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Uddcomb’s nuclear solutions address critical industry challenges such as process-related degradation of material and components. Uddcomb has capabilities to repair, manufacture, and replace customized components.
“We see the beginning where others see the end”
Your journey begins with a personalized consultation, during which our expert team thoroughly examines your requirements and objectives. We focus on understanding the unique characteristics of your project by tailoring solutions that meet your specific needs.
Your journey begins with a personalized consultation, during which our expert team thoroughly examines your requirements and objectives. We focus on understanding the unique characteristics of your project by tailoring solutions that meet your specific needs.
Your journey begins with a personalized consultation, during which our expert team thoroughly examines your requirements and objectives. We focus on understanding the unique characteristics of your project by tailoring solutions that meet your specific needs.
Your journey begins with a personalized consultation, during which our expert team thoroughly examines your requirements and objectives. We focus on understanding the unique characteristics of your project by tailoring solutions that meet your specific needs.
Expertise in Manufacturing, Repairs, Installation, Welding, and Materials
We provide highly specialized engineering services tailored for the nuclear industry — with deep expertise in mechanical design, manufacturing, repair projects, installation, and welding & materials technology.
Our engineering capabilities support the entire project lifecycle, from concept development and feasibility studies to detailed design, qualification, and execution support.
Our engineers combine hands-on experience from nuclear sites and workshops with deep technical expertise in design, welding, and material performance under nuclear conditions.
Our engineering services are a vital part of all our projects — but are also offered separately as feasibility studies or consultancy services.
Installation Services for the Nuclear Industry
Uddcomb offer qualified installation services for the nuclear industry — with a focus on safety, precision and full compliance with nuclear regulations.
Our experienced team performs installation work on-site at nuclear facilities, following strict safety protocols and the highest quality standards.
Uddcomb handle:
Our personnel are highly recognized for their extensive experience in mechanized welding and to operate effectively in a nuclear environment.
We deliver safe, reliable, and precise installation work — fully tailored to each project and in strict compliance with the demands of the nuclear industry.
Engineering Services for the Nuclear Industry
Expertise in Manufacturing, Repairs, Installation, Welding, and Materials
We provide highly specialized engineering services tailored for the nuclear industry — with deep expertise in mechanical design, manufacturing, repair projects, installation, and welding & materials technology.
Our engineering capabilities support the entire project lifecycle, from concept development and feasibility studies to detailed design, qualification, and execution support.
Uddcomb deliver:
Our engineers combine hands-on experience from nuclear sites and workshops with deep technical expertise in design, welding, and material performance under nuclear conditions.
Our engineering services are a vital part of all our projects — but are also offered separately as feasibility studies or consultancy services.
Manufacturing of specific NPP plant components and parts
Dedicated workshop area and working routines for manufacturing that contain sensitive information.
We implement rigorous project-based quality control measures to verify accuracy and reliability throughout manufacturing. This includes dimensional checks and material analysis to ensure that the components meet the highest quality and performance standards.
A unique manufacturing process for test blocks and test specimens with various manufactured defects.
The defects are not limited to length and depth.
The defects can be tilted and follow HAZ or other expected directions.
Test blocks or test specimens based on Uddcomb’s proven technology have been used in the nuclear industry for over 40 years and comply with ENIQ’s requirements.
The manufactured defects accurately replicate common flaws found in industrial components, enabling comprehensive testing and evaluation.
We deliver high-quality mechanical components and systems for the nuclear industry with a focus on precision, traceability and efficiency.
All manufacturing is carried out in our own workshop (4000m2) or in one of our many partners’ facilities. Independent of location, manufacturing is governed by us securing strict quality control and compliance with nuclear industry requirements.
We manufacture based on customer drawings or we develop and design complete solutions in-house. Our processes meet the highest standards, including ASME, EN, ISO, and nuclear-specific requirements.
Our capabilities include:
We support both maintenance, modernization, and new build projects — ensuring reliability where it matters most.
Our capabilities include:
We support both maintenance, modernization, and new build projects — ensuring reliability where it matters most.
Manufacturing of specific NPP plant components and parts
Feed water spargers, particle separtors (foreign debris removal equipment), dry tubes,pressure vessels, various spare parts,temporary reactor vessel covers, internals, piping components etc
Uddcomb have extensive manufacturing capabilities in karlskrona,Sweden. together with our scandinavian strategic partners in the Uddcomb Alliance we offer extensive manufacturing capabilities and a competitive swedish manufacturing alternative of heavy nuclear components.Uddcomb bridge the gap between conventional nuclear and new nuclear in scandinavia
Our laboratory a unique competitive edge when it comes to Development of welding procedures welding tests, test and evaluation of manufacturing concepts etc
The defects are not limited to length and depth.
The defects can be tilted and follow HAZ or other expected directions.
Test blocks or test specimens based on Uddcomb’s proven technology have been used in the nuclear industry for over 40 years and comply with ENIQ’s requirements.
The manufactured defects accurately replicate common flaws found in industrial components, enabling comprehensive testing and evaluation.
We offer specialized repair services for the nuclear industry, focusing on the development, qualification, and use of project-specific equipment to meet unique technical challenges.
Our experienced team supports complex repair projects inside nuclear facilities — always with the highest standards of safety, precision, and regulatory compliance.
Our personnel combine extensive experience in nuclear repair projects with deep expertise in mechanized welding, precision machining, and the development of remote-controlled customized tooling.
Manufacturing of specific NPP plant components and parts
Dedicated workshop area and working routines for manufacturing that contain sensitive information.
A unique manufacturing process for test blocks and test specimens with various manufactured defects.
The defects are not limited to length and depth.
The defects can be tilted and follow HAZ or other expected directions.
Test blocks or test specimens based on Uddcomb’s proven technology have been used in the nuclear industry for over 40 years and comply with ENIQ’s requirements.
The manufactured defects accurately replicate common flaws found in industrial components, enabling comprehensive testing and evaluation.
Uddcomb offer qualified installation services for the nuclear industry — with a focus on safety, precision and full compliance with nuclear regulations.
Our experienced team performs installation work on-site at nuclear facilities, following strict safety protocols and the highest quality standards.
Our personnel are highly recognized for their extensive experience in mechanized welding and to operate effectively in a nuclear environment.
We deliver safe, reliable, and precise installation work — fully tailored to each project and in strict compliance with the demands of the nuclear industry.
Installation Services for the Nuclear Industry
Uddcomb offer qualified installation services for the nuclear industry — with a focus on safety, precision and full compliance with nuclear regulations.
Our experienced team performs installation work on-site at nuclear facilities, following strict safety protocols and the highest quality standards.
Uddcomb handle:
Our personnel are highly recognized for their extensive experience in mechanized welding and to operate effectively in a nuclear environment.
We deliver safe, reliable, and precise installation work — fully tailored to each project and in strict compliance with the demands of the nuclear industry.
Engineering Services for the Nuclear Industry
Expertise in Manufacturing, Repairs, Installation, Welding, and Materials
We provide highly specialized engineering services tailored for the nuclear industry — with deep expertise in mechanical design, manufacturing, repair projects, installation, and welding & materials technology.
Our engineering capabilities support the entire project lifecycle, from concept development and feasibility studies to detailed design, qualification, and execution support.
Uddcomb deliver:
Our engineers combine hands-on experience from nuclear sites and workshops with deep technical expertise in design, welding, and material performance under nuclear conditions.
Our engineering services are a vital part of all our projects — but are also offered separately as feasibility studies or consultancy services.
Testblocks and test specimens for NDE
Uddcomb develop and manufacture high-quality test blocks with realistic defects for NDE qualification supporting industries such as nuclear, energy, process, offshore, marine, and manufacturing.
For over 40 years, Uddcomb have delivered customized test blocks to the international market, ensuring reliable and realistic defects for NDT.
Uddcomb offer:
Weld solidification cracks are defects that form in the weld metal during the final stage of solidification, as the molten weld pool turns into solid metal. They typically appear along the weld centerline and are caused by factors such as poor material properties, high heat input, or improper welding parameters.
These cracks reduce the structural integrity of the weld and can lead to failure, especially in critical applications. Preventive measures include optimized welding techniques, proper material selection, and control of heat input.
Mechanical fatigue cracks are cracks that develop in materials or welded joints due to repeated cyclic loading over time. Even when the applied loads are below the material’s ultimate strength, microscopic cracks can initiate and gradually grow with each load cycle.
These cracks often start at stress concentrations such as weld toes, sharp corners, or material defects. If undetected, they can lead to sudden and catastrophic failure. Preventing fatigue cracks involves good design, smooth transitions, proper weld profiles, and regular inspection.
Lack of fusion is a welding defect where the weld metal fails to properly bond with the base material or with a previous weld pass. This results in weak, unbonded areas within the weld that can compromise its structural integrity.
The defect is often caused by insufficient heat input, incorrect welding technique, or poor joint preparation. Lack of fusion typically occurs at the weld root, sidewalls, or between weld passes. Preventive measures include proper joint design, optimized welding parameters, and thorough operator training.
Geometrical defects are imperfections in the shape, size, or alignment of a weld or component that do not meet specified tolerances. These defects can affect the structural performance, fatigue resistance, and overall quality of welded structures.
Typical examples include excessive weld reinforcement, undercut, misalignment, incomplete joint penetration, and irregular weld profiles. Geometrical defects are often caused by poor joint preparation, incorrect welding technique, or inadequate control during fabrication.
Primary Water Stress Corrosion Cracking (PWSCC) is a type of intergranular cracking that occurs in nickel-based alloys and stainless steels exposed to high-temperature primary water environments, typically in pressurized water reactors (PWRs). The cracking develops along grain boundaries due to the combined effect of tensile stresses, high temperatures, and the specific chemistry of primary water.
PWSCC can significantly reduce the structural integrity of critical components such as nozzles, welds, and steam generator tubes.
Key contributing factors include material susceptibility, operating temperature, water chemistry, and the presence of tensile or residual stresses. Prevention involves using resistant materials, stress-relief treatments, and strict control of water chemistry.
Intergranular Stress Corrosion Cracking (IGSCC) is a type of cracking that occurs along the grain boundaries of a material when exposed to a specific corrosive environment combined with tensile stresses. The cracks propagate between the grains, weakening the material’s structure without significant visible surface damage initially.
IGSCC commonly affects stainless steels and nickel alloys, particularly after sensitization, where chromium depletion at grain boundaries makes the material more vulnerable to corrosion.
The key contributing factors are a susceptible microstructure, a corrosive environment (such as chlorides or high-purity water), and applied or residual stresses. Preventive measures include proper material selection, heat treatment to avoid sensitization, and controlling the operating environment.
Implants are artificial defects introduced into test blocks or components by embedding prefabricated flaw inserts, such as wires, discs, or small crack-like features. They are used to simulate realistic flaws for the development, qualification, and verification of non-destructive testing (NDT) methods.
Although implants provide a high degree of realism, they still represent artificial flaws and should be complemented with other defect simulations.
Interdendritic Stress Corrosion Cracking (IDSCC) is a form of cracking that occurs along the dendritic grain boundaries of a material exposed to a corrosive environment combined with tensile stresses. The cracks propagate between the dendrites, often following the weak, segregated areas formed during solidification.
Electrical Discharge Machined (EDM) Notches. EDM notches are precisely manufactured artificial defects created using electrical discharge machining. They are used to simulate cracks or other flaw types in test blocks or components for non-destructive testing (NDT) development, qualification, and training.
EDM notches are a valuable tool for verifying inspection capability, but it is important to note that they do not fully replicate the metallurgical characteristics of real cracks.
Our test blocks are used for NDT method development, qualification, equipment verification, and personnel training — a proven solution by the use of realistic defects.
These cracks reduce the structural integrity of the weld and can lead to failure, especially in critical applications. Preventive measures include optimized welding techniques, proper material selection, and control of heat input.
These cracks often start at stress concentrations such as weld toes, sharp corners, or material defects. If undetected, they can lead to sudden and catastrophic failure. Preventing fatigue cracks involves good design, smooth transitions, proper weld profiles, and regular inspection.
The defect is often caused by insufficient heat input, incorrect welding technique, or poor joint preparation. Lack of fusion typically occurs at the weld root, sidewalls, or between weld passes. Preventive measures include proper joint design, optimized welding parameters, and thorough operator training.
Typical examples include excessive weld reinforcement, undercut, misalignment, incomplete joint penetration, and irregular weld profiles. Geometrical defects are often caused by poor joint preparation, incorrect welding technique, or inadequate control during fabrication.
ISCC is typically associated with materials such as stainless steels and nickel alloys, especially when exposed to aggressive environments like chlorides or high-temperature water.
The main contributing factors are a susceptible material, a corrosive environment, and the presence of tensile stresses. Preventive actions include proper material selection, stress-relief treatments, and control of the operating environment.
PWSCC can significantly reduce the structural integrity of critical components such as nozzles, welds, and steam generator tubes.
Key contributing factors include material susceptibility, operating temperature, water chemistry, and the presence of tensile or residual stresses. Prevention involves using resistant materials, stress-relief treatments, and strict control of water chemistry.
Although implants provide a high degree of realism, they still represent artificial flaws and should be complemented with other defect simulations.
EDM notches are a valuable tool for verifying inspection capability, but it is important to note that they do not fully replicate the metallurgical characteristics of real cracks.
Our test blocks are used for NDE method development, qualification, equipment verification, and personnel training — a proven solution by the use of realistic defects.
Testblocks and test specimens for NDE
Uddcomb develop and manufacture high-quality test blocks with realistic defects for NDE qualification supporting industries such as nuclear, energy, process, offshore, marine, and manufacturing.
For over 40 years, Uddcomb have delivered customized test blocks to the international market, ensuring reliable and realistic defects for NDT.
Uddcomb offer:
Our realistic defects representing:
These cracks reduce the structural integrity of the weld and can lead to failure, especially in critical applications. Preventive measures include optimized welding techniques, proper material selection, and control of heat input.
These cracks often start at stress concentrations such as weld toes, sharp corners, or material defects. If undetected, they can lead to sudden and catastrophic failure. Preventing fatigue cracks involves good design, smooth transitions, proper weld profiles, and regular inspection.
The defect is often caused by insufficient heat input, incorrect welding technique, or poor joint preparation. Lack of fusion typically occurs at the weld root, sidewalls, or between weld passes. Preventive measures include proper joint design, optimized welding parameters, and thorough operator training.
Typical examples include excessive weld reinforcement, undercut, misalignment, incomplete joint penetration, and irregular weld profiles. Geometrical defects are often caused by poor joint preparation, incorrect welding technique, or inadequate control during fabrication.
ISCC is typically associated with materials such as stainless steels and nickel alloys, especially when exposed to aggressive environments like chlorides or high-temperature water.
The main contributing factors are a susceptible material, a corrosive environment, and the presence of tensile stresses. Preventive actions include proper material selection, stress-relief treatments, and control of the operating environment.
IGSCC commonly affects stainless steels and nickel alloys, particularly after sensitization, where chromium depletion at grain boundaries makes the material more vulnerable to corrosion.
The key contributing factors are a susceptible microstructure, a corrosive environment (such as chlorides or high-purity water), and applied or residual stresses. Preventive measures include proper material selection, heat treatment to avoid sensitization, and controlling the operating environment.
PWSCC can significantly reduce the structural integrity of critical components such as nozzles, welds, and steam generator tubes.
Key contributing factors include material susceptibility, operating temperature, water chemistry, and the presence of tensile or residual stresses. Prevention involves using resistant materials, stress-relief treatments, and strict control of water chemistry.
Although implants provide a high degree of realism, they still represent artificial flaws and should be complemented with other defect simulations.
EDM notches are a valuable tool for verifying inspection capability, but it is important to note that they do not fully replicate the metallurgical characteristics of real cracks.
Our test blocks are used for NDE method development, qualification, equipment verification, and personnel training — a proven solution by the use of realistic defects.
Take a look at some of the most common types of defects that Uddcomb manufacture with the tesblock portfolio for the nuclear industry
A unique manufacturing process for test blocks and test specimens with various manufactured defects.
The defects are not limited to length and depth.
The defects can be tilted and follow HAZ or other expected directions.
Test blocks or test specimens based on Uddcomb’s proven technology have been used in the nuclear industry for over 40 years and comply with ENIQ’s requirements.
The manufactured defects accurately replicate common flaws found in industrial components, enabling comprehensive testing and evaluation.
Partnering with Uddcomb means gaining access to expertise, innovations and a dedicated supply chain. Our commitment to excellence ensures that your project will be a success.
A critical pipe component was degraded after 10 years of operation at a process plant. The customer had to either replace the component or develop an urgent repair solution to extend the life of the component.
Learn more about Advanced orbital TIG welding repairs and cladding of components – life time extensions of critical components
After 10 years of operation a stainless steel pressure vessel have lost 9mm of thickness. Actual thickness was 7 mm below t-min and the pressure vessel was not allowed to operate.
Learn more about Mechanized weld build-up solutions for degraded pressure vessels below t-min
A nuclear power plant requires replacement of a primary circuit component, with stringent demands for welding quality, heat input, and minimal distortion. In additiona lack of access the the welding joint require a customized welding head for access.
Learn more about UDDCOMB OPTIGAP – Customized remote controlled orbital TIG welding applications
A 200-mm-thick reactor is experiencing severe corrosion and erosion in an instrument nozzle, requiring replacement. The replacement process involves complex on-site machining, welding, and heat treatment, which engages multiple suppliers and increases technical risks and costs.
Learn more about UDDCOMB OPTICLAD® – refurbishment & welding repairs inside nozzles and pipes
A production plant (nuclear, refinery or process plant) anticipates a risk that an urgent advanced welding repair of a pressure vessel or machinery may be required during the annual maintenance shutdowns.
Learn more about Ready for the Unexpected: Advanced welding repair readiness for critical shutdowns
European NPP with PWR technology needs to verify and extend the lifetime of its reactor. This requires a reliable NDT method to identify and characterize all potential manufacturing and operational-related defects in the reactor tank.
Learn more about Testblocks & Test specimens – Lifetime Extension and NDE Verification of PWR Reactor
Learn more about Manufacturing of Nuclear Power Plant Components
A nuclear power plant needs to repair a pipe component located in an area with high radiation levels, making human intervention unsafe.
Learn more about Remote controlled orbital welding in high radiation areas
Contact our experienced sales representatives to explore how Uddcomb’s industry-leading solutions can optimize your business.
Uddcomb Internationals advanced welding technology for orbital narrow gap welding with optimized metallurgical properties. Advanced orbital welding solutions that can be tailorized for multiple applications. A technology specially developed for the highest quality requirements.