Custom CNC Machined Aluminum Plastic Gear Support Connector 3D Printing Precision Parts

Our Factory

Shenzhen Pans Technology Co., Ltd is committed to revolutionizing digital intelligent manufacturing by combining traditional methods with additive manufacturing. Our comprehensive services include 3D scanning, 3D printing, machining, metal production, and mold manufacturing. We strive to offer both domestic and international clients with customized manufacturing solutions from concept to final product, simplifying the development process and lowering market promotion expenses.

Process Introduction

Fused Deposition Modeling (FDM): Use heated thermoplastic materials (such as ABS, PLA) to extrude through a nozzle and accumulate layer by layer to form an object.

Selective Laser Sintering (SLS): Use a laser beam to sinter powder materials (such as nylon, metal powder) layer by layer to form a solid structure.

Stereolithography (SLA): Use ultraviolet light to cure liquid photosensitive resin, solidify layer by layer and form an object.

Electron Beam Melting (EBM): Use an electron beam to melt metal powder at high temperature, suitable for high-precision metal printing.

Advantage of 3D printing

Customization: 3D printing can be customized according to individual needs, especially in the medical and consumer goods fields, and can produce personalized products.

Save materials: Unlike traditional manufacturing methods, 3D printing uses a layer-by-layer stacking method, which reduces material waste.

Accelerate the production cycle: By printing products directly from design files, the time for mold making and other preparations is reduced, significantly shortening the product design to production cycle.

Realization of complex designs: 3D printing can realize complex geometric shapes that are difficult to produce with traditional manufacturing methods, providing more design freedom.

Printing Material

Inspection

In our company's workshop, parts inspection is a crucial step in ensuring product quality. Before any part is processed, the factory inspects the raw materials to confirm that the material and appearance are acceptable, preventing errors from the outset. After the first product is completed, operators conduct a first-piece inspection to confirm that the dimensions match the drawings; only after this is done will mass production continue.

During production, quality inspectors conduct random checks, focusing on key dimensions and appearance. If any deviations are found, equipment is adjusted promptly to prevent the problem from escalating. After all parts are processed, a final inspection is performed to ensure that dimensions, appearance, and quantity meet requirements before packaging and shipping.

Through this step-by-step inspection process, the factory can reduce rework and scrap, ensuring that every part delivered to the customer is qualified and reliable.

Certifications

As a company specialized in customized machining parts, Pans Technology places quality at the core of its business operations. We recognize that every customer drawing is unique and every component plays a critical role in the final application. In a custom manufacturing environment, consistent quality relies not only on advanced machining capabilities but also on a well-structured and effectively implemented quality management system.

Pans Technology is certified to ISO 9001, AS9100, and IATF 16949, which demonstrates our strong commitment to internationally recognized quality standards. These certifications reflect our ability to manage complex manufacturing processes and to meet the rigorous quality requirements of customers across aerospace, automotive, and industrial sectors.

ISO 9001 provides the foundation for Pans Technology’s quality management system and supports our customized machining operations. By adopting a customer-focused and process-based approach, we have established structured controls covering contract review, process planning, raw material procurement, machining, in-process inspection, final inspection, and delivery. This systematic framework enables Pans Technology to effectively manage quality risks, even in low-volume, high-mix, and high-precision custom machining projects, ensuring that every part is produced strictly in accordance with customer drawings and specifications.

AS9100 is a quality management system standard specifically developed for the aerospace and high-reliability manufacturing industries. Operating under the AS9100 system strengthens Pans Technology’s capabilities in risk management, critical process control, documentation, and full product traceability. This certification demonstrates that Pans Technology is capable of supporting applications where safety, reliability, and precision are essential, and where strict quality control is mandatory.

IATF 16949 is the globally unified quality management system standard for the automotive industry. Through the implementation of IATF 16949, Pans Technology has established a systematic approach to defect prevention, process stability, and continuous improvement. This enables us to maintain consistent quality performance in repeated or batch production of customized machining parts and to meet the long-term supply expectations of automotive customers.

In conclusion, ISO 9001, AS9100, and IATF 16949 certifications are not merely formal credentials, but a reflection of Pans Technology’s long-term commitment to standardized management, precision manufacturing, and customer-oriented quality assurance.

Packing

Proper and standardized packaging effectively protects parts during transportation and storage.

Machine-machined parts come in a wide variety of materials, including carbon steel, stainless steel, aluminum alloys, copper alloys, and cast iron, each with different packaging requirements. For high-precision parts and products with stringent surface finishes, the primary task of packaging is to prevent bumps, scratches, and deformation. Cushioning materials such as pearl cotton, foam, and EVA lining are typically used for individual isolation, ensuring that parts do not come into contact with each other and preventing damage from transportation vibrations.

Rust and corrosion prevention are also crucial aspects of machine-machined packaging. Metal parts are prone to rust in humid environments, especially precision-machined surfaces, which require extra protection. Common practices include applying rust-preventive oil before packaging or using rust-proof paper or bags for sealed packaging. For export products, the long-term maritime environment necessitates even higher requirements for the moisture-proof performance of the packaging.

For outer packaging, wooden crates, plywood crates, and reinforced cardboard boxes are widely used. Wooden crates are suitable for heavier or more complex parts, providing greater overall strength; cardboard boxes are better suited for smaller parts, balancing cost and ease of transport. The outside of the packaging is usually clearly marked with the part name, quantity, order number, weight, and shipping markings such as "Fragile," "Moisture-proof," and "Here," to reduce human risk during loading, unloading, and logistics.

Furthermore, standardized packaging procedures are an important part of a quality management system. Good packaging not only protects the parts themselves but also reflects the machining company's responsibility to product quality and customers, laying a solid foundation for long-term, stable partnerships.