Custom CNC Lathe Parts Copper Turning Parts Service CNC Machining Medical

CNC Parts

High Precision CNC Copper Parts , Aerospace Industrial CNC Milling Components

CNC machining, which stands for computer numerical control machining, is a subtractive

manufacturing technique that involves the integration of computerized controls and machine

tools. This combination is employed to methodically eliminate layers from a solid material block.

Programmed instructions dictate the desired metal cuts and correspond to specific tools and

machinery, enabling the automated execution of the machining process.

Product Details

We specialize in the production of custom-made products and offer surface treatment services

tailored to meet our customers' specific requirements and industry standards.

Our comprehensive solutions are both efficient and cost-effective, making us a one-stop

destination with the capacity and capability to provide integrated services.

CNC Machining Applications

1. Aerospace:
CNC machinery is pivotal in the aerospace industry for the fabrication of intricate and precision

components used in aircraft and spacecraft.

2. Automotive Parts Manufacturing:
The automotive industry extensively relies on CNC machining for the production of precise and

customized components used in vehicles.

3. Medical Machine Manufacturing:
CNC machining plays a crucial role in the medical industry, contributing to the manufacturing

of intricate components for medical devices and equipment.

4. Transportation:
Industries involved in transportation, such as railways and mass transit, utilize CNC machinery

for the production of components ensuring efficient and reliable transportation.

5. Defense:
The defense industry benefits from CNC machining for the production of accurate and complex

components essential for various defense applications.

6. Marine:
In the marine industry, CNC machinery is employed for the manufacturing of precision parts

used in boats and marine equipment.

7. Oil and Gas:
The oil and gas industries leverage CNC machining to fabricate components used in exploration,

drilling, and extraction processes.

8. Electronics:
The electronics industry relies on CNC machinery for the production of intricate components used

in electronic devices, ensuring precision and reliability.

Company Profile

FAQ's

1. Machined Parts Tolerances Overview:

Our tolerances for machined parts are as follows:

Local tolerances of +.005”/- .005” are applicable across most geometries in metals, with a

variation of +/- 0.010" for plastics. Tolerances may differ for large parts, particularly

concerning flatness over large parts after heat treatment.

For "As Milled" finish, a minimum surface finish of 125 is required for CNC parts.

All fabricated parts adhere to a dimensional tolerance of 0.010” and an angular tolerance of 1°.

Tapped holes not explicitly called out as features on the quoted CAD model may be machined to

the diameters specified in that model.

Surface treatments (e.g., anodize, bead blast, iridite, powder coat, etc.) will not be applied unless

explicitly paid for and acknowledged.

2. Surface Texture in CNC Milled and Turned Parts:

In the realm of CNC machining, the general surface texture of as-machined milled parts typically

exhibits a roughness of approximately 3.2μm (1.6μm for relatively new machines).

On the other hand, turned parts can achieve a finer surface with a roughness of 0.8μm.

Notably, this level of surface quality is attained without the need to adjust the machining speed.

3. Understanding CNC Machining Costs:

The cost of CNC machining a part is influenced by various factors, including:
1. Material: The choice of material significantly impacts cost. Machining materials like Inconel

are more expensive due to increased tool wear and slower cutting speeds compared to materials

like aluminum.

2. Complexity: Parts with complex features are more expensive to machine. For instance,

components with intricate surface shapes incur higher costs than those with flat surfaces.

3. Tolerances: Tight dimensional tolerance requirements contribute to higher costs.

Over-specifying tight tolerances on non-critical features can increase CNC machining expenses.

4. Surface Finish: Achieving mirror finishes demands specialized tooling and machining strategies,

prolonging machining time and elevating costs.

5. Quantity: Low-volume production is inherently costlier per part than large-volume production.

The higher fee stems from spreading initial setup and programming costs over fewer parts.