Through maximizing product life and material circulation, we are aiming for 90% circularity in products, packaging, and waste by 2030. “We are building circularity and resource efficiency into our business in many different ways, and we help customers and suppliers do the same,” says Tove Jensen, Circularity Expert at Sandvik Machining Solutions. #circularity #sustainability #machining #manufacturing
Sandvik’s Post
More Relevant Posts
-
Take a look at our latest blog and YouTube video about the Circular Economy in Manufacturing: How to Minimise Waste and Maximise Efficiency https://lnkd.in/ehy-rJcJ #NetZero #sustainability #circulareconomy #SBCityDeal
Circular Economy in Manufacturing: How to Minimise Waste and Maximise Efficiency
http://netzeroskills.wales
To view or add a comment, sign in
-
🌱 Embrace #Sustainability. In the quest for sustainable practices, recognizing the significance of #manufacturing and #supplychain in the circular economy is vital. ♻️ At inriver, we know the importance of #ProductInformationManagement (#PIM) and its value in creating effective and sustainable manufacturing processes. Discover the advantages of circularity in manufacturing and join us in reducing our environmental footprint. Check out our blog for insights and actionable steps: https://ow.ly/3NPG50PfWO4
The role of manufacturing in a circular economy
inriver.com
To view or add a comment, sign in
-
Climate Change Policy | US-India Emerging Climate Leader | Top 75 Global Call for Ideas @ LiFE Mission | TISS Mumbai
🔄 Circular Economy Models in the ⛓Iron and Steel Sector⛓: Navigating Circular Transformation In the dynamic realm of the iron and steel sector, the concept of the circular economy takes center stage. Circular economy models offer a strategic pathway to transform linear product value chains into sustainable, closed-loop cycles. In this context, let's delve into the crucial components of circularity within the iron and steel industry, emphasizing the importance of data and industry knowledge. 1. Circular Economy Models in the Iron and Steel Sector ▶The circular economy concept revolves around reducing, reusing, and recycling materials to minimize wastage. In the iron and steel sector, circularity finds expression in two essential pillars: ▶Material Efficiency: This involves optimizing the use of steel products through innovative designs, refurbishment, and integration of alternative materials. A data-driven approach helps identify areas for improvement and supports informed decision-making for lightweighting and optimizing structures. ▶Steel Scrap Recycling: Recycling end-of-life steel products for repurposing not only conserves resources but also diminishes the demand for primary steel production. Industry knowledge and data analytics play a pivotal role in streamlining the scrap collection process and optimizing recycling practices. 2. Options to Improve the Circularity of the Sector ▶Enhancing circularity in the iron and steel sector demands comprehensive strategies informed by data insights: ▶Reducing Steel Demand: Material efficiency measures can significantly curtail steel demand. By leveraging industry data and lifecycle analysis, innovative designs that use less steel while maintaining performance standards can be developed. ▶Extending Product Lifetimes: The economic efficiency principle involves designing products for extended lifetimes. Access to industry data enables the identification of components that can be repaired, refurbished, or remanufactured, thereby extending their usability. 3. Challenges to Implementing Material Efficiency Strategies In the pursuit of circularity, industry-specific challenges demand data-centric solutions: ▶Technical Hurdles: Innovating and adopting new designs or processes requires data-driven research to ensure safety, efficiency, and performance compliance. ▶Regulatory Barriers: Aligning regulations with circularity goals necessitates data-backed insights to demonstrate the feasibility and benefits of material efficiency measures. ▶Financial Constraints: Industry knowledge informs the development of cost-effective material efficiency strategies, optimizing investments in advanced technologies. ▶ Cultural Shifts:Changing consumer behavior and practices demands data-driven awareness campaigns that showcase the environmental and economic benefits of circular practices. 🔗https://lnkd.in/gUqK3q9j
To view or add a comment, sign in
-
-
The State of Sustainable Manufacturing: 2023 and Beyond! - TechSling Weblog #Weblog #StateofSustainableManufacturing #manufacturing #sustainability
The State of Sustainable Manufacturing: 2023 and Beyond!
https://www.techsling.com
To view or add a comment, sign in
-
Title: Navigating the Future of Sustainable Manufacturing: As businesses around the globe embrace sustainability as a cornerstone of their operations, the manufacturing sector stands at a pivotal crossroads. With growing consumer demand for eco-friendly products and increasing pressure to reduce carbon footprints, manufacturers are tasked with reimagining traditional production processes to align with a more sustainable future. In this blog, we'll explore key strategies and best practices for navigating the evolving landscape of sustainable manufacturing, offering insights to help businesses thrive in an era defined by environmental stewardship and social responsibility. Embracing Circular Economy Principles: At the heart of sustainable manufacturing lies the concept of the circular economy – a regenerative approach that aims to minimize waste and maximize resource efficiency throughout the product lifecycle. By designing products with longevity in mind, prioritizing repair and refurbishment over disposal, and incorporating recycled materials into production processes, businesses can create value while minimizing environmental impact. Embracing circular economy principles not only reduces reliance on finite resources but also fosters innovation and fosters collaboration across supply chains. The Power of Collaboration and Transparency: Achieving true sustainability in manufacturing requires collaboration and transparency across the entire value chain. From suppliers to consumers, every stakeholder plays a crucial role in driving positive change and fostering a culture of accountability. By forging partnerships with like-minded organizations, sharing best practices, and engaging with consumers on sustainability initiatives, businesses can build trust, enhance brand reputation, and create a lasting impact on the planet. In today's interconnected world, transparency is paramount – consumers demand visibility into the environmental and social impacts of the products they purchase, and businesses that prioritize openness and honesty will emerge as leaders in the sustainable manufacturing revolution. As we embark on this journey toward a more sustainable future, the manufacturing sector has a unique opportunity to lead the charge and drive meaningful change. By embracing innovation, embracing circular economy principles, and fostering collaboration and transparency, businesses can not only reduce their environmental footprint but also create a more resilient and prosperous future for generations to come.
To view or add a comment, sign in
-
Technology Innovation for the Circular Economy: Recycling, Remanufacturing, Design, System Analysis and Logistics From the Editor's web site: Some of the greatest opportunities for innovation in the circular economy are in remanufacturing, refurbishment, reuse, and recycling. Critical to its growth, however, are developments in product design approaches and the manufacturing business model that are often met with challenges in the current, largely linear economies of today’s global manufacturing chains. The conference hosted by the REMADE Institute in Rochester, NY, brought together U.S. and international researchers, industry engineers, technologists, and policymakers, to discuss the myriad intertwining issues relating to the circular economy. This book consists of 56 chapters in 10 distinct parts covering broad areas of research and applications in the circular economy area. The first four parts explore the system level work related to circular economy approaches, models and advancements including the use of artificial intelligence (AI) and machine learning to guide implementation, as well as design for circularity approaches. Mechanical and chemical recycling technologies follow, highlighting some of the most advanced research in those areas. Next, innovation in remanufacturing is addressed with descriptions of some of the most advanced work in this field. This is followed by tire remanufacturing and recycling, highlighting innovative technologies in addressing the volume of end-of-use tires. Pathways to net-zero emissions in manufacturing of materials concludes the book, with a focus on industrial decarbonization. https://lnkd.in/d-T-vSQm
To view or add a comment, sign in
-
-
Circularity is THE pathway towards sustainability. Our latest blog looks at how circularity works in manufacturing together with how operating in this manner helps us reach crucial net zero targets. We’d love to hear the ways you are adopting circularity in your factory and warehouse processes. #NetZero #Circularity #SustainableManufacturing #Conveyors #ConveyorSystems https://lnkd.in/ezJ9PTkw
Circularity in Manufacturing
https://pjpconveyors.co.uk
To view or add a comment, sign in
-
Can We Move Away from a Linear Economy to a Circular Economy? The answer is yes, but it won't happen overnight. It's a gradual process that requires taking small steps towards a more sustainable future. Let's take the example of a carpet manufacturer. By switching to Nylon 6, they can repolymerize old carpet and turn it into new carpet. This not only reduces waste but also creates new commercial opportunities. But what about other industries? Redesigning products to make them more recyclable can be complex and costly. And in some cases, it might not be feasible at all. So, what's the solution? It's about taking small steps towards a circular economy. And who knows, maybe a new technological breakthrough will make it possible to achieve a 100% circular economy one day! #CircularEconomy #Sustainability #Innovation #EcoFriendly
To view or add a comment, sign in
-
-
Business Limelight: PMMI: The Association for Packaging and Processing Technologies says that true Packaging Circularity requires important policy changes, improvements in design and an improved recovery-infrastructure #sustainablepackaging #recyclability #packaging #sustainability #circulareconomy #recycledmaterials #resourceefficiency
Fresh clarity for Circularity
spnews.com
To view or add a comment, sign in
-
Promoting Circularity in Spare Parts and Machinery Maintenance. ♻️ Circularity plays an essential role in the #industrialsector. Our methods for addressing #spareparts and #machinery #maintenance are built around the four cornerstone principles of circularity: Reduction of Material Usage, Reusability, Repairability, and Recyclability. By incorporating these principles into our service framework, we're committed to advancing sustainable practices: 1️⃣ Through innovative design engineering, we #optimize vertical roller mills to minimize material consumption without compromising performance. 2️⃣ Prioritizing the development of easily interchangeable spare parts and components. By enabling reuse, we extend their lifespan, reduce new manufacturing, and decrease environmental impact, fostering a circular economy. 3️⃣ Our focus on maintenance and repair ensures straightforward tasks and efficient fixes. By emphasizing #repairability, we minimize waste and maximize product longevity. 4️⃣ Designing spare parts and components with #recyclability in mind, enabling the recovery of valuable materials and reducing reliance on raw resources. Our commitment to recyclability drives a closed-loop approach and advances circular economy principles.
To view or add a comment, sign in
-
Product and Services Delivery, Program Management, and Team Building
6dGood initiative. It would be interesting to understand the impact of incorporating circularity on the carbon footprint of the tool considering the lifecycle cost analysis