Voting for the highly anticipated 3D Printing Industry Awards 2023 has officially begun! This year’s awards showcase the best and brightest in the 3D printing industry, highlighting the innovative technologies and companies that are pushing the boundaries of manufacturing.
One company that has caught the attention of industry insiders is Batch.Works. Known for their cutting-edge 3D printing capabilities, Batch.Works has recently launched an equity crowdfunding campaign on Seedrs. The funds raised will be used for research and development of AI-driven smart factories and Circular Manufacturing as a Service (CMaaS).
In a remarkable show of support, Batch.Works reached its £300,000 target in just 24 hours, proving the confidence that investors have in the company’s mission. With a pre-money valuation of £3.5 million, Batch.Works’ campaign is now in the overfunding phase, allowing even more individuals to take part in this exciting opportunity.
Batch.Works aims to revolutionize the manufacturing industry, recognizing the significant impact it has on carbon emissions and global energy consumption. With 20% of carbon emissions and 54% of global energy consumption linked to manufacturing and production, the need for sustainable and eco-friendly solutions is more pressing than ever.
The company’s strategy revolves around offering agile and sustainable manufacturing solutions. By streamlining production processes, reducing costs, and meeting the rising demand for eco-friendly products, Batch.Works hopes to transform the $726 billion industry.
Julien Vaissieres, CEO and Founder of Batch.Works, expressed his enthusiasm for the equity crowdfunding campaign, stating, “This campaign is the first and last chance to invest in our company at its current valuation. We hope this public campaign will make more people aware of our purpose, building a wider community around our business.”
Batch.Works’ commitment to sustainability is not just talk. With investments from Sustainable Ventures and government grants totaling £1.8 million, the company is well-prepared for future growth. They have already established a strong client base in various sectors, including furniture, retail, med-tech, and consumer electronics.
Over the past six years, Batch.Works has developed partnerships that have resulted in the production of 150,000 parts made from recycled or bio-sourced materials. While their current revenue model focuses on design consultancy and direct manufacturing services, Batch.Works plans to launch their CMaaS subscription model in 2024.
The CMaaS model entails a forward-looking cloud-based warehouse and scheduling software that will empower clients to adopt circular manufacturing processes for a monthly fee. By providing flexible, on-demand manufacturing capabilities and extending product life cycles, Batch.Works aims to reduce the capital investment and risks associated with traditional manufacturing methods.
Batch.Works’ past projects demonstrate their commitment to sustainable manufacturing. Collaborating with medical technology company Proximie, Batch.Works co-designed and manufactured custom solutions that are not commercially available. These include an enclosed, secure charging dock for Proximie’s technology in the operating room, protective casing and packaging for device safety, and smart glasses with added safety features for surgical procedures.
In collaboration with Sheep Inc., Batch.Works has created Merino wool clothing that minimizes environmental impact. The company also offers recyclable pilling combs to customers, setting a new standard for sustainable manufacturing in an industry that traditionally relies on non-recyclable combs with high minimum orders and long lead times.
Another successful partnership is with Morrama, resulting in the creation of eco-conscious kids’ headphones under the brand name Kibu. These colorful headphones are designed for responsible consumers, promoting easy assembly, repair, and recycling. Produced on-demand with 100% recycled PLA material derived from agricultural packaging waste, Kibu exemplifies Batch.Works’ commitment to sustainable and environmentally-friendly manufacturing.
In 2019, Batch.Works introduced its first-ever homeware collection, showcasing the possibilities of 3D printing. Collaborating with design studios Bold Design and UAU, the collection included lighting fixtures, containers, candle holders, and vases, all made from eco-friendly PLA plastic and reclaimed plastics from water bottles and packaging.
As awareness of the environmental impact of mass production grows, so does the demand for sustainable alternatives. Batch.Works is at the forefront of this movement, leveraging 3D printing technology to produce high-quality, eco-friendly products while minimizing waste and reducing reliance on fossil fuel plastics.
The company’s commitment to innovation and sustainability was further highlighted when they participated in the “SPARE PARTS: Rethinking Human Repair” exhibition held at Kings College London. Collaborating with Cellule, a London-based design studio, Batch.Works contributed to the production of personalized 3D printed hearts, exploring the concept of autonomous body parts detached from human anatomy.
The future of manufacturing is evolving, and Batch.Works is leading the way with its agile manufacturing systems and commitment to sustainability. By investing in Batch.Works’ equity crowdfunding campaign, individuals not only have the opportunity to support a groundbreaking company but also become part of a wider community dedicated to transforming the manufacturing industry and shaping a more sustainable future. Cast your vote now for the 3D Printing Industry Awards 2023 and join Batch.Works on this exciting journey!
In the rapidly advancing world of technology, one area that has garnered significant attention is 3D printing. This revolutionary technology has the potential to transform various industries and change the way we manufacture products. But what does the future hold for 3D printing? What are the engineering challenges that need to be overcome in the coming decade?
To start, let’s take a step back and understand what 3D printing is all about. Also known as additive manufacturing, 3D printing involves creating three-dimensional objects by adding layer upon layer of material. This is in contrast to traditional manufacturing methods, which often involve subtracting material through processes like cutting or carving.
The potential applications of 3D printing are vast and diverse. From creating prototypes and customized products to manufacturing complex structures, this technology is set to revolutionize various industries, including aerospace, healthcare, automotive, and consumer goods. But as with any emerging technology, there are significant engineering challenges that need to be addressed to unlock its full potential.
One of the primary challenges is the materials. While traditional manufacturing methods have a wide range of materials to choose from, 3D printing is currently limited by the selection of compatible materials. Research and development in this area are crucial to expanding the possibilities of 3D printing. Scientists and engineers are exploring new materials and improving existing ones to meet the demands of various applications.
Another crucial challenge is scalability. While 3D printing excels in producing intricate and small-scale objects, it faces limitations when it comes to manufacturing larger or more complex structures. The speed and efficiency of 3D printing need to be improved to make it a viable option for mass production. Engineers are working on developing faster and more accurate 3D printing techniques to address this challenge.
Robustness and reliability are also important factors that need to be improved in the additive manufacturing sector. To be widely adopted across industries, 3D printing must demonstrate consistent and reliable performance. Engineers are continuously working to enhance the precision, accuracy, and repeatability of 3D printing processes to ensure high-quality output.
Moreover, the integration of 3D printing with other manufacturing processes is an area that requires attention. Many industries rely on a combination of traditional and additive manufacturing methods. Developing seamless integration between these processes will enable manufacturers to optimize their production pipelines and achieve greater efficiency.
Addressing these engineering challenges will require collaboration and innovation across different disciplines. Scientists, engineers, researchers, and industry professionals need to work together to push the boundaries of 3D printing. This includes exploring new materials, refining manufacturing processes, enhancing software and hardware capabilities, and improving post-processing techniques.
As we look ahead to the next ten years, the future of 3D printing seems promising. Advancements in technology and engineering solutions will likely overcome the challenges we currently face. This will lead to further adoption of 3D printing in various industries and pave the way for new applications that we can’t even imagine today.
In conclusion, the coming decade holds immense potential for the additive manufacturing sector. While there are engineering challenges that need to be tackled, the strides being made in research and development give us hope for what lies ahead. As 3D printing continues to evolve, we can expect to see breakthroughs in material selection, scalability, reliability, and integration. The future of 3D printing looks bright, and it’s an exciting time to be part of this revolution. So stay tuned, as we witness the incredible journey that lies ahead for 3D printing.
“Why did the 3D printer go to therapy? Because it had too many layers of unresolved issues!”
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