Neway Precision Works Ltd R&D Team

 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

  Die casting is a versatile and efficient manufacturing process that produces high-quality metal parts with intricate shapes and excellent dimensional accuracy. At its core, die casting involves forcing molten metal under high pressure into a mold cavity. This method is favored for its speed, precision, and the superior quality of the final product. Material selection plays a pivotal role in die casting. The choice of metal influences the part's properties and affects the production process, cost, and application suitability. Zinc and aluminum are two of the most popular choices among the various metals, each bringing unique characteristics. Differences Between Zinc Die Casting Vs. Aluminum Die Casting Material Properties: Cast Aluminum And Zinc Understanding the material properties of aluminum and zinc is crucial for selecting the suitable metal for your die-casting project. Each metal has distinct physical and mechanical characteristics that affect its performance and suitabili

  Understanding Common Defects in CNC Machining CNC machining is a cornerstone in modern manufacturing, offering unparalleled precision and repeatability. CNC Machining prototyping has revolutionized how parts are made, contributing significantly to advancements in various industries, from aerospace to automotive. However, like any manufacturing process, CNC machining has. Understanding and addressing common defects is crucial for maintaining high quality and efficiency. This blog will delve into the typical defects encountered in CNC machining. By recognizing these issues, manufacturers can take proactive steps to mitigate them, ensuring the production of high-quality parts. Whether you're a seasoned engineer or new to CNC machining, this exploration will enhance your knowledge and help you better navigate the complexities of this advanced manufacturing process. Let's begin by understanding CNC machining and why identifying common defects is vital for success. Overview of CN

  Tungsten Metal Injection Molding (MIM) is a sophisticated process in the realm of custom parts manufacturing, particularly in the field of powder metallurgy. This method combines powdered metal technology's benefits with injection molding's flexibility, producing intricate and high-density tungsten components. Process Highlights: Powder Preparation:  The process initiates with fine tungsten powder, meticulously chosen for its quality and particle size distribution. The powder is mixed with a binder to form a feedstock, ensuring optimal flow during the injection stage. Injection Molding:  The prepared feedstock is injected into a mold cavity under high pressure. The mold is intricately designed to replicate the desired shape of the final tungsten part. This step allows for the production of complex geometries with exceptional precision. Debinding:  After injection molding, the formed green part undergoes debinding to remove the binder from the matrix. This step is critical fo