This is the second segment of CCJ’s three-part report on PSM’s 2024 Asset Management Conference, conducted at the Westin Beach Resort in Fort Lauderdale, Fla, January 29-February 1. The first segment was published earlier this year, the third installment will appear in CCJ later this year.

The focus here is fourfold:

• FlameSheet™ keeps getting better.
• Benefits of additive manufacturing (AM) in the production of R1 vanes.
• Technical presentations by industry partners on (1) generator field rewinds, (2) impacts of GT upgrades on heat-recovery steam generators (HRSGs), (3) exhaust-frame mods and improvements.
• Shop tour (below).

A focus of the shop tour conducted Feb 1, 2024 as part of PSM’s Silver Anniversary celebration was the company’s FlameSheet™ product. The assembly drawing A is helpful in understanding the nature of parts displayed at the various manned stations on the tour.

In B, Jose Gutierrez, manager of combustion manufacturing engineering, shows components critical to proper air and fuel flow in the FlameSheet assembly—specifically dome, metering plate, and pilot injector. The main injectors and flow sleeve are in C.

Recall from the text that FlameSheet is a “combustor within a combustor” with four fuel circuits—Main 1, Main 2, Pilot, and Pilot tune—to widen the operating envelope and allow for a larger fuel variance. It is characterized by an aerodynamic trapped vortex, creating recirculation zones to provide a wide margin of stability.

FlameSheet’s modular design allows retrofit of components as the product grows. It also enables PSM engineers to properly dial in emissions and dynamics for the best performance in each engine.

Chris Varney, senior technician, flow system services, is in the final stages of FlameSheet assembly in D. Flow tests of individual components, then of the entire combustor, assure the best possible performance in the field. Last step: Inspection prior to packaging E. After crates are built around the combustors, they are shipped to the job site ready to mate to their respective transition pieces.

Mark Zangara, senior engineer, airfoil manufacturing (center) and Greg Vogel, senior engineering manager of technology (left), display new and engine-run 501F R1 vane segments F. The disassembled R1 vane, manufactured using 3D printing technology, is shown prior to coating removal. Its disassembly and inspection, conducted after the first full-service interval, revealed no cracks in the vane, and vane segments were fully repairable.

This stop also showcased the first full-interval GTOP7, including repair of PSM’s first additive manufactured set of hot-gas-path components (R1 vanes).

Shear-wave testing G is used to check for cracks in OEM’s 501F support housings. A cross section, shown on the left in the photo, was beneficial for supporting speaker commentary. The PSM team: Darius Marchal, technical lead, manufacturing engineering of combustion, cases, and rotors; Timothy Hleboski, technical lead, fuel system services; Ryan Griffen, cell lead, fuel system services.

Joshua Eads, technical lead, metrology (x-ray, white light, blue-light scanning, CMM, and faro arm) calibrates portable scanning equipment H that allows PSM to ensure conformity with both repairs and new manufacturing activities. Fixed and portable equipment also is used to support field findings and activities.

Derek Ji, engineering management, coating processes, shows PSM’s new coating booth I, installed in 2023, to add capacity for both new manufacturing and repair processes. Robotic thermal spray booths accommodate bond-coat and top-coat applications. HVOF (high-velocity oxygen fuel) and APS (air plasma spray) are available.

Attendees were told that PSM offers several unique thermal barrier coating applications for both stationary and rotating equipment, developed in concert with the company’s new manufacturing engineered solutions activities.

Eric Rosenlieb, senior technical lead, workshop operations, introduces PSM’s flow lab J to conference participants. Behind the speaker are fixtures for combustion components used to accommodate tight flow tolerances and wheeling of combustion systems.

The M&D Center, last stop on the tour, operates 24/7 along with its sister facility in Houston. M&D Engineers Sanjana Singh and Vojtech Bednar, and M&D Operator Josh Massie, were on hand to discuss the company’s experience in tracking the performance of 52 gas turbines, three steam turbines, and 55 generators.

By James Azar, AP4 Group

While cybersecurity has been inoculated into most everyone who works in critical infrastructure, like the power industry, some may not realize that the threat vectors are shifting from clever hackers to state-sponsored malicious actors.

In 2015 and 2016, Ukrainian power grids targeted by state-sponsored actors suffered widespread power outages. The attacks, attributed to a group linked to the Russian government, exposed broader vulnerabilities within the energy sector’s operational technology (OT) environments.

In 2020, a cyberattack on an Israeli water treatment facility was reportedly carried out by Iranian state-sponsored hackers. The attackers attempted to alter water chlorine levels, posing a significant risk to public health and highlighting the susceptibility of water infrastructure to cyber threats. A similar attack took place at the water plant in Oldsmar, Fla, during a Superbowl weekend in nearby Tampa. Once again, the events exposed vulnerabilities in OT control systems for infrastructure.

As geopolitical tensions continue to rise, so does the sophistication of cyberattacks aimed at critical infrastructure. Because the Russian cyber attack on Ukraine stands as one of the most significant and well-documented examples of a geopolitical cyber-event, much has been learned from it.

How it went down

The coordinated attack targeted three of Ukraine’s regional electricity distribution companies, ultimately affecting approximately 225,000 customers on Christmas Eve:

• Initial compromise. The attackers gained initial access through spear-phishing emails containing malicious Microsoft Office documents. Once the documents were opened, the software installed BlackEnergy malware, a sophisticated tool used for reconnaissance and credential theft.
• Network reconnaissance. After gaining access, the attackers spent several months performing detailed reconnaissance within the IT networks of the power companies. They mapped out the network, identified critical systems, and harvested credentials.
• Credential theft. The attackers stole VPN and remote-access credentials, allowing them to move laterally within the networks and access the OT environments.
• Attack execution. Scada systems were compromised on Dec 23, 2015. The attackers opened circuit breakers at multiple substations, effectively cutting power to the affected regions.
• Destruction of systems. To delay recovery efforts, the attackers deployed KillDisk malware, which wiped the hard drives of key systems, and disabled uninterruptible power supplies, wreaking havoc on the system.
• Denial-of-Service attack. Concurrently, the attackers launched a DoS attack on the call centers of the electricity companies, preventing customers from reporting outages, impairing management’s ability to respond.

General lessons

First, the attack underscored the importance of properly segmenting IT and OT networks to prevent lateral movement by attackers. Although the power industry has been focused on this for many years, there is still much to be done.

Second, the need became evident for robust incident response and disaster recovery plans that include cyber-attack scenarios—including regular drills and coordination with national cybersecurity agencies.

Third, the event drove home the need for continuous monitoring of network traffic to detect and respond to unusual activity and threats before significant damage occurs.

Finally, organizations must invest in regular training and awareness programs so that employees recognize phishing attempts, often the initial attack vector, as in the Ukraine event.

In the US, the mandate given by Congress to CISA (Cybersecurity Infrastructure Security Agency) and DOE, is serving as the playbook to help build resiliency in the energy sector. These and other agencies offer threat intelligence sharing forums to help keep powerplants informed and updated about actual threats and existing attack vectors.

What’s behind it all

The emergence of Cyber Crime as a Service (CaaS) has lowered the entry barrier for committing cyberattacks. CaaS platforms offer various illicit services, from distributed denial-of-service (DDoS) attacks to ransomware deployments. These services can be purchased or rented by individuals with minimal technical knowledge. In effect, cyber-attacks can now be carried out by almost anyone, not just highly skilled hackers.

Regulatory frameworks for cybercrime are outdated and do not address the latest risks and challenges. A new legal framework should specifically address nations that harbor cybercriminals and allow them to operate with impunity. Economic and diplomatic consequences should be built into the framework, hopefully as deterrence.

Collaboration among various sectors and sharing of threat intelligence is crucial. The Electricity Information Security and Analysis Center (E-ISAC), operated by NERC, and InfraGard, a partnership between the FBI and the private sector, both offer robust support for regional infrastructure businesses.

Bad actors know that traditional security measures are often inadequate against such a dynamic threat landscape. They simply are not nimble enough. Advanced threat intelligence and monitoring systems, falling under broad names like network monitoring, IDS (Intrusion Detection Systems) and IPS (Intrusion Prevention Systems) offer continuous, real-time monitoring.

It is well-known that the proliferation of Internet of Things (IoT) devices in critical infrastructure has introduced significant risks. IoT devices often serve as entry points for cyber threats because of their frequent lack of robust security measures. Some IoT devices provide no way for the powerplant to make network changes or change default passwords. Others introduce backdoor risks from poor coding and patching mechanisms that require additional network access.

What you can do

When scoping and purchasing IoT devices, ensure that you have the ability to change the default password, patch the device with limited or no downtime, and network and manage the device without having to change network topology. Insist on a full software bill of materials.

Conducting regular audits and penetration testing, and following industry standards and regulations, will help you identify vulnerabilities. Make sure your intrusion detection, anomaly detection, and firewall systems are specifically designed for OT environments.

Cultivate a culture of security awareness among all employees. When the water treatment plant in Oldsmar became a target during Super Bowl weekend, it was one engineer’s awareness that prevented a disaster. Conduct training and drills regularly to ensure that staff are aware of the latest threat vectors and understand and adhere to best practices. Make sure you have a well-documented incident response plan in place and stress-test it regularly.

No one knows your powerplant or business quite like you. Assess your facility’s weaknesses and areas of concerns. Cultivate program champions, reward great behavior, acknowledge the good, and deal with the bad as a team. Everything should be documented and organized in a binder available at multiple locations. Finally, join E-ISAC and InfraGard to gain more insights on how to defend and recognize threats to your business.

 

James Azar, chief information security officer (CISO) at AP4 Group, has two decades of experience leading information security and engineering teams to solve complex challenges head-on and align technology, security, and privacy to business goals. He is the host of CyberHub podcast, CISO Talk, as well as Goodbye Privacy, a new podcast focusing on privacy concerns. The widely published Azar is a frequent speaker at industry events.

Bob Anderson, principal, Competitive Power Resources Corp

Bob Anderson joined CPS in 2005, following a 33-year career at Florida Power Corp/Progress Energy (now Duke Energy). The independent consulting firm, based in Palmetto, Fla, focuses on heat-recovery steam generators and their related auxiliaries for combined-cycle and cogen plants.

Recognized globally as an HRSG expert, Anderson has deep experience in powerplant design, operation, and maintenance. His positions at Progress included boiler engineer, steam-turbine engineer, plant manager, and director of gas-turbine major maintenance. As manager of PE’s combined-cycle services section, he was involved in the procurement, design, and O&M of the utility’s CC fleet.

Over the years, Anderson has participated in the installation of thousands of tube-temperature thermocouples in a variety of HRSGs and analysis of the resulting data. His expertise includes the optimization of boiler drain systems and attemperation systems. Plus, he has contributed to the development of startup/shutdown procedures for more than 70 combined-cycle and cogen plants around the globe. Results of his work have been published in many conference papers and the CCJ.

Anderson, chairman of the HRSG Forum (www.HRSGforum.com), is a skilled discussion leader well known both for his technical leadership in combined-cycle seminars and conferences and willingness to share his knowledge with users worldwide.

Nick Bohl, plant manager, St. Charles Energy Center

Nick Bohl as been plant manager at St. Charles, a 2 × 1 7F.05-powered combined cycle, since July 2018. Earlier, he was GM at Cogentrix Energy’s Effingham County Power and held various leadership positions at CAMS from June 2007 to June 2015. He began his career in the energy industry as a technician for Mirant in 2001, migrating to Progress Energy in June 2005 as a production team leader. Bohl’s journey began in the US Marine Corps, where he served as an avionics technician for five years before going to Mirant.

Bohl and his present and former colleagues at St. Charles Energy and Effingham County Power continue share many of their valuable O&M experiences with the industry through CCJ’s ongoing Best Practices program. The two plants have received more Best of the Best awards than any other facility since the program’s inception 20 years ago.

Dr Barry Dooley, senior associate, Structural Integrity Associates (UK)

Barry Dooley, respected worldwide for his encyclopedic knowledge of powerplant materials and chemistry, has served the electric power industry for more than five decades. During that time, he has authored or co-authored more than 300 technical papers.

Dooley organizes and chairs boiler/HRSG and chemistry forums worldwide—including the Australasian Boiler and HRSG Users Group, European HRSG Users Group, Film Forming Substances conferences, and several others.

Prior to joining Structural Integrity, he was a technical executive at EPRI, specializing in cycle chemistry, materials, boilers, HRSGs, and steam turbines. Management of the research organization’s boiler/HRSG tube-failure reduction/cycle-chemistry improvement and FAC programs was one of his responsibilities.

Earlier in his career, Dooley provided cycle chemistry and materials services for Ontario Hydro’s fossil fleet and conducted oxidation research at the UK’s Central Electricity Research Laboratories.

Dooley is well known today for his ongoing work as executive secretary at the International Association for the Properties of Water and Steam where he chairs the development of IAPWS Technical Guidance Documents so valuable to powerplant personnel, among others. Access the TGDs at no cost on www.iapws.org.

Sam Graham, plant manager, Tenaska Virginia Generating Station

Sam Graham was promoted from maintenance manager to plant manager at TVGS in fall 2017 with nearly two decades of experience in the power industry. His current responsibilities include facility operations, maintenance, and overall performance to ensure optimal efficiency and compliance with industry standards.

Graham came to Tenaska Virginia Partners in July 2005 after nearly a decade with Edison Mission Energy where his focus was instrumentation and controls. Responsibilities at Edison included maintaining and troubleshooting control systems, ensuring the accurate operation of instrumentation, and contributing to the overall efficiency of the power-generation process.

Graham has been stalwart in advancing and expanding the reach of industry user groups and championing the cause of owner/operators as long-time 7F Users Group steering committee member and instrumental in the development of many of the Power Users Group conferences like the Steam Turbine Users Group and Frame 5 Users Group.

Garry Grimwade, utilities generation technician, Riverside Public Utilities

Garry Grimwade is a seasoned powerplant operator and the only member of the Editorial Advisory Board with extensive aeroderivative O&M experience. He currently volunteers as vice president of the Western Turbine Users Inc, the world’s largest organization of aeroderivative owner/operators, where he holds tremendous responsibility for organizing and managing its extensive technical program.

Grimwade has been with Riverside since May 2011 with responsibilities for an LM2500-powered combined cycle, four LM6000s, and four GE10 engines that include safely starting up and shutting down units, ensuring environmental compliance, maintaining logs and readings, adjusting plant water chemistry, providing safety training, and managing the plant’s self-reporting ORAP® program.

Earlier, Grimwade was a CRO for GE Energy, attached to two 7H-powered single-shaft combined cycles. From August 2007 to January 2010 he was a powerplant operator for Dynegy at a 700-MW merchant facility with natural-gas-fired boilers and steam turbine/generators. His role included ensuring emissions compliance, performing and writing switching orders and LOTO, and troubleshooting faulty equipment.

From July 2003 to August 2007, Grimwade was at Duke Energy and Diamond Generating Corp. After mustering out of the US Navy in March 1999 with four years of experience as an engine mechanic, Grimwade joined the Pacific Gas Turbine Center as a rotor-balance team leader, supervising the overhaul of JT8-D engines.

Jason Makansi, president, Pearl Street

Jason Makansi, chairman of CCJ’s Editorial Advisory Board, founded Pearl Street, an independent consulting firm, in 2001 and continues to serve as the firm’s president. A chemical engineer by education, Makansi has spent the last four decades evaluating the global engineering, business, and regulatory issues governing advanced energy technologies, with a special focus on electricity production and delivery—including energy sources, electricity production, transmission, and distribution, customer-side energy services, and energy storage.

Earlier, he was employed as a process engineer for Heywood Robinson and as a chemical engineer for TVA.

Makansi is recognized worldwide as a thought leader in energy storage, clean-coal utilization technologies; environmental management; emissions control processes and carbon-footprint reduction; diagnostics, automation and information technologies, and knowledge management; powerplant asset optimization, gas-turbine and combined-cycle technologies, sustainable development, and industrial ecology.

A highly skilled communicator in energy technologies—verbal and written—Makansi has authored several books, including two for John Wiley, and hundreds of magazine articles on power generation technologies for CCJ and Power magazine, among others. Other credits include executive director of the Energy Storage Council and Coalition to Advance Renewable Energy through Bulk Storage, founder of Pearl Street Capital, and principal, Pearl Street Liquidity Advisors.

Bobby Noble, senior program manager for gas-turbine R&D, EPRI

Bobby Noble and his research team work on topics involving all aspects of the gas-turbine system, with a focus on combustion dynamics, high-hydrogen and other alternative fuels, next-generation low-NOₓ combustion architectures, and engine health and performance analytics—including digital twins.

Noble, an ASME Fellow with more than 20 years of GT experience, was awarded the 2024 Westinghouse Silver Medal for his work on behalf of the power industry. He holds five patents and has authored/co-authored/edited/co-edited more than 15 journal publications and more than 60 conference publications.

Peter So, project development/management director, Calpine Corp

Pete So currently manages technical development for Calpine projects in the West—including those involving carbon capture. He has been involved in powerplant development, operations, and maintenance for three decades and has a wealth of experience at facilities relying on traditional fossil fuels as well as leading-edge resources and technologies.

So’s efforts have been rewarded with patents in the following areas:

• Inlet bleed heat and power augmentation.
• A method for providing off-gas to a combustion system.
• GT engine controls for minimizing combustion dynamics and emissions.

Among his many professional accomplishments, So led the software development of the first PSM LEC III retrofit on a 501D5 engine. Plus, he was the lead controls engineer for the company’s Humid Air Injection project.

User-group credits include development of user-to-user discussion forums, serving on founding committees of Power Plant Controls User Group and Low Carbon Peer Group, as well as more than a dozen years on the steering committee for the 7F Users Group, where he contributed significantly to the group’s growth and its transition to Power Users (www.powerusers.org), a 501c(6) organization. So remains involved with the not-for-profit organization as treasurer.

SVI DYNAMICS, a division of SVI BREMCO, is a leading supplier of engineered noise control and gas path solutions for industrial sites including power generation and process applications. We design, engineer, and manufacture custom solutions to meet project specific requirements and specifications. It is a fast-paced small business environment that is very rewarding for someone who is self-motivated and is good at multi-tasking.

SVI DYNAMICS is seeking a Proposal Engineer with some previous experience in the sales, scoping, estimating and offering proposals for engineered equipment. Relevant equipment includes turbine exhaust silencers, stacks, ductwork, steam vent silencers, liners, expansion joints, and acoustical barrier systems. The position will support tasks related to the sales and marketing of engineered products and will need to understand acoustical engineering analysis and be able to apply it to customer focused solutions.

Position: Proposal Engineer
Type: Remote position
Travel: ~20% – as needed for customer visits, vendor fairs and EOS meetings

Job Duties:

• Application engineering support for sales by creating product designs, associated drawings, material lists, product cost estimates, and field construction sequences for large-scale silencers, ductwork, exhaust stacks and other equipment at heavy industrial sites
• Support technical marketing efforts for engineered products used at heavy industrial sites including website and direct-to-customer content, industry tradeshow and professional event participation, case- study development,
• Work with the Sales Director to support targeted marketing communications for existing prospects by working with the CRM (Customer Relationship Management system). Help organize targeted customers in the CRM database to further develop prospects and prioritize prospecting For core product line of noise control products, drive proposal efforts for the sales department, coordinating responses directly to the customer. Assisting Director of Acoustical Engineering with site evaluations, technical reports, virtual modeling of customer sites, and noise control product and material selection development
• Field inspection support for heavy industrial equipment including gas turbine simple cycle exhaust systems, Heat Recovery Steam Generators (HRSG’s) and other gas path systems
• Utilize engineering best practices and six sigma techniques to implement standardized processes across the organization to support growth

Position qualifications include:

• Bachelor of Mechanical Engineering or equivalent
• Experience with acoustical engineering, sound level and vibration measurement equipment, and modeling software (SoundPLAN) a plus
• Proficient with CAD software (preferably SolidWorks and/or AutoCAD) to generate drawings and drafting procedures
• Experience with design of steel ductwork, stacks, and support structures a plus
• Proficient with suite of Microsoft products including Project, Word, Teams, and

Candidates for this position shall be:

• Self-motivated and high energy
• Customer focused with ability to interface in board room or on job site
• Highly organized with good time management skills to prioritize multiple tasks

Please contact Scott Schreeg (219.380.9267 or sschreeg@svi-industrial.com)