EM Update August 25, 2020

 

EM Update | Vol. 12, Issue 23 | Aug. 25, 2020

EM Continues Progress On 2020 Priorities SRS Completes Risk Reduction Activities in Building Used to Produce Fuel for Space Program Chemists Make Final Move to Hanford WTP Analytical Laboratory Idaho Crews Complete Landfill Cover Progress Continues on Hanford Project to Stabilize At-Risk Structures SRS 'Switches IT Up,' Optimizing Cybersecurity EM Continues Progress On 2020 Priorities EM is continuing to make progress on its 2020 priorities. Each month through the end of the year, EM Update will highlight accomplishments in each of the priority groups. This month underlines progress on significant construction project milestones. Direct-Feed Low-Activity Waste

Chemists Kay Keltner, left, and Jaime Edwards are part of a team at Hanford’s Waste Treatment and Immobilization Plant that is integrating scientific instruments inside the Analytical Laboratory.

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Despite reduced operations and continuing challenges caused by the COVID-19 pandemic, the Hanford Site continues to make strides in completing construction necessary to move forward with the Direct-Feed Low-Activity Waste (DFLAW) initiative and turn DFLAW facilities over to commissioning. Training is well underway for the commissioning technicians who will play a vital role as Hanford gets closer to tank waste treatment via the DFLAW approach. The Tank-Side Cesium Removal (TSCR) system recently passed important factory acceptance testing and will soon be placed on newly poured concrete pads adjacent to Hanford’s AP Tank Farm for additional testing. TSCR will send pretreated waste directly from the tank farms to the Low-Activity Waste Facility for vitrification. Construction is also underway on the Integrated Disposal Facility.

Workers recently finished startup testing at the Analytical Laboratory, marking the first nuclear facility in the Waste Treatment and Immobilization Plant complex to reach that point prior to moving into the commissioning phase for operations.

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Energy Secretary Dan Brouillette, at podium, toured AVANTech in Richland to see the Tank-Side Cesium Removal system that will be used at Hanford as part of the Direct-Feed Low-Activity Waste approach to tank waste treatment.

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Salt Waste Processing Facility

An aerial view of the Salt Waste Processing Facility at the Savannah River Site.

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The Salt Waste Processing Facility (SWPF) at the Savannah River Site (SRS) received Critical Decision-4 (CD-4) and Authorization to Operate approvals on Aug. 17, authorizing “hot” or radioactive operations to begin at the landmark facility. CD-4 signals project completion and the transition from project phase to operations.

The SWPF is the last major piece of the liquid waste system at SRS and will process the majority of the site’s salt waste inventory by separating highly radioactive waste — mostly cesium, strontium, actinides, and waste slurry — from the less radioactive salt solution. After the initial separation process is completed, the concentrated high-activity waste will be sent to the nearby Defense Waste Processing Facility. The decontaminated salt solution will be mixed with cement-like grout at the nearby Saltstone Facility for disposal on site. Removing salt waste, which fills over 90 percent of tank space in the SRS tank farms, is a major step toward emptying and closing the site’s remaining 43 high-level waste tanks.

The approval comes five months ahead of the current baseline CD-4 completion date of January 31, 2021. The SWPF remains on track to start normal operations later this year following completion of hot commissioning. By 2030, it is expected that nearly all of the salt waste inventory at SRS will be processed.

 

Integrated Waste Treatment Unit

An Integrated Waste Treatment Unit ceramic filter bundle.

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The DOE Idaho Operations Office and its EM contractor Fluor Idaho continue to make progress on modifications to the Integrated Waste Treatment Unit (IWTU).

Long-term testing has concluded on ceramic filters that will be used on the IWTU, which will treat up to 900,000 gallons of radioactive liquid waste from legacy spent nuclear fuel reprocessing activities. The ceramic filters demonstrated exceptional performance during extended simulant runs at a pilot plant operated by Hazen Research in Golden, Colorado. Work continues at the IWTU on both wet and dry decontamination systems and robotic technology that will be needed once the facility begins actual liquid waste treatment.

 

Waste Isolation Pilot Plant

As a load of excavated dirt is dumped from the utility shaft, an excavator works on a sloped area that will hold the shaft's forced-air intake pipe, known as the plenum.

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A bucket of excavated dirt is lifted out of the utility shaft at the Waste Isolation Pilot Plant site.

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A worker gets a bucket ready for lifting in the Waste Isolation Pilot Plant's utility shaft as a mini excavator prepares to fill a second bucket with soil.

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The Waste Isolation Pilot Plant (WIPP) began work on its $75 million, 2,275-foot-deep utility shaft April 27, and crews have made rapid progress with excavation down to 50 feet. Working 24 hours a day, five days a week through challenges caused by the global pandemic, workers will soon begin blasting to remove debris.

Electrical switch gear has been installed to supply power to a large headframe over the shaft that will use a pair of winches to extract buckets of debris. When the shaft reaches 100 feet deep, a five-deck steel cylindrical work platform will be attached to the winches and lowered into the shaft.

The utility shaft, part of the Safety Significant Confinement Ventilation System, will provide increased air to the WIPP underground, eventually tying into the existing mine through new passageways known as drifts.

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SRS Completes Risk Reduction Activities in Building Used to Produce Fuel for Space Program

The Shift Operating Base inside the Plutonium Fuel Form Facility was a clean area that allowed operators to use manipulators to work with material inside the cells.

AIKEN, S.C. – Workers at the Savannah River Site (SRS) have completed risk reduction and cleanup activities in a building containing residual plutonium (Pu)-238 oxide, once used to power deep space missions. The two-story, blast-resistant, windowless, reinforced concrete building, known as Building 235-F, has been inactive for more than 25 years. One section of Building 235-F, known as the Plutonium Fuel Form (PuFF) Facility, was used to make fuel spheres and pellets out of Pu-238 to provide heat to electrically power long-term, deep-space missions, such as Galileo, Ulysses and Cassini. “Since late 2012, Savannah River Nuclear Solutions (SRNS) has been executing the Department of Energy’s implementation plan to reduce the hazards associated with the material at risk that remains as residual contamination in the Building 235-F facility,” said Building 235-F Project Manager Jeff Hasty. “Most of the residual contamination in the facility is within the hot cells where processing of plutonium was performed.” In 2019, following several years of prep work, SRNS conducted risk reduction activities that included the removal of a portion of residual plutonium contamination. Measurements conducted during the removal activities indicated that the plutonium oxide, which is left behind in a manner that was expected to be easily disturbed, was harder to spread (and less of an immediate hazard to co-located workers) than previously believed. This also meant that further plutonium removal activities were not necessary. Upon the partial removal of the residual plutonium contamination, a revised risk reduction strategy was developed to ensure the facility is safe until it can be decommissioned. Under the risk reduction strategy, the Savannah River National Laboratory completed characterization by performing an analysis to determine the amount of residual plutonium that remained in the facility. Following characterization, SRNS, the management and operations contractor of SRS, hired an independent contractor to evaluate potential fire scenarios, specifically looking at whether a fire could occur and, if so, whether it could impact the plutonium. Based on the reports, the SRNS project team removed or replaced ceiling tiles in rooms containing plutonium and removed combustibles identified above the ceiling tiles. Also the PuFF cells were sealed. Waste generated during plutonium removal was characterized and prepared for shipment to the SRS Solid Waste Management Facility. With the rsk reduction project completed, the project team transitioned in May 2020 to deactivating the facility. Deactivation will place the facility in a stable configuration for long-term safe storage until eventual decommissioning. The final deactivation plan is scheduled to be issued in September 2020. -Contributor: Lindsey MonBarren  Chemists Make Final Move to Hanford WTP Analytical Laboratory

Chemists at Hanford’s Waste Treatment and Immobilization Plant, such as Jaime Edwards, developed training and procedures and verified laboratory equipment performance over the past two years while working from a temporary off-site lab at Columbia Basin College in Pasco, Washington. Rigorous processes, procedures, and training developed by the team will ensure the waste vitrified in the Low-Activity Waste Facility is safe for long-term storage.

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RICHLAND, Wash. – A team of chemists and lab technicians has moved into its permanent home in the Analytical Laboratory (LAB) at Hanford’s Waste Treatment and Immobilization Plant (WTP).

Over the past two years, the scientific team developed training and procedures and verified laboratory equipment performance while working from a temporary laboratory at Columbia Basin College (CBC) in Pasco, Washington. In parallel, startup testing of systems in the LAB was completed to allow the team to transition to the site. The Analytical Laboratory is a key component to the Direct-Feed Low-Activity Waste (DFLAW) approach that will enable Hanford to begin treating task waste.

“It’s a critical moment in time for the project to welcome the laboratory team to the jobsite,” said Valerie McCain, project director for lead contractor Bechtel National, Inc. “I appreciate CBC’s collaboration as we leveraged the capabilities in our community to help progress the mission. Now, with the people and equipment here, we are well positioned for cold and hot commissioning for Direct-Feed Low-Activity Waste.”

The LAB’s key function is to determine the correct “recipe” of glass-forming materials for each incoming batch of tank waste, and then to confirm the glass produced by the Low-Activity Waste (LAW) Facility meets state and federal regulatory requirements. Rigorous processes, procedures, and training developed by the team will ensure the vitrified waste is safe for long-term storage.

“This is a key step in preparations to bring the vitrification plant online, begin making glass, and continue moving forward in our Hanford cleanup mission,” said Tom Fletcher, WTP federal project director. “Over the next several months, we will have fewer construction workers and more commissioning and operations workers. It’s exciting and a long time in coming.”

Under the DFLAW process, the tank farms will feed waste directly to the LAW Facility for vitrification. During the cold commissioning phase, a waste-like simulant will be run through the LAW Facility. Then, a hot-commissioning vitrification phase will begin turning low-activity radioactive tank waste into stable glass. The LAB will analyze 3.000 process samples annually to ensure the quality of vitrified waste.

-Contributor: Staci West

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Idaho Crews Complete Landfill Cover

Following cover placement, the Materials and Fuels Complex Landfill was reseeded and mulched. In a few years, it will look like the surrounding terrain.

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IDAHO FALLS, Idaho – Work crews at the Idaho National Laboratory (INL) Site have completed the installation of a soil cover over a construction debris landfill at the Materials and Fuels Complex (MFC).

The landfill was created to dispose of nonradioactive and nonhazardous debris generated during the demolition of ancillary buildings, structures, and equipment associated with the Experimental Breeder Reactor-II, which operated until 1994. Metal, concrete, empty storage tanks, and non-friable asbestos were disposed of in a 9.1-acre natural depression near the MFC facility.

In all, 4,400 cubic yards of debris were disposed of in the landfill over the last decade, with the last load delivered in August 2019. About 1.6 acres of the depression were filled with debris.

Last summer, crews from cleanup contractor Fluor Idaho began to cover the landfill with 18 inches of compacted native soils and six inches of topsoil. When winter arrived early, crews had to curtail work until this year.

Over the course of the summer, nine natural grasses and plants, including sage brush, were planted on the landfill cover. The purpose is to match the surrounding terrain while minimizing erosion and excessive settling. A berm was erected on the southern end the landfill to divert water runoff around the landfill during heavy rainfall.

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Heavy equipment was used to stockpile fill material for the landfill cover. The material was trucked from a borrow source near the Advanced Test Reactor Complex.

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“Our goal was to match up the vegetation on the landfill with the nearby natural plants and grasses,” said Fluor Idaho Field Support Specialist Dave Eaton.

Once its closure is approved by DOE, the Environmental Protection Agency, and state of Idaho Department of Environmental Quality, the landfill will be turned over to the Idaho site’s Environmental Restoration Program for long-term institutional controls to include controlling access, subsidence/vegetation monitoring, and maintenance as necessary.

-Contributors: Nicole Badrov, Erik Simpson

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Progress Continues on Hanford Project to Stabilize At-Risk Structures

EM Richland Operations Office contractor CH2M HILL Plateau Remediation Company tests an off-site mock-up of a conveyance system that will be used to move engineered grout from trucks into three at-risk underground structures.

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RICHLAND, Wash. – A Hanford Site project to stabilize three at-risk underground structures with engineered grout is well underway, with workers starting field preparations this month after successfully testing a full-scale mock-up of the grouting system earlier this summer.

The three structures, located near the former Plutonium Finishing Plant on Hanford’s Central Plateau, received liquid waste during Hanford’s plutonium production operations and contain residual radioactive and chemical contamination. A 2019 report indicated the structures are at risk of age-related failure.

EM Richland Operations Office (RL) contractor CH2M HILL Plateau Remediation Company (CHPRC) is filling the structures with engineered grout to protect workers and the environment, while not precluding future remedial actions or final closure decisions.

“This work is critical to Hanford’s ongoing risk reduction mission,” said Al Farabee, Hanford’s senior technical advisor for the project. “We are confident in the process, having used grout to safely stabilize other at-risk structures on the Hanford Site, most recently PUREX Tunnels 1 and 2.”

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Engineered grout will be pumped from trucks through more than 1,500 feet of pipe to stabilize three underground structures at the Hanford Site.

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Last month’s off-site mock-up tests provided another boost of confidence for the project.

“We learned valuable lessons about the grout conveyance system,” said Delise Savior, CHPRC project manager. “It let us see firsthand what would and would not work, and allowed us to fix those issues in a clean environment before we started work in radiologically contaminated areas.”

This animation shows the grout delivery and conveyance system that will be used to safely stabilize the structures. The use of grout will provide additional protection, while not precluding future remedial actions or final closure decisions.

Grouting is expected to begin this fall with project completion scheduled near the end of the 2020 calendar year. For more information, visit the stabilization project webpage.

-Contributor: Joan Lucas

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SRS 'Switches IT Up,' Optimizing Cybersecurity

From left, Savannah River Nuclear Solutions IT Network Engineers Alan Chafin, Kyle Garner, and Nicole Arnold complete the configuration of 800 computer network switches in dozens of buildings across the Savannah River Site. The project was completed nearly a year ahead of schedule.

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AIKEN, S.C. –The future of cybersecurity was brought to reality at the Savannah River Site (SRS) with a hardware upgrade that replaced 800 computer network switches in dozens of buildings across the site and the installation of new, cutting-edge security software. The multi-year project was completed nearly a year ahead of schedule.

A network switch is an essential component used as an interface between a computer, server, or computerized hardware, such as a printer, plotter, and other peripheral equipment. Through a company or sitewide data network, a computer user sends and receives email and accesses the internet.

Alan Chafin, network engineer with Savannah River Nuclear Solutions (SRNS), the management and operations contractor at SRS, managed a team of SRNS information technology (IT) personnel assisted by several subcontractor employees. They used innovative thinking and strategic planning to compress the project schedule.

Project management carefully coordinated outages with SRS organizations that were heavily reliant on IT equipment. This was crucial to avoid lost productivity and delayed completion of application-based tasks. Affected systems included payroll processing, employee benefits, and security programs.

“We began this project about two and a half years ago for several reasons, primarily because we wanted to proactively replace the switches before age-related maintenance issues appeared,” Chafin said. The improved switches recognize and harness new security software that older switches could not support.

“This is a game changer,” said Henry Longley, SRNS lead network engineer. “The new software, called Identity Services Engine or ISE, requires a new way of thinking in order to fully understand the immense and versatile capabilities it offers SRNS IT. Moving to ISE software is like moving from black-and-white television to virtual reality. It has that kind of potential impact to radically improve our ability to defend our data network and defeat attacks.

“We are really excited about the nearly limitless potential, which is so great it’s difficult for us to fully grasp at this time,” he added.

SRS utilizes Defense-in-Depth cybersecurity, which means layers of security are in place to protect computer systems and data. IT employees continually work to identify and patch vulnerabilities on network equipment, in order to maintain this defense strategy.

“DOE recognizes this project as a significant accomplishment,” said Lewann Belton, chief information officer, DOE-Savannah River Cyber and Information Technology Division. “Everyone involved in completing this project is to be commended.”

-Contributor: DT Townsend

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