CNC machining has steadily become a cornerstone of high-volume manufacturing. Its repeatability, versatility, and precision position it uniquely in the production industry. Whether you’re creating multifaceted or moderate modules, the technique offers a wide range of quality and efficiency benefits.
However, it doesn’t come without challenges. Although you can get quality services, understanding these problems allows you to seek strategic solutions to improve your production.
7 Common CNC Machining Challenges
Let’s explore common difficulties you can encounter with CNC machining, the possible causes, and practical solutions.
1. The Cost of Software and Equipment
CNC machines often have several features to enhance their efficiency and capabilities. Features like high-speed spindles and automated tool changers increase productivity but come at an additional cost. The corresponding software is another significant cost that can be prohibitive for medium to small-sized businesses. Ongoing expenses for periodic updates and licensing fees for CAD/CAM software are also high.
However, you can conduct a thorough analysis to ensure your investment will yield sufficient results. Leasing machines is another alternative to minimize the initial capital expenditure, especially if you’re a beginner. You can seek financial support from government grants for technological upgrades.
2. Challenges with Material Selection
Selecting the right CNC machine materials significantly affects production, component quality, and cost. Choosing materials is a complex challenge involving consideration for the end-use of the components, cost-effectiveness, and CNC machining compatibilities.
Material selection directly affects the production process and quality of the final product. Each material has its challenge;
- Plastics – Their properties vary widely; some deform or melt due to heat. Others are too brittle and break or crack easily, leading to losses or substandard final products.
- Aluminum – Aluminum is ductile and soft, making it easy to work with. However, it can stick to cutting tools, leading to delays or damage to tools.
- Titanium – Titanium uniquely offers excellent corrosion resistance and strength. However, its CNC machining is challenging due to its high heat resistance and hardness. As a result, it causes tool wear and tear and requires specialized strategies to work on.
- Stainless Steel – While it’s tough for added durability, stainless steel causes rapid wear on cutting tools. It leads to high maintenance costs that most small to medium-sized enterprises find hard to sustain.
The idea is to select materials that are easy to work on CNC machines while improving production and increasing revenue.
3. Tool Wear and Maintenance
CNC machining increases the production and precision of components. However, with the introduction of composite materials and heat-resistance metals, cutting tools increasingly wear out. Prolonged operation periods and malfunctions are the most prevalent challenges. Mechanical and thermal stresses also lead to tool wear.
The common wear types include:
- Crater wear: It often appears on the rake face of a cutting tool, caused by chemical reactions. It’s an abrasive wear that’s common in high-speed cutting operations. To prevent crater wear, ensure you reduce cutting speeds and use coated cutting tools to provide an extra layer of thermal barrier.
- Thermal cracking: It results from periodic heating and cooling cycles. The cutting tool then expands and contracts repeatedly, causing microcracks. Thermal cracking can be prevented by maintaining a consistent cooling strategy. You can also use ceramic tools that are more resistant to high thermal shock.
- Adhesive wear: This type of wear occurs when there is sticking or welding between the material and the tool. Increased cutting speed minimizes adhesion at low temperatures.
- Frank wear land: It’s a uniform abrasion on the edge of a CNC machining cutting tool caused by severe friction. It’s caused by high temperatures, hardness of the materials, and friction.
Once tools wear, they deviate from specifications, causing defects in the end-use products. Regular inspections allow early wear and tear detections, facilitating timely replacements. More so, using appropriate coolants reduces thermal stress on tools, reducing wear.
4. Skills Required
Operating CNC machines effectively is a high-demand skill in the fabrication and manufacturing industries. Having a good CNC machine is not enough to improve your production. You need skilled labor for exceptional outcomes. The shortage of machinists can lead to increased costs and inefficiencies, factors that lead to huge losses.
A combination of practical experience and technical knowledge is required. The operator should understand a CNC system’s software and hardware aspects to achieve optimal production results.
For better results, a detailed training program for employees should be deployed. You can also collaborate with certified educational institutions that prepare students for CNC machining. Besides, you can purchase or lease automated CNC machines to minimize the dependency on skilled labor for simple tasks.
5. Production Speed
The primary goal of a CNC machine is to achieve quality products within the shortest time possible. However, balancing accuracy and speed is a significant challenge in the manufacturing industry. Increasing production speed may achieve more products but affect products’ final quality.
Understand the speed at which a CNC machine can operate without affecting the accuracy. Pushing the system beyond its capacity results in quick wear and tear. Apply lean manufacturing principles to reduce waste and streamline operations.
6. Repair Costs
CNC machines encounter various defects like equipment failure and wear and tear of machining tools. Machines that are continuously operated without proper maintenance tend to have frequent breakdowns. Some machines also require expensive spare parts that are sometimes hard to procure.
You can equip your in-house technical team with the necessary skills to repair some components. This reduces reliance on costly external services, lowering repair costs. You can also implement preventative maintenance to reduce frequent breakdowns.
7. Design Limitations
The relationship between manufacturability and design often restricts CNC machines’ capabilities. Producing intricate components can be challenging due to the movement and accessibility limitations of tools. Machine components with thin walls cause material breakage or deformation due to exerted pressure.
Some designs need materials that are difficult to machine. Such materials include super alloys and titanium, which will likely affect the tool’s life.
Wrapping Up
Integrating skilled personnel and advanced technology continues to drive the CNC machining industry forward. As the industry evolves, you need to adopt techniques to solve the arising challenges. This way, manufacturers will meet the needs of a wide array of industries.