Santa is a wee bit lost, click "Read More" to watch the video and see where we found him. Enjoy your holiday! Click Play Below to Enjoy the Show! May your holiday season be wrapped up with cheer and filled with prosperity to forge the New Year! Scroll down to see the full Scot Forge Cast and Crew Thanks for watching! Share your favorite Scot Forge Christmastime moment and follow us on our social networks. Enjoy the Holidays!

At Scot Forge, we wish you the hap-hap-happiest Christmas and a wonderful New Year! Click Play Below to Enjoy the Show! Oh, the silent majesty of a winter's morn... the clean, cool chill of the holiday air... Clark and Eddie helping decorate the Forge. It's the gift that keeps on giving throughout the entire year. At Scot Forge, we wish you the hap-hap-happiest Christmas and a wonderful New Year! Scroll down to see the full Scot Forge Cast and Crew Mele Kalikimaka was performed and provided by Michael Masci .

Take a peek into what makes Scot Forge different, how we forge our future by succeeding or failing as a team and the tradition of the SPIKE Award. Tradition. Loyalty. Pride. When you have a company with more than 125 years of history, tradition, loyalty and pride become infused in not only the culture, but the employees themselves. At Scot Forge, you can sense the essence of tradition, the vigor of loyalty and the notion of pride the moment you arrive at any of our three facilities. This has much to do with the fact that we are an employee-owned (ESOP) company and have been for more than 40 years.    Employee-ownership means that we forge our future by succeeding or failing as a team, which is significantly impacted by the principles above. We must take pride every day in what we do and how we do it to succeed in creating the best possible outcomes for our customers that extend beyond simply forgings. After all, what we develop impacts lives through strengthening infrastructure , improving aerospace designs, powering the world through mined commodities and bolstering our national defense .   Furthermore, for success, we must have loyalty internally to hold ourselves and each other to high standards. To achieve these standards, we leverage each other’s strengths, exhibit servant leadership in all that we do and attack the problem, not the person, which would not be possible without trust. Our loyalty to our customers is another facet of success. What we do would not be possible if we weren’t devoted to delivering high-quality, essential forged solutions on time, as promised.   Finally, establishing pride and developing loyalty couldn’t take place without tradition. At Scot Forge, “plaid is pride” it is our tradition to wear plaid to honor the Scottish roots of Pete “Spike” Georgeson, our ESOP founder.  Plaid also represents the way we rely on each other through success and failure, and the way that we unite with our customers. Another tradition is the recognition and reward of employee-owners who demonstrate the values of commitment and contribution with the SPIKE Award.   The SPIKE Award was founded in 1987 and named in honor of Pete. It celebrates employee-owners who have gone above and beyond the call of duty for the past year. Once a year, around August, employee-owners vote for fellow employee-owners who make an impact daily and truly embody the Scot Forge values of safety, personal accountability, integrity, continuous improvement, learning and collaboration.   By living these values daily, our employee-owners have created an environment that has surpassed just a job or a place to work and formed a family. Some employee-owners have been with Scot Forge right out of high school and are retiring after a 25-year career. While others have worked in different industries who now call Scot Forge home.  But, we all work toward one common goal, to leave our company better than we found it. Congratulations and thank you to this year’s SPIKE Award winners!   To learn more about Scot Forge and the opportunities we have in machining, forge, heat treat, operations, engineering or office positions call us or take a look at our careers page.

Quality is at the heart of Scot Forge’s operations, and innovation is a driving force. Whether forging components for the next generation of aircraft or creating custom solutions for unique industrial challenges, Scot Forge stands ready to forge ahead, shaping the future of manufacturing one piece at a time. In the world of metal forging, one company stands as a beacon of innovation, quality and reliability—Scot Forge. With a history that spans more than 130 years, Scot Forge has become a leader in the forging industry, renowned for its expertise in creating high-quality forged components for a diverse range of industries. Let's take a closer look at what makes Scot Forge a cornerstone in this critical field. A Rich History Founded in 1893, Scot Forge began as a small hammer shop in Chicago. Over the decades, the company has evolved, expanding its capabilities and facilities to meet the growing demands of its clients. Today, Scot Forge operates out of Spring Grove, Illinois, Clinton, Wisconsin and Franklin Park, Illinois. Despite its growth, the company remains a 100% employee-owned organization, fostering a unique culture of accountability and pride in workmanship. Cutting-Edge Capabilities Scot Forge specializes in open-die and rolled-ring forging and offers a wide range of services to industries such as aerospace, defense, oil and gas, mining, construction and many more. Its state-of-the-art facilities are equipped with the latest technology, allowing it to produce forgings that meet the most stringent specifications and standards. Some of the key capabilities include: Open-Die Forging: This process allows Scot Forge to create large, complex shapes that are essential for heavy machinery, power generation equipment and other industrial applications. Rolled-Ring Forging: Ideal for applications requiring precise, high-strength rings, this process is widely used in the aerospace and bearing industries. Custom Forging: Scot Forge excels in producing custom forgings tailored to specific customer requirements, ensuring that each piece meets exacting standards. Commitment to Quality Quality is at the heart of Scot Forge’s operations. The company is ISO 9001:2015 certified, demonstrating its commitment to maintaining the highest quality management standards. Additionally, Scot Forge adheres to various industry-specific standards, guaranteeing products meet or exceed customer expectations. The in-house metallurgical team works closely with clients to select the appropriate materials and processes, ensuring optimal performance and longevity of the forged components. Advanced testing and inspection methods, including ultrasonic testing, magnetic particle inspection and mechanical testing, are employed to verify the integrity and quality of each forging. Innovation and Sustainability Innovation is a driving force at Scot Forge. The company continually invests in research and development to push the boundaries of what is possible in metal-forming technology. The Forge Development and Metallurgy teams work on developing new processes and materials to enhance performance and reduce customer lifecycle costs. Furthermore, Scot Forge makes strategic partnerships to advance new technologies, such as additive manufacturing, including 3-D printing metal and alloy development and testing. Scot Forge is also committed to sustainability by optimizing processes and utilizing environmentally friendly practices to minimize waste and reduce its carbon footprint. Its efforts include recycling scrap material, reducing energy consumption and implementing green technologies wherever possible. Employee Ownership: A Unique Culture One of the defining features of Scot Forge is its employee ownership model. As a 100% employee-owned company, each team member has a vested interest in the success of the business. This model fosters a culture of collaboration, innovation and dedication, as employees are not just workers—they are owners. This sense of ownership translates into exceptional customer service and a relentless pursuit of excellence. Every employee-owner is motivated to contribute to the company's success, knowing that their efforts directly impact the future of Scot Forge. Looking Ahead As Scot Forge continues to grow and evolve, its commitment to quality, innovation and sustainability remains unwavering. With a rich history behind them and a bright future ahead, Scot Forge is poised to continue leading the forging industry, delivering high-quality solutions that meet the ever-changing needs of a diverse customer base. Whether it’s forging components for the next generation of aircraft or creating custom solutions for unique industrial challenges, Scot Forge stands ready to forge ahead, shaping the future of manufacturing one piece at a time.

Choosing ABS Grade 3 forgings is crucial for high-stress, high-fatigue maritime applications where regulatory compliance and structural integrity are paramount. By selecting the right supplier who meets ABS standards and has the necessary expertise, you can ensure that your ship components are of the highest quality, leading to enhanced safety and performance. In the maritime industry, choosing the right material for ship components ensures safety, durability, and optimal performance. ABS Grade 3 forgings stand out for their superior mechanical properties, making them a preferred choice for various high-stress applications. This blog will explore when to choose ABS Grade 3 forgings, the specific applications they are suited for, and how to find an approved forging supplier. When to Choose ABS Grade 3 Forgings High-Stress Applications: ABS Grade 3 forgings are specifically designed to withstand high-stress environments. These forgings exhibit high tensile strength and toughness, which are essential for components that must endure significant mechanical loads and forces. If your application involves substantial stress or heavy loads, ABS Grade 3 forgings are an ideal choice due to their robust performance. High Fatigue Life: Components in maritime applications often face repeated cycles of loading and unloading. ABS Grade 3 forgings offer a high fatigue life, meaning they can withstand these cyclic stresses over extended periods without experiencing fatigue failure. This property is crucial for parts like propeller shafts and rudders, which are subjected to constant operational stresses. Regulatory Compliance: When regulatory compliance is mandatory, ABS Grade 3 forgings are a must. These forgings meet the stringent standards set by the American Bureau of Shipping (ABS), ensuring that the materials used in ship construction or repair are approved and certified. Compliance with ABS standards is essential for obtaining the necessary certifications and avoiding legal or operational issues. Critical Structural Components: For critical structural components where failure is not an option, ABS Grade 3 forgings provide the reliability and strength to ensure safety and integrity. These forgings are designed to perform under extreme conditions, making them suitable for crucial parts that play a vital role in the overall stability and functionality of the vessel. Applications of ABS Grade 3 Forgings Propeller Shafts: Propeller shafts are a vital component of a ship’s propulsion system, transmitting power from the engine to the propeller. They require high strength and resistance to fatigue to ensure efficient power transmission and reliable performance. ABS Grade 3 forgings provide the necessary mechanical properties to withstand the rotational forces and stresses exerted by the propeller. Rudders: Rudders are essential for steering and maneuvering a ship. They are subjected to significant mechanical stresses and forces, particularly during sharp turns or adverse weather conditions. ABS Grade 3 forgings ensure that rudders maintain their structural integrity and performance under these demanding conditions, enhancing the vessel's safety and maneuverability. Shafting Systems: Shafting systems, including intermediate shafts and stern tubes, are critical components in the propulsion system. These systems require materials that can endure high rotational speeds and torque. ABS Grade 3 forgings offer the strength and durability needed to maintain the efficiency and reliability of the shafting system over time. Structural Supports and Brackets: Structural supports and brackets in a ship's framework must bear heavy loads and provide stability. ABS Grade 3 forgings are used for these applications due to their high strength and toughness, ensuring that the ship's structural integrity is maintained even under extreme conditions. ABS Grade 3 Considerations and Limitations While ABS Grade 3 steel is suitable for many marine applications, it is essential to consider its limitations and ensure it meets the specific requirements of your project: Corrosion Resistance: Although ABS Grade 3 steel provides moderate corrosion resistance, it may not be suitable for highly corrosive environments, such as areas with high salinity or pollution. Higher alloy grades with better corrosion resistance should be considered or used as a shell in such cases. Weight Considerations: While the high strength of ABS Grade 3 steel allows for thinner sections, this may not always be the most effective approach for all applications. The overall weight distribution and balance of the vessel or structure should be carefully evaluated. Cost Factors: Although ABS Grade 3 steel is generally cost-effective, the overall project cost should be considered, including fabrication, maintenance, and potential replacements due to wear and tear. Highlighting US-Sourced Material Using US-sourced materials in marine applications offers several benefits, particularly in terms of quality, regulatory compliance, and supply chain reliability. Quality Assurance: US manufacturers adhere to stringent quality standards and certifications, ensuring that ABS Grade 3 steel produced domestically meets the highest industry standards. This guarantees superior performance and longevity of marine structures. Regulatory Compliance: Sourcing materials from the US ensures compliance with American regulations and industry standards, such as those set by the American Bureau of Shipping (ABS) and the American Society for Testing and Materials (ASTM). Supply Chain Reliability: Relying on domestic sources for ABS Grade 3 steel reduces the risk of supply chain disruptions. This is particularly important in the marine industry, where delays can lead to significant financial losses. Economic and Environmental Benefits: Utilizing US-sourced materials supports the local economy and reduces the carbon footprint associated with transporting steel from overseas suppliers. How to Find an Approved Forging Supplier Identify Approved Suppliers: Start by identifying suppliers who are approved by the American Bureau of Shipping for producing ABS Grade 3 forgings. ABS maintains a list of approved manufacturers and service providers, which can be accessed on their official website. Ensure that the supplier you choose has the necessary certifications and approvals for the specific forgings you require. Evaluate Supplier Capabilities: Assess the capabilities of potential suppliers. Consider factors such as their production capacity, technological expertise, and experience in producing ABS Grade 3 forgings. It’s important to select a supplier who can meet your volume requirements and deliver consistent quality. Review Quality Control Processes: Quality control is paramount in forging production. Review the supplier’s quality control processes, including material testing, inspection procedures, and adherence to industry standards. An approved supplier will have robust quality management systems in place to ensure the integrity of their products. Verify Compliance and Certification: Ensure that the supplier’s forgings comply with ABS standards. Verify their certification and approval status with ABS. This step is crucial to avoid any issues related to regulatory compliance and to guarantee that the forgings meet the required specifications. Request Samples and Prototypes: Before placing a large order, request samples or prototypes from the supplier. This allows you to assess the quality, performance, and compatibility of the forgings with your specific application. It also provides an opportunity to conduct any necessary tests and inspections. Conclusion Choosing ABS Grade 3 forgings is crucial for high-stress, high-fatigue maritime applications where regulatory compliance and structural integrity are paramount. By selecting the right supplier who meets ABS standards and has the necessary expertise, you can ensure that your ship components are of the highest quality, leading to enhanced safety and performance. Additionally, sourcing ABS Grade 3 steel from US manufacturers offers numerous advantages, including quality assurance, regulatory compliance, supply chain reliability, and economic benefits. By choosing US-sourced materials, you can enhance the sustainability of your marine applications.

Modernizing military equipment by applying cutting-edge manufacturing processes is not just an innovation; it's a strategic imperative. In the fast-evolving landscape of military technology, staying ahead requires constant innovation. One strategic approach to enhancing military capabilities is updating old designs with better manufacturing processes. This revitalizes existing equipment and streamlines the military supply chain, fostering efficiency, cost-effectiveness, and improved performance on the battlefield. It ensures the military is equipped with state-of-the-art technology while optimizing resource utilization. Challenges with Outdated Designs Outdated military equipment poses several challenges to modern armed forces. These challenges include: Limited Compatibility: Older part designs may not be compatible with modern systems and technologies, hindering interoperability and integration efforts. Material Limitations: Outdated designs may rely on materials that are no longer optimal for performance or may face scarcity, complicating the sourcing process. Increased Maintenance Demands: Aging parts often require more frequent maintenance, leading to higher costs, longer downtimes and reduced operational readiness. Inefficiencies in Production: Outdated manufacturing processes may be less efficient, causing delays and bottlenecks in the production of critical military components. Updating Old Designs with New Manufacturing Processes: Digital Twins: Creating digital twins of existing equipment enables simulation and testing of modifications before physical implementation. This reduces the risk of errors and streamlines the development process. Additive Manufacturing (3D Printing): 3D printing technology enables the production of complex and customized parts with reduced waste. This not only accelerates the manufacturing process but also allows for the creation of lightweight and high-performance components. Forging Advancements: Modern forging techniques, such as precision forging, semi-closed-die and closed-die forging, offer enhanced shaping and strength. These capabilities allow for the production of high-quality, durable components that outperform their predecessors. By combining forging and additive, you can get the benefits of forged strength and grain flow with the speed and reduced material cost of printing nozzles or other protrusions onto the forging. Advanced Materials: Integrating new, advanced materials into existing designs can enhance durability, reduce weight and improve overall performance. This is crucial for maintaining a competitive edge on the battlefield. Collaborative Design Platforms: Implementing collaborative design platforms facilitates real-time communication among design teams. This ensures that updates are efficiently communicated and implemented throughout the supply chain. Benefits of Updating Designs: Cost Savings: By utilizing modern manufacturing processes, the military can reduce production costs, maintenance expenses and overall lifecycle costs associated with outdated equipment. Enhanced Performance: Upgraded designs often improve performance, giving the military a technological edge on the battlefield. Faster Production Cycles: New manufacturing processes, such as automation and advanced robotics, can significantly reduce production times, allowing for a more responsive and agile supply chain. Interoperability: Updated designs can be engineered to seamlessly integrate with newer systems, ensuring interoperability and compatibility across the military's arsenal. Benefits of Updating Part Designs with Forging: Strength and Durability: Forged components exhibit exceptional strength and durability, crucial attributes for military applications where reliability is paramount. Reduced Production Costs: While forging may have higher upfront tooling costs, the efficiency and material savings during production often result in overall cost reductions, especially for high-volume components. Streamlined Supply Chain: Upgrading part designs with forging capabilities enhances the supply chain by reducing lead times, improving production efficiency and ensuring a reliable source of high-quality components. Interchangeability and Standardization: Forged components can be manufactured with high precision, facilitating interchangeability and standardization across military platforms. This simplifies logistics and maintenance processes. Modernizing military equipment by applying cutting-edge manufacturing processes is not just an innovation; it's a strategic imperative. The integration of forging capabilities into the military supply chain by updating old part designs marks a significant leap forward in modernizing defense capabilities. As forging capabilities continue to evolve, the military benefits from a supply chain that meets and exceeds the demands of the dynamic and complex modern warfare landscape by streamlining, reducing costs and enhancing overall operational effectiveness by updating old designs. This approach ensures that our armed forces are equipped with the latest technology and maintain a flexible and efficient supply chain to meet the dynamic challenges of the modern battlefield.

The success of manufacturing critical components, such as ship shafts, gears, artillery or adaptor plates/rings, depends on their design and how well that design can be translated into a tangible, cost-effective, high-quality product. Design for Manufacturability and the Role of Forging in Supply Chain Resilience The success of manufacturing critical components, such as ship shafts, gears, artillery or adaptor plates/rings, depends on their design and how well that design can be translated into a tangible, cost-effective, high-quality product. This is where Design for Manufacturability (DFM) comes into play. So, let’s explore the significance of DFM and dig into the forging process's role in creating a robust and resilient supply chain. Design for Manufacturability (DFM): DFM is an engineering approach emphasizing the importance of designing products with manufacturing considerations in mind from the outset. It involves optimizing the design to ensure ease of manufacturing, assembly and overall efficiency. Manufacturers can streamline production processes, reduce costs and enhance product quality by incorporating DFM principles. Key Principles of Design for Manufacturability: Simplicity: Simplifying the design without compromising functionality can lead to easier manufacturing and assembly processes. This reduces the likelihood of defects and lowers production costs. Material Selection: Choosing readily available and well-suited materials for manufacturing can enhance efficiency and cost-effectiveness. Standardization: Standardizing components and processes wherever possible simplifies production, reduces the need for specialized tooling and facilitates smoother supply chain management. Minimization of Parts: Reducing the number of components in a product simplifies assembly, decreases the chances of defects and eases the burden on the supply chain. The Role of Forging in DFM and Supply Chain Resilience: Forging is a manufacturing process that involves the shaping of metal using compressive forces. It can play a crucial role in critical component DFM and contributes significantly to creating a robust supply chain. Here's how: Material Strength and Integrity: Forging enhances the strength and integrity of materials. Components produced through forging exhibit superior mechanical properties, ensuring a longer lifespan and reduced need for replacements. Reduction in Waste: Forging results in minimal material wastage compared to other manufacturing processes. This aligns with DFM principles of resource efficiency, contributing to sustainability and cost-effectiveness. Consistency in Production: The forging process produces components with consistent quality. This is essential for maintaining uniformity in the supply chain and reducing the likelihood of defects or variations in the final product. Effective Use of Resources: Forging is often more energy-efficient than other metal-forming processes. This effectiveness contributes to overall sustainability goals and positively impacts the economic viability of the supply chain. Near Net Shaping: Advancements in open die forging have led to near-net shaping capability, reducing input material and lowering the cost of machining. When considering the size of large forgings, reducing input material can have significant cost savings. In the dynamic manufacturing landscape, Design for Manufacturability emerges as a key strategy for success. When coupled with the advantages of the forging process, it becomes a powerful tool for creating a resilient supply chain. By prioritizing DFM principles and leveraging the benefits of forging, manufacturers can optimize their production processes and build a supply chain that is agile, efficient and capable of withstanding the challenges of the ever-evolving industry.

Proactive procurement involves anticipating future needs, ensuring a secure supply chain, and mitigating risks. Here's how forgings contribute to these strategies, along with a focus on strategic partnerships, diversified sourcing and risk mitigation practices. From protecting our country to plowing crops, forgings significantly enhance the effectiveness of proactive procurement strategies used to ensure vehicles, ordnances and equipment get out into the field quickly. For the Department of Defense, proactive procurement involves anticipating future needs, ensuring a secure supply chain, and mitigating risks. Here's how forgings contribute to these strategies, along with a focus on strategic partnerships, diversified sourcing and risk mitigation practices: Strategic Partnerships: Collaboration with Forging Suppliers: Building strong strategic partnerships with forging suppliers is essential. These partnerships can involve long-term contracts, joint research and development efforts, and information sharing. A stable and timely supply of critical components can be established by working closely with reliable forging suppliers. Technology Transfer and Innovation: Forming strategic partnerships can facilitate technology transfer and innovation. Collaborating with forging experts can lead to the development of advanced manufacturing techniques, improving the quality and performance of forged components. This ensures that the DoD and other OEMs have access to cutting-edge technologies. Capacity Planning: By building strategic partnerships, buyers can work with forging suppliers to plan production capacities effectively. This collaboration helps align production schedules and ensures that the required quantities of forgings are available when needed, reducing the risk of supply chain disruptions. Rapid Deployment of Military Assets: Quick Turnaround Time: Forgings are integral in the manufacturing of components for military vehicles, weaponry, and equipment. The use of forgings, which are produced through processes like hot forging, allows for a quick turnaround in production. This expedites the manufacturing of critical components, facilitating the rapid deployment of military assets when needed. Reliability in Extreme Conditions: Forged components, known for their strength and durability, are crucial for military applications. Whether it's the chassis of military vehicles or key components in weapons systems, the reliability of forgings ensures that military assets can operate effectively in harsh environments and extreme conditions, contributing to national defense readiness. Minimizing Downtime: The robustness of forgings helps minimize downtime due to equipment failures or breakdowns. Proactively procuring forged components that can withstand the rigors of military operations contributes to maintaining a high level of operational availability, enabling a swift and effective response to emerging threats. In summary, forgings contribute significantly to proactive procurement strategies by fostering strategic partnerships, diversifying sourcing, and implementing effective risk mitigation practices. Collectively, these approaches enhance the resilience, flexibility and reliability of the supply chain, supporting the Department of Defense mission to maintain a strong and secure defense capability.

The robust and evolving nature of the forging industry in the United States and the nation's ability to meet the growing demand for forgings in various sectors, including defense, energy and aerospace. In recent years, there has been a prevalent misconception regarding the limited forging capacity in the United States. Due to perceived limitations in forging capabilities, some have expressed concerns about the nation's ability to meet the growing demands of various industries, including defense, energy and aerospace. However, it's crucial to address and dispel these misconceptions to showcase the robust and evolving nature of the forging industry in the United States. U.S. Forge Capacity: Unraveling the Misconception Growing Industry Presence: Contrary to the belief of limited forging capacity, the United States boasts a significant and growing presence in the forging industry. Forging facilities, like Scot Forge, have invested in state-of-the-art technology and advanced manufacturing processes to enhance their production capabilities. These facilities play a pivotal role in meeting the diverse needs of industries ranging from automotive and defense to infrastructure and clean energy. Advanced Technologies and Innovation: There is a false impression that often arises from a lack of awareness about the advancements in forging technologies. Modern forging facilities in the U.S. employ advanced techniques such as precision forging, closed-die and semi-closed-die forging and additive manufacturing. These innovations increase the overall capacity and allow for the production of complex and near-net-shaped components, debunking the notion of limited capabilities. Strategic Partnerships: The forging industry in the U.S. has forged strategic partnerships with research institutions and government agencies to foster innovation and address potential downstream capacity constraints. Collaborative efforts between industry players and academia have led to the development of cutting-edge processes, materials and quality control measures, ensuring a robust and competitive forging sector. Diverse Applications: While defense and aerospace are key consumers of forged components, the industry serves a myriad of sectors, including mining, semiconductor manufacturing and construction. This diversity in applications showcases the adaptability and versatility of U.S. forging facilities, proving that capacity is not limited but rather multifaceted. Forge Capacity: Addressing Industry Challenges Workforce Development: We actively participate in workforce development and apprenticeship programs to strengthen the forging industry further. By reaching out to educate young people on their options for career paths, we have established a thriving pipeline of new talent. Furthermore, by offering training programs and initiatives that attract skilled professionals to the field we contribute to sustaining and enhancing forging capacity in the U.S. Infrastructure Investment: Upgrading and expanding infrastructure within forging facilities will be crucial for meeting the evolving demands of various industries. We reinvest our own money, to the tune of $500 million over the last 15 years, in facilities and assets that will continue to support the needs of the nation for years to come. Our continued investment in cutting-edge equipment and technology will ensure that the forging sector remains at the forefront of manufacturing capabilities. In conclusion, the misconception of limited forging capacity in the United States is far from the truth. The forging industry in the U.S. is robust, technologically advanced and continuously evolving to meet the diverse and growing needs of various sectors. By dispelling these misconceptions, we can appreciate the strength and adaptability of the forging sector, positioning it as a key player in the nation's industrial landscape. As the industry continues to innovate, forge ahead and debunk myths, the future of forging in the U.S. remains promising and dynamic.

EHS Today Magazine  names Scot Forge one of 16 companies to receive the 2019 America's Safest Company award. Scot Forge Recognized Again As One Of America's Safest Companies EHS Today Magazine  names Scot Forge one of 16 companies to receive the 2019 America's Safest Company award. This is the second time that the employee-owners of Scot Forge have received the award, with the first time being in 2014 when their company became the first forging company ever recognized.   "As employee-owners, our first responsibility is to complete each task without compromising our own personal safety and the safety of others," explains Joseph Lyons, safety leader. "We live this by looking out for one another, helping others and intervening when we recognize a hazard—behavioral or physical."  Each year,  EHS Today Magazine  invites companies from all industries to submit an application that demonstrates strong participation in the environmental, health and safety process. From those applications,  EHS Today Magazine selects  15 to 20 companies that have gone above and beyond safety culture standards, and then recognizes them as one of America's Safest Companies.   Once a company has won once, they must wait five years to resubmit an application. This waiting period is designed to challenge companies to make their processes even more remarkable because their next application is judged off of an already world-class process. Over the past 17 years, the magazine has recognized more than 200 companies with the award.    About Scot Forge Company Starting as a small hammer shop in Chicago in 1893, Scot Forge is proud to be a 100% employee-owned American manufacturer. Based in Spring Grove, Illinois, Scot Forge is a company with a 126-year track record of success focused on solving our customers' greatest challenges. With five U.S. facilities and 500 employee-owners, Scot Forge offers the most modern open-die and rolled-ring forging, machining and downstream capabilities in North America. From the wheels of NASA's Curiosity Mars Rover, to mission-critical components for nuclear submarines, to large hydraulic cylinders for the largest mining trucks on the planet, Scot Forge creates the precision forged metal parts used in demanding applications all over the world.

ABS Grade 2 steel bars play a key role in the maritime and offshore industries, and as technology continues to advance, the demand for materials that can withstand the rigors of the sea will only increase, making ABS Grade 2 steel a valuable asset in the world of marine engineering. In the world of marine engineering and offshore structures, the choice of materials plays a crucial role in ensuring the safety and durability of vessels. One such material that stands out is ABS Grade 2 steel, particularly in the form of bars. Let's look into the characteristics and applications of ABS Grade 2 steel bars. Understanding ABS Grade 2: ABS (American Bureau of Shipping) Grade 2 steel is a high-strength, low-alloy structural steel designed specifically for marine applications. It is known for its excellent weldability and toughness, making it an ideal choice for various components in shipbuilding and offshore platforms. Key Features of ABS Grade 2 Steel: High Tensile Strength : ABS Grade 2 steel bars are characterized by their high tensile strength, providing the necessary structural integrity required in the demanding conditions of the open sea. Impact Resistance: The steel exhibits excellent impact resistance, a vital property for structures exposed to harsh maritime environments where waves, currents and collisions are potential challenges. Corrosion Resistance: ABS Grade 2 steel offers good mechanical properties for a variety of applications, but its corrosion resistance is limited. For applications requiring higher corrosion resistance, it is advisable to consider covering or plating with stainless steel or other alloy steel designed specifically for such environments. Weldability: Welding is a common process in shipbuilding, and ABS Grade 2 steel excels in this regard. Its weldability ensures easy fabrication, allowing for the construction of intricate structures with minimal difficulty. Applications of ABS Grade 2 Steel Bars: Shipbuilding : ABS Grade 2 steel bars find extensive use in the construction of various ship components, including hulls, frames and structural members. The high strength of the steel contributes to the overall robustness of the vessel. Offshore Platforms : Offshore structures, such as oil platforms, demand materials that can withstand the challenging conditions of the open sea. ABS Grade 2 steel is preferred for these platforms due to its strength and corrosion resistance. Marine Equipment: From support structures to critical components like propeller shafts, ABS Grade 2 steel bars are employed in various marine equipment, ensuring reliability and longevity. ABS Grade 2 steel bars play a key role in the maritime and offshore industries, and as technology continues to advance, the demand for materials that can withstand the rigors of the sea will only increase, making ABS Grade 2 steel a valuable asset in the world of marine engineering. Procuring ABS Grade 2 Steel Bars: Now that we've explored the qualities and applications of ABS Grade 2 steel bars, the next crucial step is sourcing this high-strength material for your maritime projects. Fortunately, there are several reputable avenues where you can procure ABS Grade 2 steel bars: Specialized Steel Suppliers: Some steel suppliers, like Scot Forge, specialize in providing materials for the marine and offshore industries. These suppliers often stock a range of ABS-certified steels, including Grade 2 bars. Ensure that the supplier is recognized for quality and compliance with industry standards. Authorized Distributors : ABS Grade 2 steel is subject to strict quality control and certification processes by the American Bureau of Shipping. Purchasing from authorized distributors, like Scot Forge, ensures you receive genuine ABS-certified material that meets the required standards. Marine Equipment Manufacturers: Companies involved in manufacturing marine equipment and components may also serve as reliable sources for ABS Grade 2 steel bars. They often maintain partnerships with reputable steel suppliers and can provide materials with the necessary certifications. Local Steel Yards : Depending on your location, local steel yards or metal service centers may carry ABS Grade 2 steel bars. Visit or contact these establishments to inquire about the availability of the material and check if they meet the required industry standards. Before making a purchase, it's crucial to verify the authenticity of the ABS Grade 2 steel bars and ensure they come with the necessary certification from the American Bureau of Shipping. This certification guarantees that the material meets the stringent requirements for marine and offshore applications. By choosing a reliable source, you ensure the material's quality and contribute to the safety and performance of your maritime projects.

Do you know what the complete supply chain for semiconductor manufacturing looks like and what it takes to get those materials or build those machines? Most people know that our modern economy runs on semiconductors, the tiny electronic brains for millions of devices, including space vehicles, car computers, smartphones, medical equipment, appliances and more. But do you know what the complete supply chain for semiconductor manufacturing looks like? Of course, initial thoughts are the elements that must be processed to create a wafer and the machines that do the processing. But what does it take to get those materials or build those machines? As mining plays a huge role in obtaining the materials required for the wafers and producing the machines that make the wafers, so does forging in creating the components that are strong enough to withstand the processes to create a wafer. We learned during the COVID-19 pandemic that the vast majority of semiconductors were being manufactured and shipped from overseas. As chipmaking companies like Intel bring semiconductor manufacturing back to the U.S., setting up a complete supply chain will be key. With cost being critical to semiconductor manufacturing, using near-net-shaped parts can help mitigate price differences from Asia to the U.S. Forged components are viable because they are stronger and more material efficient than other methods. Forgings for the machines that make semiconductors are made through the hot forging process, which is a metalworking process that involves heating a piece of metal until it is pliable and then shaping it into the desired shape using a die. The metal is cooled and hardened to achieve the desired properties, then finished and machined to the desired dimensions. This process is often used to create complex shapes and tight tolerances that have better properties than can be produced using other manufacturing methods. Saving time and money, forged components are an excellent alternative to burning out or machining away bar or plate because of the near-net shaping capabilities. As a result, forgings can be found in various stages of semiconductor manufacturing, including wafer production machines, fabrication and packaging. Forgings used in semiconductor manufacturing are typically made from high-strength materials such as stainless steel or aluminum that have properties to withstand the high temperatures and pressures it takes to create wafers. One common type of forged component used in semiconductor manufacturing is the base frame of the machine. The base frame is a structural piece that allows the machine to move seamlessly in all directions to produce chips. Base frames are typically made from a high-strength steel alloy or aluminum and are precision-machined to ensure a tight, secure fit within the lithography machine. Another important forged component used in semiconductor manufacturing is the heat exchanger. These devices are used to cool the wafers during processing and are typically made from aluminum or aluminum alloy. They are designed to maximize heat transfer between the hot process fluids and the coolant and are often precision-machined to ensure optimal flow and heat transfer. Forged components are also used in semiconductor packaging, which is the final step in the manufacturing process. These include lead frames and substrate carriers, which are used to hold and position the semiconductor die during the packaging process. Lead frames are typically made from a high-strength steel alloy, while substrate carriers generally are made from aluminum alloys. Overall, forged components are important in the semiconductor manufacturing supply chain. Selecting a forging partner who is reliable and will work to manufacture the most effective part for your needs will help ensure this type of work comes back to the U.S. It will also help the machine shops working with these large OEMs or bidding on projects have better opportunity for success.