Budget custom copper parts manufacturers: Tooling Precision and Press Capabilities – Forming, stamping, and bending are frequent operations used in copper parts. The repeatability, as well as the edge definition, directly depends on tooling precision. The supplier has to keep their dies, jigs, and fixtures in proper condition so as to produce dimensionally stable products. Enquire about the press tonnage and depth limits of forming. Are they capable of turns with a tight radius without cracking the edges? There should be proper die registration and forming pressure control in the case of small part tolerances. In electronics or cooling systems sectors, tolerances are usually measured in microns. A good manufacturer provides accurate batch to batches. They can validate wear of tooling, calibration of the press, as well as die life. Read more information on copper turned components manufacturer.
Standardize Features: Using standard hole sizes, thread pitches, and other features can reduce the need for custom tools and simplify the machining process. Standard features are easier to produce and often result in lower costs. Simplify Geometries: Complex geometries can increase machining time and tool wear. Simplifying your part design where possible can lead to faster machining and lower costs. Avoid unnecessary intricacies that don’t add functional value to the part.
The factory has strong technical force, with 45 professional mold technicians and 5 mold design engineers, from product evaluation to mold design, manufacturing, assembly and production, a one-stop service. There are 70 sets stamping machines, punching tonnage from 25-200 tons, stamping speed can reach 1200 times/ min. We can produce different material with thickness 0.1-5.0MM, Single stamping terminal monthly maximum capacity is 30 million pieces, shrapnel is 5 million pieces. At present, the utilization rate of equipment stamping equipment is 60%. The factory has 40 sets of 5-axis CNC machines and 2 sets of 6-axis CNC machines that imported from Japan. The processing diameter is from 1.0-32MM, the processing precision is 0.005MM, and it can process different materials. The current equipment utilization rate is 70%. The factory is located in the Matigang Industrial Zone, Dalingshan Town, Dongguan City, a famous manufacturing city, 500 meters away from the highway intersection and 40 minutes drive from Shenzhen Airport.
When we receive the inquiry, we will provide the quotation according to the drawings (CAD drawings, 3D data, PDF drawings) within 2 days, including mold charge, unit price, MOQ and lead time, etc. The price depends on the product and the customer’s requirements. Customer quotation confirmation – After a discussion, the customer confirms the price and sends us a mold order. Mold deposit prepayment – Next, according to our quotation and customer payment terms, the customer arranges the mold prepayment, most of which is 30%-50% of the entire mold price. At the same time, our R&D department will conduct detailed technical assessments and manufacturability assessments based on customer drawings. In general, we will give reasonable advice based on the mechanical properties of the customer’s raw materials, product structure and other subsequent treatments (such as electroplating, heat treatment and anodizing) to maximize the stability and sustainability of the production.
At present, our company has introduced 3 sets of Sei bu slow wire cutting machines, whose processing accuracy is within 0.002MM. They are mainly used to process various precision, small and complex terminals, shrapnel, and bracket molds. They mainly control product accuracy while also improving cutting, Speed, the cutting speed can reach 220mm/min. Fortuna has 8 sets of grinders, among which the machining accuracy can reach within 0.002mm. It is capable of precision grinding of various materials and is easy to operate. It can not only complete the processing of conventional parts such as shafts and ball shaft couplings, and can also complete the processing of parts with various complex shapes. Discover extra information at dgmetalstamping.com.
Customization of mold materials: select appropriate mold materials and processing methods based on the structure and material requirements of customer products to ensure that the mold produces products that meet customer drawing requirements; Product size and design customization: assist customers in optimizing drawings and designing and optimizing molds to meet the specific functional requirements of the product. Customization of quality requirements: set product quality standards according to the actual needs of customers. If necessary, cooperate with customers to purchase corresponding quality testing equipment to ensure that the products produced meet customer requirements.
CNC machining is a cornerstone of modern manufacturing, known for its precision and versatility. Whether you’re crafting intricate aerospace components or robust automotive parts, the design phase is critical. Getting it right can mean the difference between a smooth, efficient production run and costly, time-consuming errors. In this guide, we’ll explore essential tips and best practices for designing parts specifically for CNC machining. From selecting the right materials and understanding tolerances to optimizing tooling and prototyping, we’ll cover all aspects to help you create high-quality, cost-effective CNC machined parts.
Different materials may require different tool materials and coatings. For example, carbide tools are excellent for cutting hard metals, while high-speed steel tools might be suitable for softer materials. Matching the tool to the material and the specific machining task can enhance efficiency and part quality. Tool Path Optimization – Tool path planning is essential for reducing machining time and improving efficiency. Effective tool path strategies like climb milling, where the cutting tool rotates in the same direction as the material is fed, can reduce tool wear and improve surface finish. Trochoidal milling, a technique that uses circular tool paths, can also be beneficial for removing material efficiently. By optimizing tool paths, you can reduce machining time, minimize tool wear, and achieve better part quality.