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  • Brishine United Industry Co.,Limited
  • Address : No 218, Dieyuan Road, Shounan Street, Yinzhou, 315100, Ningbo, China
  • Email : [email protected]
  • Tel : +86 574 87907106
  • Fax : +86 574 87485095
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Custom Precision Machining Parts Manufacturers

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Brishine United Industry Co.,Limited is a professional China Custom Precision Machining Parts Manufacturers and Precision Machining Parts Factory, We have been in custom metal parts field for nearly 15 years, with ISO 9001:2015 certification. We specialize in manufacturing China Custom Precision Machining Parts according to customer specifications. Due to continuous expanding of business, we invested a new building which was built in 2016 occupying an area of more than 3000 square meters. We have 2 production lines: precision steel castings; and precision CNC and turning parts. Brishine can supply you with a sustainable supply chain that increases your productivity and reduces your cost. We will be your excellent partnership for your custom needs.

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*[Industry Knowledge Development]*

Precision machining parts can be made from a wide variety of materials, including metals (steel, aluminum, brass, titanium), plastics, and composites. The specific materials used will depend on the design and function of the parts, as well as the equipment and capabilities of the machining shop. Some of the most commonly used materials for precision machining include:
Steel: Steel is a strong and durable metal that is widely used in precision machining. It can be easily machined and heat treated to achieve a wide range of mechanical properties.
Aluminum: Aluminum is a lightweight metal that is easy to machine and has good corrosion resistance. It is often used in precision machining for parts that need to be lightweight and/or have a high strength-to-weight ratio.
Brass: Brass is a soft, malleable metal that is easy to machine and has good corrosion resistance. It is often used in precision machining for parts that require good wear resistance and low friction.
Titanium: Titanium is a strong, lightweight metal that is difficult to machine but has excellent corrosion resistance and a high strength-to-weight ratio. It is often used in precision machining for parts that require a combination of strength and light weight.
Plastics: Plastics are widely used in precision machining for a variety of applications. They can be machined into a wide range of shapes and sizes, and are often used for parts that require good wear resistance, low friction, and/or good electrical or insulating properties.
Composites: Composites are materials made from a combination of two or more materials, typically a matrix material reinforced with fibers or particles. They can be machined into a wide range of shapes and sizes, and are often used in precision machining for parts that require a combination of strength, stiffness, and lightweight.

Some of the key features of precision machined parts include:
High accuracy and tight tolerances: Precision machining can produce parts with extremely high levels of accuracy, with tolerances often as low as a few thousandths of an inch (0.001").
Smooth surface finishes: Precision machining can produce parts with very smooth surface finishes, with roughness values often below 16 microinches.
Dimensional stability: Precision machined parts are highly stable dimensionally, meaning that they will maintain their size and shape over time, even under extreme conditions.
Repeatability: Precision machining can produce parts with high levels of repeatability, meaning that multiple copies of the same part will be virtually identical.
Versatility: Precision machining can be used to produce parts from a wide range of materials, including metals, plastics, and composites.
Complex geometries: Precision machining can be used to produce parts with complex shapes and features that would be difficult or impossible to achieve using other manufacturing methods.

There are several key steps involved in the precision machining process, including:
Designing the part: The first step in the precision machining process is to create a detailed design of the part. This typically involves the use of computer-aided design (CAD) software to create a digital model of the part.
Programming the CNC machine: Once the design of the part has been completed, the next step is to program the CNC machine to produce the part. This typically involves writing a series of instructions in a programming language called G-code, which tells the machine how to move and what tools to use.
Setting up the machine: Before the machining process can begin, the CNC machine must be set up with the appropriate tools and workpiece. This typically involves mounting the workpiece in a chuck or fixture, and selecting and installing the correct cutting tools.