October 2025

Plastic furniture has become increasingly popular due to its light weight, durability, affordability, and resistance to moisture and corrosion. The manufacturing of plastic furniture involves a combination of material science, design precision, and advanced moulding technologies. Below is a step-by-step overview of the process: 1. Material Selection The first step in manufacturing plastic furniture is […]

IntroductionOvermoulding is a specialized moulding process in which one material—typically a soft thermoplastic elastomer (TPE) or another polymer—is moulded over a pre-existing substrate or component. In the case of electronic components, overmoulding provides both functional and protective benefits, such as insulation, shock resistance, moisture sealing, and improved aesthetics. Purpose and Advantages Overmoulding in electronics serves

Composite materials are engineered materials made by combining two or more distinct substances—typically a matrix and a reinforcement—to produce a material with superior mechanical, thermal, and chemical properties. The most common composites used in industrial moulding include fiberglass-reinforced plastics (FRP), carbon-fiber composites, and kevlar-reinforced polymers. These materials are increasingly preferred in automotive, aerospace, marine, and

Rapid prototyping has become an essential tool in modern plastic furniture manufacturing. It enables designers and engineers to transform digital concepts into physical models quickly, helping to visualize, test, and refine designs before investing in expensive production moulds. By integrating rapid prototyping techniques, manufacturers can significantly reduce development time, improve product quality, and enhance design

Introduction:Transfer moulding is a widely used process for producing high-precision and complex thermosetting plastic components. In this process, the plastic material is preheated and then forced into a closed mould cavity through sprues and runners using a transfer plunger. With advancements in technology, electronic control systems have been integrated into transfer moulds to enhance precision,

High-Performance Plastics in Automotive Components Introduction The automotive industry is continuously evolving to meet demands for lighter, stronger, and more fuel-efficient vehicles. High-performance plastics (HPPs) have become a crucial part of this evolution, offering superior properties compared to conventional materials like metals and standard polymers. These plastics enable engineers to design components that are lighter,

Design defects are flaws that occur during the conceptual or planning phase of a product, structure, or system. Unlike manufacturing defects, which arise during production, design defects stem from errors or oversights in the design itself. These defects can lead to performance issues, safety risks, or even complete product failure. Understanding the most common design

Introduction Electronic compression moulds are specialized moulds used for manufacturing electrical and electronic components such as switch housings, plug tops, connectors, circuit breaker parts, and other insulating components. These moulds are designed to produce high-precision parts using thermosetting materials like phenolic, melamine, or epoxy resins that can withstand heat, electrical stress, and mechanical load. Working

Automobile moulds are used extensively in the manufacturing of vehicle components such as bumpers, dashboards, lighting parts, and interior panels. The performance, durability, and precision of these moulds largely depend on the type of material used for their construction. Selecting the right mould material ensures better surface finish, longer life, and cost-effectiveness in production. Below

1. Introduction In the modern furniture industry, the demand for innovative designs, precision manufacturing, and rapid production has grown significantly. To meet these needs, Computer-Aided Design (CAD) and Computer-Aided Manufacturing (CAM) technologies have become essential tools in mould design and production. These technologies bridge the gap between creative design and physical manufacturing, enabling designers and