipes; and fluids such as deionized water and mizuame (millet jelly) that have low conductivity.

In addition to this non-wetted electrode construction, the newly released OpreX Magnetic Flowmeter CA Series has the following new features:

1. New and useful functions that improve user-friendliness and operational efficiency
   Support for the widely used HART communications protocol has also been added, and a choice of nine languages is now given for the user interface, enabling swift and stress-free checking of displayed information. As an optional feature, measurement data can be saved on a microSD card for viewing on a PC, and instrument setting data that is saved on a microSD card can be copied to other devices. The display is now equipped with a backlight function that greatly improves visibility at night and in dark locations.
2. A device soundness analysis function that improves maintainability
   Products in this series are equipped with a function that can analyze and verify that they are in sound operating condition while mounted on a pipe. Inspection of magnetic circuits, excitation circuits, and arithmetic circuits, and the checking of device status alarms and soundness can be performed in as little as six minutes. When used in combination with Yokogawa’s FSA130 software (sold separately) and other maintenance tools, many additional items can be checked while a device is mounted on a pipe, and reports can be easily created.
3. Easily replaceable measurement tubes suiting a wide variety of purposes
   Measurement tubes in eight sizes ranging from 15mm to 200mm are available for use with these flowmeters, suiting a wide range of purposes. As they have the same face-to-face lengths^* as the ADMAG CA Series flowmeters, no additional work is required to replace an ADMAG CA Series flowmeters with a product from the OpreX Magnetic Flowmeter CA Series.

* The length from end face to end face required to mount a magnetic flowmeter on a pipe

Major Target Markets

Chemicals, paper and pulp, mining, food and beverages, water and sewerage

Main Uses

Flow measurement for fluids with the following properties

• Fluids with insulators that are prone to adhering to measurement tubes
• Fluids that include high-density slurry (solids)
• Fluids with low electrical conductivity

About OpreX

OpreX is the comprehensive brand for Yokogawa's industrial automation (IA) and control business. The OpreX name stands for excellence in the technologies and solutions that Yokogawa cultivates through the co-creation of value with its customers, and encompasses the entire range of Yokogawa's IA products, services, and solutions. This brand comprises the following five categories: OpreX Transformation, OpreX Control, OpreX Measurement, OpreX Execution, and OpreX Lifecycle. The OpreX Magnetic Flowmeter CA Series belongs to the OpreX Field Instruments family, which is aligned under the OpreX Measurement category. The OpreX Measurement category includes field equipment and systems for highly precise measurement, data collection, and analysis.

About Yokogawa

Yokogawa provides advanced solutions in the areas of measurement, control, and information to customers across a broad range of industries, including energy, chemicals, materials, pharmaceuticals, and food. Yokogawa addresses customer issues regarding the optimization of production, assets, and the supply chain with the effective application of digital technologies, enabling the transition to autonomous operations.

Founded in Tokyo in 1915, Yokogawa continues to work toward a sustainable society through its 17,000+ employees in a global network of 122 companies spanning 61 countries. For more information, visit www.yokogawa.com 

(Courtesy of Yokogawa)

Yokogawa to Release CENTUM VP R6.10

Yokogawa to Release CENTUM VP R6.10 Integrated Production Control System to Enable the Control of Steam Turbine Control for Compressor Drive and the Integrated Control of Multiple Compressor Trains

- Expands the functionality of CCC Inside™ for Yokogawa CENTUM VP -

Yokogawa Electric Corporation (TOKYO: 6841) announces that on December 13, it will be releasing CENTUM VP R6.10, a new version of the flagship Yokogawa integrated production control system in the OpreX Control and Safety System lineup that enables the steam turbine control for compressor drive and the integrated control of multiple compressor trains*. With this release, new functionality is enabled for the CCC Inside^TM for Yokogawa CENTUM VP solution that was jointly developed by Compressor Controls LLC (CCC) and Yokogawa. In addition to allowing process control and turbomachinery control to be carried out on the same CENTUM VP system, the scope of control that can be performed with a single system has been extended, allowing the streamlining not only of operations, but also of engineering, procurement, and maintenance.

* Compressor train: multiple compressors and a motor or steam turbine to drive the compressors connected to a shaft.

Development Background

Conventionally, different systems have been used to control processes and the large number of turbomachines found in plants, meaning users had to manage and operate multiple systems. To address this issue, Yokogawa worked with CCC to develop CCC Inside^TM for Yokogawa CENTUM VP. Released in November 2021, this solution enables CENTUM VP to control both processes and turbomachinery.

For the many different steam turbines and compressor trains that are found in plants, customers want to be able to expand the scope of control and streamline operations, engineering, and maintenance by using a single production control system. To enable the steam turbine control for compressor drive and integrated control of compressor trains and expand the scope of control with CCC Inside^TM for Yokogawa CENTUM VP, Yokogawa has developed this latest release of the CENTUM VP system.

Main Features

1. Expanded scope of control with support for steam turbine control for compressor drive
   With this release, it is now possible for CCC control algorithms running on CENTUM VP to control steam turbines for compressor drive. This allows whole compressor system which contains steam turbine control to be monitored and controlled from the same human-machine interface (HMI) used for conventional process control. The ability to use the same hardware to perform these functions simplifies engineering, procurement, and maintenance, reduces the need for spare parts, lowers maintenance costs, and helps to reduce the workload for maintenance planning and implementation.

   
   Image of integrated human-machine interface of CCC Inside^TM for Yokogawa CENTUM VP
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2. Optimization through the integrated control of multiple compressor trains
   
   Yokogawa has enabled the control of multiple compressor trains, of which many can be found in customers' plants, by working with CCC to develop a function block for the integrated control of multiple compressor trains, and has realized overall optimized control through the distribution of the compressor load.

Major Target Markets

Oil and gas, petrochemicals, chemicals, electric power, etc.

Main Uses

Control of steam turbine control for compressor drive and the integrated control of multiple compressor trains

About CCC Inside^TM

CCC Inside^TM was developed to deploy CCC control algorithms and expertise into DCS platforms. The control algorithms are based on the same code structure of CCC Pro Built^TM platforms, maintaining consistency and reliability. CCC Inside is delivered with native human machine interfaces for the DCS operator station and direct integration with the alarm system. CCC Engineering Utilities further facilitate configuration and tuning, with high-resolution recording capabilities. CCC Inside is engineered and commissioned by CCC global project and field service teams.

About the CENTUM series

Yokogawa released its CENTUM distributed control system (DCS) in 1975, a world first. CENTUM VP is the ninth generation in the CENTUM series. Known for their rugged performance, CENTUM systems set high standards for engineering and technology excellence while ensuring backwards compatibility with previous system versions and support of the latest technology applications. Knowledge-driven engineering lies at the heart of CENTUM, a Yokogawa flagship product that has been proudly serving the process industry over the past 40+ years.

About OpreX

OpreX is the comprehensive brand for Yokogawa's industrial automation (IA) and control business. The OpreX name stands for excellence in the technologies and solutions that Yokogawa cultivates through the co-creation of value with its customers, and encompasses the entire range of Yokogawa's IA products, services, and solutions. This brand comprises the following five categories: OpreX Transformation, OpreX Control, OpreX Measurement, OpreX Execution, and OpreX Lifecycle. One of the product groups that make up the OpreX Control category is the OpreX Control and Safety System family, which includes the CENTUM VP DCS. With its various OpreX Control solutions, Yokogawa is able to quickly effect changes for its customers that lead to a transformation in such areas as management and operations, and provides highly reliable control technology that ensures high efficiency, high quality, and safe and stable plant operations.

With the OpreX brand, Yokogawa will deliver integrated solutions that address specific needs and support its customers in their efforts to transform and grow their businesses.

About Yokogawa

Yokogawa provides advanced solutions in the areas of measurement, control, and information to customers across a broad range of industries, including energy, chemicals, materials, pharmaceuticals, and food. Yokogawa addresses customer issues regarding the optimization of production, assets, and the supply chain with the effective application of digital technologies, enabling the transition to autonomous operations.

Founded in Tokyo in 1915, Yokogawa continues to work toward a sustainable society through its 17,000+ employees in a global network of 122 companies spanning 61 countries.

For more information, visit www.yokogawa.com 

(Courtesy of Yokogawa)

Yokogawa Adds ZR802S Explosion-proof Converter to OpreX Analyzers Lineup

 – Features sensor self-assessment and data logging functions that significantly reduce operating costs –

Yokogawa Electric Corporation (TOKYO: 6841) announces that it has developed the ZR802S explosion-proof converter and will be releasing it for sale as part of its OpreX Analyzers lineup in all markets on December 12. The ZR802S converter supports the IECEx, FM, ATEX, CSA, China Ex, Korea Ex, India Ex, and Taiwan Ex explosion-proof standards. It is intended for use with the ZR22S explosion-proof zirconia oxygen detector, an existing Yokogawa product with a highly durable zirconia sensor that is highly dust resistant and easy to install and replace. Together, the ZR802S converter and the ZR22S detector comprise a complete oxygen analyzer system.

The new ZR802S converter and the ZR22S detector (foreground)
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Development Background

Plant operators need to increase operational efficiency by improving uptime and introducing labor-saving measures, and thus are looking to decrease the likelihood of instrument failures that can lead to plant stoppages or a deterioration in product quality, and to eliminate the need to perform on-site inspections of instruments.

As such, Yokogawa has sought with its zirconia oxygen concentration analyzers to introduce remote monitoring and other capabilities that reduce the time and effort required for maintenance operations and increase uptime. The ZR802S converter features a self-assessment function that provides early detection of deterioration in a zirconia oxygen detector, a data logging function that records essential maintenance information, and support for a number of key communication protocols. It is expected that these innovations will help to significantly reduce OPEX.

Features

1. Automatic transmission of sensor resistance value at regular intervals, enabling replacement timing to be determined without on-site inspection
   Up to now, assessment of sensor deterioration by checking the sensor resistance value has normally been carried out whenever maintenance personnel went on site to perform calibration. As this work is usually performed on a scheduled basis at intervals of a month or more, it has not always been possible to spot problems in time, leading to sudden sensor breakdowns and decreased uptime. With its self-assessment function, the ZR802S converter is able to regularly measure the resistance value of the sensor in the ZR22S detector and send this data over a wired connection to the plant’s control system. Once an operator receives notification of a higher resistance value, which is an indication of deterioration in the sensor, maintenance personnel can take immediate action to correct the problem and prevent an instrument failure, thereby sustaining plant uptime.
    
2. Data logging function that helps to reduce maintenance time and downtime in the event of a fault
   The ZR802S converter can log up to 40 days of measurements, alarm on/off history, and sensor resistance trend graphs, among other data. As well as being able to directly display logs on the LCD screen, it is also possible to export the data using an SD card. In the event of a fault, it can determine whether it is due to the analyzer system or the distributed control system (DCS) by looking into differences with the data from the host device. This helps reduce maintenance time and the downtime required to find a solution.
    
3. Industry-first communication protocol support, meeting a range of needs and enabling cloud-based management
   The ZR802S converter is the only product in the zirconia oxygen analyzer market that supports all three of the following communication protocols: HART7 for analog output, and Modbus TCP and Modbus RTU for digital communications. It also complies with the NAMUR NE43 guideline for the issuance of signals to indicate a sensor fault and the NAMUR NE107 guideline for on-site instrument self-assessment functions. Using the ZR802S converter’s communication functions, cloud-based management is also possible, and this not only increases convenience in terms of data analysis and other such activities, it also enables operation with the minimum number of staff, making it suitable for a range of uses by customers in a variety of industries.
    
4. Support for multiple languages and provision of operational support
   In addition to Japanese and English, the device LCD can also be set to display information in French, German, Chinese, and Portuguese. Russian will be added in the near future. Furthermore, information on what steps should be taken in response to specific alarms can now be displayed on the LCD screen, enabling even less knowledgeable and experienced personnel to perform necessary maintenance.

Major Target Markets

Oil refining, petrochemicals, chemicals, electric power, steel

Uses

• Combustion management for heating furnaces and decomposition furnaces in the fields of oil refining, petrochemicals, and chemicals
• Combustion management for various types of furnaces, such as those used in steel production and waste incineration
• Combustion control for boilers at power plants

About OpreX

OpreX is a comprehensive brand in the control business. It represents the excellence of the technology and solutions that Yokogawa has cultivated through value co-creation with our customers, and encompasses all of Yokogawa's control-related products, services, and solutions. OpreX is composed of five categories of OpreX Transformation, OpreX Control, OpreX Measurement, OpreX Execution, and OpreX Lifecycle. The ZR802G converter belongs to the OpreX Analyzers family - one of the OpreX Measurement suite of products and solutions. OpreX Measurement refers to on-site devices and systems that enable high-precision measurements, data collection, and analysis.

Under this brand, Yokogawa provides its customers with integrated solutions that help them bring about reforms and accomplish growth by addressing specific business challenges.

About Yokogawa

Yokogawa provides advanced solutions in the areas of measurement, control, and information to customers across a broad range of industries, including energy, chemicals, materials, pharmaceuticals, and food. Yokogawa addresses customer issues regarding the optimization of production, assets, and the supply chain with the effective application of digital technologies, enabling the transition to autonomous operations. Founded in Tokyo in 1915, Yokogawa continues to work toward a sustainable society through its 17,000+ employees in a global network of 122 companies spanning 61 countries.

For more information, visit www.yokogawa.com 

(Courtesy of Yokogawa)

Redefining data center service with technology

 

Technological advancements in the field of service can play a crucial role in upholding uptime and reliability in data centers.

It is undeniable how digitalization has transformed and reshaped people’s way of life. It has introduced alternative means for communication and collaboration, increased transparency and insight on operational procedures and processes, and facilitated agility and productivity across various industries.

This important transformation, however, has placed an increased demand on uptime and efficiency for data centers, which serves as one of the primary drivers in an encompassing shift towards the use of digital technologies. The cost of outages in data centers has increased exponentially, a clear indication of how reliant individuals and industries have become on digital platforms and services.

With both revenue and reputation on the line, how can data centers ensure that uptimes remain up and outages stay out? The answer lies in preventive maintenance.

Why regular data center service is a must

Just like how car owners need to have their vehicle regularly tuned-up to make sure they run smoothly, data center operators must also conduct regular monitoring of their facilities, particularly mission-critical equipment, to guarantee the reliable provision of data services. The basic rule of thumb is that the more intensive the operations, the more regular service activities are needed to avoid unplanned outages.

More than just a tick on the to do list, preventive maintenance decreases the possibility of critical errors from occurring, especially in an environment as complex as a data center. More importantly, it safeguards the health and efficiency of mission-critical equipment that keeps data centers up and running. Suffice to say, the cost of regular service activities is far more reasonable compared to the financial and reputational expense of having to go offline due to system or equipment malfunction.

In addition, by keeping a close eye on system and equipment health, regular service procedures also uphold the health and safety of data center employees by preventing the occurrence of electrical hazards such as electrical explosions. A study from the Workplace Safety Awareness Council estimates the cost of an electrical accident to be at a minimum of $750,000 on top of litigation fees and medical costs for affected workers.

A technological approach to service

Thankfully, technology has paved the way for basic service tasks to be done safely, collaboratively, and more efficiently.

First, ABB offers a diverse portfolio of intelligent solutions that provide real-time insights that can help data center managers monitor equipment health and performance. This deep component-level visibility not only allows operators to optimize their processes to realize more efficient operations, but also encourages a more proactive maintenance strategy that can save time and resources.

For instance, ABB Ability Energy and Asset Manager  allows data center operators to have full remote visibility of asset and electrical-system behavior. Through this intuitive dashboard, data center managers can swiftly identify inefficiencies that can lead to excessive energy use and optimize equipment performance to ensure reliability and product quality. Aside from cutting back on energy usage and corresponding costs, the ABB Ability Energy and Asset Manager can also yield savings on unplanned labor, maintenance, and operational expenses.

To support the implementation of preventive maintenance measures and maximize data center productivity, especially in settings as intricate as data centers, ABB offers two innovative digital applications – Collaborative Operations for electrical systems (CLOSER) and Remote Assistance for electrical systems (RAISE) – to easily get support when needed and make troubleshooting much easier.

With their augmented reality visualization capacity, CLOSER and RAISE simplify maintenance, reduce downtime, and increase equipment effectiveness by improving the quality of repairs and speed of resolution.

CLOSER provides first-level support for ABB electrification solutions and products by offering detailed troubleshooting guides that can help data center workers in addressing basic component or equipment issues. CLOSER is accessible 24/7 to provide in-depth guidance through the different steps of key troubleshooting procedures.

If further assistance is needed, RAISE provides the next level of support by having an ABB service professional facilitating remotely guided repairs. RAISE reduces time to repair and maintain electrical equipment by allowing ABB experts to use augmented reality to remotely guide field operators on their Android or iOS smartphone, tablet, or via smart glasses and other supported wearables. This speed of resolution is vital in minimizing potentially highly disruptive and costly downtime. With time being of the essence in data centers, every second saved can make a big difference in productivity, profitability, and even sustainability, due to the reduced need for travel to and from the facility.

The beauty of RAISE is how it also helps data centers meet their sustainability targets through significant reduction in their carbon footprint. Using RAISE will save approximately 332 tons of carbon emissions per year by reducing up to a third of customer site visits by ABB field service engineers.

Now more than ever, data centers must take steps to operate efficiently, safely, and sustainably, as they play an important role in the global digital transformation. While this continues to be a challenge, making the shift from calendar-based to condition-based monitoring can be the first step towards realizing data center reliability. ABB’s digital portfolio, together with CLOSER and RAISE, can be your ideal partner in making this important step.

(Courtesy of ABB)

Emerson Launches Ovation Green, a Dedicated Renewable Power Technology and Software Portfolio

Ovation Green will help producers navigate the emerging sustainable energy economy

Emerson has combined its comprehensive power expertise and renewable energy capabilities into the Ovation™ Green portfolio to help power generation companies meet the needs of customers navigating the transition to green energy generation and storage. By uniting the recently acquired Mita-Teknik software and technology with its own industry-leading Ovation automation platform, deep renewable energy knowledge base, cybersecurity solutions and remote management capabilities, Emerson has created a new extension of its power-based control architecture. The resulting portfolio focuses on the emerging clean energy market to provide simplified renewables automation to help power producers build and scale sustainable operations. 

(Emerson's Ovation™ Green soft ware and automation solution portfolio for renewable energy is an extension of our industry-leading Ovation automation platform that helps power producers reliably manage their green electricity operations to increase availability and production while reducing costs. Download high-resolution image)

Renewable electricity capacity has seen record growth in recent years. However, transitioning to cleaner energy systems or scaling up existing ones is a complex undertaking for power producers. Wind turbines, solar arrays, lithium-ion batteries, hydrogen electrolyzers and hydroelectric power all use a wide variety of automation software and technologies. As renewable portfolios grow, the number of applied technologies will multiply, increasing learning curves and adding complexity to operations as solutions from different vendors require additional integration. While some existing systems can provide layers of connectivity between very specific assets, the Ovation Green portfolio will deliver a single set of purpose-built software and solutions that supports different technologies in one standardized, intuitive system. 

“Countries around the globe are focused on transitioning to a clean energy economy in the coming decades, and while green energy is a simple concept everyone understands, the road to implementation is not always clear,” said Bob Yeager, president of Emerson’s power and water solutions. “With the Ovation Green portfolio, our software, support and solutions are unified in one system from a single trusted provider to help power producers more quickly, easily and reliably manage their renewable electricity operations.” 

Full access to real-time and historical operations information empowers owners and operators with greater visibility and control of all renewable assets across the enterprise. Through an integrated portfolio of data-driven asset control and management solutions, Ovation Green technologies provide secure, standardized access to data, independent of equipment manufacturer or system type, across a single or multiple sites.  

By gathering, collating and contextualizing vast amounts of data created by renewable generation and storage assets, Emerson’s Ovation Green portfolio provides a clear view of renewable operations in a seamless space. The portfolio will empower actionable intelligence from a unified platform to drive faster, more informed decisions to increase availability and production while reducing operations and maintenance costs. 

Emerson’s Ovation Green portfolio will be featured at the Intersolar and Energy Storage North America Conference February 14-16, 2023 in Long Beach, California. 

To learn more about Ovation Green technologies, please visit Emerson.com/Ovation-Green. 

(Courtesy of Emerson)

The research project: Battery-free sensors for the smart factory of the future by ABB

Networked Embedded Systems (NES) are the backbone of many sensor and communication systems today. Thanks to the awardee of the second ABB Research Award in Honor of Hubertus von Grünberg they now could become even more important. Flexibly designed, low-cost and battery-free sensor devices will help collect enormous amounts of data to accelerate the digital transformation of industries.

The world is full of them: NES comprise a class of devices that combine sensing and communication capabilities. Over the past two decades, there has been an enormous growth of NES devices to enable various sensing and Internet of Things (IoT) applications.

And this is just the beginning. The past several years have seen a significant interest to develop various machine learning techniques and apply them to different domains. An essential aspect of these tools and techniques is the collection and processing of large amounts of data. “This, we believe, will significantly accelerate the growth of NES even more”, says Ambuj Varshney, the 33-year-old awardee of the renowned ABB Research Award in Honor of Hubertus von Grünberg. “Machine learning techniques often require collection and processing of large amounts of data. For many applications, this would require a massive deployment of sensing devices.”

(The ABB Ability Smart Sensor for low-voltage motors was introduced in 2016. It was the first data-gathering device for electric motors in an industrial environment and needs batteries to sense and transmit the data.)

Many predictions already state that billions of such devices will be deployed in the near future. Though, as promising as the applications are, there is one major problem: Today NES devices are usually energy-constrained and commonly comprise of battery-operated, bulky devices which require a significant effort to deploy and maintain. “This severely challenges the vision of large-scale deployment of sensor devices for data collection”, the young researcher realized early on. 

The reasons for this are diverse: firstly, battery-operated devices require a significant maintenance effort to replace exhausted batteries. Secondly, batteries can also negatively impact the physical environment, as they often employ toxic chemicals which require proper disposal. Moreover, the devices’ large form factor also restricts their deployment, particularly in small or hard to reach places. And finally, of course, the most critical constraint for reliance on batteries is their considerable energy consumption.

What gives hope in this context, are some developments in which the current winner of the ABB Research Award had a significant share. Over the past few years, individual sensors have become exceedingly energy efficient. Today microphones or accelerometers consume just tens of microwatts of power. However, a typical radio transceiver used to communicate sensor readings, such as ZigBee, BLE or WiFi, remains energy-hungry, consuming several orders of magnitude of more power for their operation. “To overcome this limitation, we have made several significant contributions to the emerging area of backscatter communication”, Varshney says.

Backscatter technique enables wireless transmissions at much lower power consumption compared to conventional radios. It achieves this by using the fact that reflecting or absorbing wireless signals such as TV broadcast or cellular signals is much less energy expensive compared to locally generating them.

Based on this principle, as part of his doctoral thesis at the Department of Information Technology at Uppsala University, Varshney developed a system called “LoRea”. LoRea generates narrow bandwidth backscatter transmissions, which help it exploit receiver sensitivity and achieve large communication range. Further, it delegates carrier generation and reception to separate devices such as smartphones or WiFi routers, which improves the scalability of the system. Finally, it keeps the backscattered signal and the carrier signal apart in frequency, which helps to reduce the self-interference without requiring complicated and expensive hardware.

The development of LoRea represents hard work built on many failures and difficulties. But finally, Varshney´s presentation of LoRea at the highly selective ACM Conference on Embedded Networked Sensor Systems (SenSys 2017) was a complete success. “We have demonstrated the ability to communicate to distances as large as kilometres while just consuming tens of microwatts of power”, the young scientist explains. “This represents several orders of magnitude improvement in energy efficiency over conventional radio transceivers. The low-power consumption required for transmissions enables us also to radically rethink the design of NES.”

The potential to flexiblyexible designed, low-cost and battery-free sensor devices finally opens up a wide range of valuable options for the future. “We imagine our sensors could be in the form factor of stickers operating on harvested energy from the ambient environment such as light, radio frequency signals or vibrations and could be placed on surfaces and other areas to enable extensive data collection”, the awardee describes his vision. 

Flexible, battery-free sensors could significantly drive the digital transformation of industries, as large scale deployment of such sensors will enable the collection of almost unlimited amounts of data to help with various machine learning tools as well as artificial intelligence methods. That is why Varshney is particularly pleased to receive the honored research award from a company that is a global leader in the ongoing transformation already. “Enabling smart factories is definitely one use case that we want to target”, he explains, when asked about which further research projects he will invest the US$ 300,000 grant over the next three years. “My expectation from this award is that it enables me to leverage more than a century of experience of ABB in developing innovative technologies”.

(Courtesy of ABB)

Multi-function Ethernet I/O modules reduce costs by monitoring both analog and discrete I/O sensor types with one module.

Acromag has released two new Ethernet Remote Input/Output (I/O) modules, the NT2510 and NT2530, as part of its Busworks® NT Series. These modules are designed to be a cost-effective solution for monitoring and controlling analog and discrete signals in industrial applications.

Eight models have bidirectional discrete I/O, voltage or current analog inputs, and optional analog current outputs. NTE modules have dual RJ45 ports and a web server with field-selectable Modbus TCP/IP or EtherNet/IP™ communication. They also have an integrated DIN rail bus that allows up to three NTX expansion I/O modules to be connected, and a space-saving design that requires only 25mm of DIN rail per module.

The modules are suitable for use in harsh environments, with hazardous location approvals, high noise immunity, and a temperature range of -40 to 70°C. They can function as a network client or use Acromag’s i2o® peer-to-peer communication technology to transfer data directly between modules without the need for a host or server. The modules also have multicast capability and support conditional logic.

Each module will support multiple protocols which are selectable using any web browser to configure the network settings and I/O operation. The modules typically function as a network client, but also offer Acromag’s i2o® peer-to-peer communication technology to transfer data between modules directly without a host or server in between. Multicast capability and conditional logic are included.

Acromag, a mid-sized international corporation, has been developing and manufacturing measurement and control products for more than 60 years. They offer a complete line of industrial I/O products including process instruments, signal conditioning equipment, data acquisition boards, distributed I/O systems, and communication devices. 

(Courtesy of Acromag)

Introduction to Two-Wire Transmitters and 4-20mA Current Loops

The Basics of 4-20mA Current Loops

In two-wire 4-20mA control loops, we use 2-wire transmitters to convert various process signals representing flow, speed, position, level, temperature, pressure, strain, pH, etc., to 4-20mA DC for the purpose of transmitting the signal over some distance with little or no loss of signal. This paper reviews the operation of this transmission standard and its advantages; in particular as it relates to two-wire transmitters and the associated 4-20mA current loop.

What makes 4-20mA signal transmission so attractive?

Probably the greatest advantage of using a current loop for signal transmission is the current loop’s low sensitivity to electrical noise. This is very important for long distance transmission in harsh industrial environments. As a generally low impedance system, it is much less sensitive to induced noise, than perhaps the high impedance input of a voltage amplifier. The currents injected by typical noise sources are generally no more than a few hundred microamps, usually insignificant to the 16mA span. The use of a “Live Zero” also improves the signal to noise ratio at low levels, allowing us to accurately discern low signal levels without added noise or interference.

Another advantage to the 4-20mA current loop is that it is essentially lossless with respect to the transmission media (wire) and the interconnections (connectors). That is, the accuracy of the signal is not affected by the voltage drop in the interconnecting wiring. This allows the signal transmission to occur over long distances, with varying conductors. Compare this to voltage signals, which will always have an associated signal loss related to the length of the wires—the 4-20mA signal current does not exhibit any signal losses under this same scenario. Kirchoff’s Current Law teaches us that the current in a loop is equivalent at any point in the loop. That is, if you happen to be reading 12mA at your receiver input, you can be certain that 12mA is passing through your transmitter.

What is the 250T Two-wire RTD Transmitter Failsafe Hook-Up Approach?

Two-wire Transmitters and Their “Hook-up” to Achieve a Failsafe Configuration

The attached analysis references Acromag’s 250T series RTD (100 ohm platinum)

(250T Two-wire RTD Transmitters Fail-safe Hook-up Approach)

This type of hook-up is typically not used because the effects of lead-wire resistance inaccuracies are additive to the RTD measurement. However, when addressing the problem of FAILSAFE, this configuration offers the most predictable output behavior. Also, H the RTD hook-up is properly done, the inaccuracies due to lead wire resistance can be minimized. The following is a list of most probable failures that could happen to the input sensor. An analysis will be performed to address each failure and predict the output of the transmitter.

1. Lead wires +/-could break open
2. The RTD sensor could fail open up
3. The input could become grounded
4. The input +/-could become shorted

Conditions/Assumptions for Failsafe Hook-up Approach:

1. RTD type: 100 ohm platinum
2. Lead-wire length: 50ft (or shorter)
3. “-” & “L” connection: internal
4. Max. temp. change for lead wires: 50°C
5. Lead wire gauge: 17 AWG (0.005 ohms/ft)
6. RTD break detection: UP

Based on these conditions, we can derive accuracies for this type of approach.

Analysis

1. Total lead wire resistance:

·         2 * 50 ft * (.005 ohms/ft) = 0.5 ohms (static value)

·        NOTE: This lead wire resistance is a static value which means that at 25°C, R’s effect can be calibrated out of the transmitter. The value of the most concern, however, is the dynamic resistance change of the lead wires over temperature

       2. The following equation approximates copper wire resistance with temperature changes of up to 50°C.

·         Rt= R(25°C) * [1 + (6 T)(0.004)]

·         Rt= 0.5 * (1 + (50)(0.004)]

·         Rt= 0.6 ohms

·         Thus, the dynamic resistance change of the lead wires is:

Dynamic change= 0.1 ohms (maximum temperature change= 50°C)

 To download click here What is the 250T Two-Wire RTD Transmitter Failsafe Hook-up Approach?