Neway Precision Works Ltd R&D Team

 In fashion and luxury, watch accessories are not just timekeeping instruments but also pivotal personal adornment and style elements. These accessories—ranging from elegant bezels and sophisticated dials to durable clasps and bands—play a crucial role in defining the aesthetic and value of a timepiece. As consumers increasingly seek out unique and high-quality products, the demand for innovative manufacturing techniques that deliver precision, durability, and beauty has never been higher. Enter Ceramic Injection Molding (CIM) and Metal Injection Molding (MIM) , two revolutionary manufacturing methods that have transformed the production of metal and ceramic watch accessories. These advanced technologies offer unparalleled design flexibility, material efficiency, and production scalability, making them indispensable tools in creating luxury watch components. MIM and CIM combine the structural complexity of plastic injection molding with the excellent properties of metal and ceramic m

 The plasma cutting process is a sheet metal fabrication process . It has become one of the most popular and widely used thermal cutting processes in industrial fabrication and manufacturing. Its ability to cut through all conductive metals with precision and speed makes it a versatile choice for many applications. However, like any process, plasma cutting has advantages and limitations. Pros of Plasma Cutting Cutting Speed One of the most significant advantages of the plasma cutting process is its very high cutting speed capability. Plasma systems can make straight cuts at over 100 inches per minute on thin gauge metal less than 1/4" thickness. This is around 2-3 times faster than processes like oxyfuel or laser cutting. The high speed is achieved because the plasma jet melts a very narrow kerf width of only 1/16" to 1/8". Plasma still maintains faster cutting speeds on thicker steel plates than other methods. Cut speeds will reach 30-40 pm on 1" mild steel with h

  Laser cutting is an efficient sheet metal fabrication service . It has revolutionized modern manufacturing, enabling the production of highly intricate, precise, and complex components. The demand for laser-cut parts has surged across industries like aerospace, automotive , electronics, and medical devices as engineers and designers push the boundaries of innovation. Laser cutting allows manufacturers to create geometries and features that are impossible through conventional machining or fabrication methods. This article will walk through the laser-cutting process step-by-step, examine the critical factors that influence cut quality, and highlight the advantages that make laser cutting a go-to technology for high-precision manufacturing. Laser Cutting Process Step-by-Step How exactly does laser cutting work to churn out such accurate, repeatable parts on a mass-production scale? Here's a play-by-play: Design and Programming It all starts with the right design. A CAD file is uplo

  What is Ceramic Injection Molding (CIM) Ceramic Injection Molding (CIM) is a manufacturing process used to produce complex and precise ceramic components. It is based on traditional plastic injection molding and sintering process principles but is adapted for ceramics, which are inherently more rigid and brittle materials.  The CIM process involves the following steps: 1. Feedstock Preparation: Ceramic powders are mixed with binders and other additives to create a homogeneous feedstock. The binders make the mixture more pliable and suitable for ceramic injection molding.  2. Injection Molding: The prepared feedstock is injected into a mold cavity under high pressure and temperature using an injection molding machine. The mold is typically steel and designed to shape the final ceramic part. 3. Debinding: After injection molding, the green ceramic part still contains the binders. The molded parts are subjected to a debinding process, where the binders are removed either thermally (the

 The automotive industry, a global manufacturing cornerstone, relies heavily on metal parts to construct vehicles. These parts, from engine components to structural frames, are integral to automobiles' functionality, safety, and performance. Manufacturing these large auto parts utilizes specialized processes, notably stamping and deep-drawn techniques, to shape metal sheets into precise, complex forms. Stamping and deep drawing are critical in producing large, durable auto parts with high precision. Stamping involves pressing flat metal sheets into a desired shape using a die and a press machine. This process is ideal for quickly and efficiently creating large quantities of parts with uniform specifications. On the other hand, deep drawing extends this principle to produce parts with a depth greater than their diameter, enabling the creation of complex, hollow shapes that stamping alone cannot achieve. Both processes are fundamental in manufacturing robust components like car bod

 In modern manufacturing and design, engineering plastics stand out as a cornerstone, bridging the gap between standard materials and the demanding requirements of advanced applications. These materials surpass conventional plastics in performance and offer a versatility that engineers and designers rely on to push the boundaries of what's possible in technology and innovation. This article aims to illuminate engineering plastics, delineate their defining characteristics, and explore the expansive universe of applications made possible through the precision of  plastic injection molding . Engineering plastics are renowned for their robustness, heat resistance, and mechanical stability, which make them indispensable in sectors as diverse as  automotive ,  aerospace ,  electronics , and  medical devices . Unlike their standard counterparts, these materials are engineered to withstand harsh environments, bear significant loads, and endure wear and tear over extended periods while main