Carbon, a leading 3D printing company, has introduced an innovative approach to manufacturing complex and customizable lattice structures using a variety of elastomeric materials. This breakthrough could significantly impact or even disrupt the traditional foam industry, which has long relied on bubble-based structures for comfort, safety, and performance applications. Carbon’s new solution allows users to input specific design parameters into their software, and the system automatically recommends the most suitable grid structure and material for the intended use.
The technology is built on Carbon’s CLIP (Continuous Liquid Interface Production) method, which enables rapid and precise 3D printing of intricate designs. With this new lattice solution, designers can create parts with varying densities and mechanical properties in a single component, offering greater flexibility than conventional foams. Unlike traditional foams, which have limitations in terms of breathability and adjustability, 3D-printed lattices are open structures that allow for better airflow and customizable compression profiles.
In terms of comfort, Carbon highlights that while foam is widely used in products like headphones, seating, and orthopedic pads, it often lacks the ability to provide tailored support. The 3D-printed grid structures offer improved breathability and can be adjusted to deliver different levels of cushioning depending on the application. This makes them ideal for replacing foam in a wide range of consumer goods.
Safety is another key area where Carbon’s technology shines. Foam-based materials like EPS are commonly used in helmets and car seats to absorb impacts. However, Carbon claims its 3D-printed grids can match or exceed these protective qualities while also allowing for more customized designs. For instance, athletes can benefit from personalized helmet or pad designs that offer enhanced protection based on individual needs.
Performance is where the real-world impact of Carbon’s innovation becomes most evident. The company has already partnered with Adidas to bring its Futurecraft 4D shoes into mass production. These shoes feature a midsole with different lattice structures in the heel and forefoot, providing optimized cushioning during running. This level of customization and precision was previously unattainable with traditional foam materials.
By integrating 3D-printed lattices into product design, Carbon is not only pushing the boundaries of what’s possible in material science but also challenging the dominance of foam in multiple industries. As more companies adopt this technology, we may see a shift toward more sustainable, functional, and user-centric solutions across sectors like healthcare, automotive, and sports.
Din Rail Terminal Block
Basic Features
1. The terminal has universal mounting feet so that it can be installed on U-rail NC 35 and G-rail NC32.
2. The closed screw guide hole ensures ideal screwdriver operation.
3. Equipped with uniform accessories for terminals of multiple cross-section grades, such as end plates, grouping partitions, etc.
4. Potential distribution can be achieved by inserting a fixed bridge in the center of the terminal or an edge-plug bridge inserted into the wire cavity.
5. The grounding terminal and the N-line slider breaking terminal with the same shape as the common terminal.
6. Using the identification system ZT, unified terminal identification can be realized.
7. The rich graphics enhance the three-dimensional sense of the wiring system.
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