What is CNC Machining

We have come a long way since the days of punched paper tape spools. Today, some mills can perform machining processes on five different axes without the need to remove and reposition the part in a fixture. This advancement leads to faster and more accurate production. CNC turning, which utilizes your 3D CAD models to create cylindrical parts, is accomplished using a high-speed CNC-controlled lathe. The concept is similar to removing slivers of wood from a spinning maple log (or white ash) to ultimately shape a baseball bat.

How Does CNC Machining Work

CNC machining differs from 3D printing in that it involves subtraction rather than addition. In CNC machining, you start with a solid block or cylinder made of metal or plastic and cut away material to achieve the desired shapes. This process can be likened to a high-speed form of sculpture, where drill-like tools called end mills replace traditional bits and chisels.

During milling, these end mills spin at incredibly high speeds, often reaching tens of thousands of revolutions per minute. The speed can be adjusted to prevent cutting errors or damage to more delicate materials, emphasizing that sometimes a slow and steady approach is best. The primary goal of CNC machining is precision, with tolerances as tight as ±0.001 inches (±0.025 mm).

What Are CNC Machining Benefits?

1. High Precision and Accuracy

Unlike manual machining, which relies on human skill and judgment, CNC machines follow programmed instructions with millimeter-level accuracy.

2. Repeatability and Consistency

Once a CNC machine is programmed and set up, it can produce identical parts with consistent quality. This repeatability is crucial for mass production, where each piece needs to meet the same standards.

3. Automation and Reduced Labor Costs

Once a program is created, the machine can run unattended for hours or even days. This automation leads to significant savings in labor costs, while also increasing production speeds.

4. Complex Designs and Customization

With advanced CAD/CAM software, designers can create detailed 3D models, and the CNC machine can replicate these designs with ease.

5. Efficiency and Speed

Once set up, they can produce parts quickly, allowing manufacturers to meet tight deadlines. CNC machining can handle tasks like drilling, milling, and turning simultaneously, which reduces cycle times and increases overall production efficiency.

6. Wide Range of Materials

CNC machines can work with a wide variety of materials, including metals (like aluminum, steel, and titanium), plastics, wood, and composites.

7. Improved Safety

CNC machines improve workplace safety by automating many of the risky tasks typically performed by workers, such as cutting, milling, or grinding.

8. Reduced Setup Time

Once the program is written and the machine is set up, CNC machining can be executed with minimal changeover time.

9. Low Maintenance

CNC machines are generally low maintenance compared to manual machines. While they do require periodic maintenance and calibration, the automation of the processes reduces wear and tear.

10. Scalability

Whether creating a small batch of prototypes or producing thousands of parts, CNC machining offers the flexibility to scale operations with minimal disruption to production efficiency.

11. Tool Life Optimization

CNC machining can automatically adjust parameters such as feed rate, spindle speed, and cutting depth to optimize tool life.

12. Integration with Other Manufacturing Processes

CNC machines can be integrated with other manufacturing processes, such as additive manufacturing, casting, or injection molding, to create more advanced parts or assemblies.

Types of CNC Machines and Cutting Tools

The technology behind machining has progressed a lot. For a long time, the basic lineup in every machine shop was CNC lathes with two axes as well as three-axis CNC machining centers. Some were horizontal while others were vertical however, for the vast part, work would bounce between both until all the machining steps were completed. In recent times, thanks to clever machine tool makers the distinction between mill and lathe has become blurred. Multitasking machines are multitasking machines that combine the spindle for milling and a tool changer with a lathe-style head as well as a turret (the part that houses all the equipment). Mill-turn lathes also incorporate stationary and rotating cutting tools, and turning machining centers have become more and more widespread. For instance, we employ lathes that have Live tooling to allow features like radial and axial grooves, holes, flats, and slots.

Machining centers could also include greater than 3 axes. For instance, a 5-axis mill can move across all of its axes simultaneously which is a feature that can be useful to make parts such as impellers as well as a variety of other complicated geometries. In addition, a traditional three-axis machine center could be fitted with an axis that is tilted and/or turns. This capability of 3+2 is great for machining multiple sides of a workpiece with one operation and eliminating the need to re-fixturing which creates more time in production. The exact configuration is what matters, and there are many of them–each type of machine is specifically designed to minimize manufacturing operations and enhance productivity flexibility.

Advantages and Common Applications of CNC Machining

Our CNC machining provides multiple benefits, including:

Precision and reproducibility
strict tolerances
high-quality production materials
Lower cost of piece-parts in larger quantity
strong post-processing capabilities that enhance the appearance of materials and cosmetics

As compared to injection molding CNC manufacturing produces parts with greater speed. Additionally, it provides greater precision in terms of dimensional accuracy than 3D printing (although this could change with new developments) and makes parts with more mechanical characteristics in three dimensions than 3D printing. It is true that CNC commonplace comes at a price increase and is typically associated with lower volumes of parts. It also offers lower flexibility when it comes to complicated geometries in comparison to the 3D printer.

As mentioned before, CNC machining is a preferred manufacturing method to create precise parts, be it for prototypes or production at the end of the line. It is extensively used in the medical, aerospace, and automobile industries due to its capability to produce parts quickly and precisely made of high-quality materials like:

enclosures and housings
brackets
Manufacturing equipment and fixtures
bearings and gears
Internal mechanical components
medical instruments

Common Materials for CNC Machining

Materials	Properties	Process
Aluminio	2024: Good fatigue resistance and strength; excellent toughness at moderate to high strengthlevels; improved fracture toughness 6061: Excellent machinability, low cost, and versatility 7075: High strength, hardness, low weight, and heat tolerance	Milling & Turning
Copper & Brass	High ductility and high electrical and thermal conductivity; develops attractive blue-green surface patina over time Versatile and highly attractive copper/zinc alloy with warm yellow color accommodates severe forming/drawing	Milling
Stainless Steel	Excellent machinability and outstanding uniformity; good workability and weldability, high ductility and formability	Milling & Turning
Titanio	Excellent strength to weight ratio, used in aerospace, automotive, and medical industries	Milling & Turning

Anodizing and Plating for Machined Parts

Anodizing

Anodizing is an electrochemical process that thickens the natural oxide layer on the surface of metals, most commonly aluminum. This results in the most durable and corrosion-resistant finish that allows for personalization in appearance and color.

While aluminum is the primary metal anodized, this technique can also be applied to other non-ferrous metals, such as titanium, magnesium, and zinc.

The anodizing process involves immersing the metal part in an acidic electrolyte bath and passing an electric current through it. The electrical current induces the metal to form an oxide-like layer over its surfaces. The oxide layer is permanently attached to the metal and increases the durability of the material.

Plating

Plating is a process that applies a metal coating to a part’s surface, often for decorative or protective purposes. Depending on the material being plated and the desired properties, this can be achieved through methods such as electroplating, electroless plating, or others.

Electroplating involves immersing the part in a solution containing metal ions and applying an electric current to bond the metal ions to the part’s surface. In contrast, electroless plating does not require an external electric current; the coating is deposited through a chemical reaction.

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