If you’re a CAD designer working onتصنيع CNC أجزاء, small design errors can lead to big problems: broken tools, wasted material, or parts that don’t fit. الأخبار السارة? Most mistakes are easy to avoid once you know what to look for. هذا الدليل ينهار 6 most common CNC design blunders, مع أمثلة حقيقية, بيانات, and step-by-step fixes to save you time, مال, والإحباط.
1. خطأ 1: Designing Walls That Are Too Thin
Thin walls might seem like a way to save material—but they’re a disaster for CNC machining. Thin sections vibrate during cutting, break easily, or lose precision.
لماذا هي مشكلة:
Low-stiffness materials (مثل الألومنيوم) are especially risky. على سبيل المثال, أ 0.5 mm aluminum wall will twist or crack when a milling tool applies pressure. Even slightly thicker walls (0.6–0.7 mm) can warp, as the tool’s vibration bends the material.
Key Guidelines for Wall Thickness:
| مادة | Minimum Recommended Thickness | Unofficial Industry Standard | Risk of Failure (If Too Thin) |
|---|---|---|---|
| الألومنيوم (6061) | 0.8 مم | 0.794 مم | 70% (twisting or cracking) |
| فُولاَذ (1018) | 1.0 مم | 0.794 مم | 50% (تزييف) |
| البلاستيك (القيمة المطلقة) | 1.2 مم | 0.794 مم | 80% (melting or breaking) |
مثال حقيقي:
A designer created a 0.6 mm thick aluminum bracket for a drone. During milling, 9 خارج 10 brackets broke because the tool’s vibration bent the thin walls. When they increased the thickness to 0.9 مم, the success rate jumped to 98%—and the bracket still weighed less than 5 غرام (no extra material waste).
كيفية إصلاحه:
- Follow the ح:ر (Height to Thickness) نسبة: Keep wall height no more than 5x its thickness (على سبيل المثال, أ 1 mm thick wall should be ≤5 mm tall).
- If thin walls are required (على سبيل المثال, for a lightweight part), switch to sheet metal manufacturing instead of CNC machining—it’s cheaper and avoids vibration issues.
2. خطأ 2: Designing Features That Can’t Be Machined
CAD software lets you draw almost any shape—but CNC machines have physical limits. The most common mistake? Designingcurved holes (holes that bend or twist through the part).
لماذا هي مشكلة:
CNC tools move in straight lines (along X/Y/Z axes) or fixed rotations (A/B/C axes). They can’t follow a curved path for holes—trying to do so will either break the tool or leave an uneven, unusable hole.
مثال حقيقي:
A medical device designer added a curved hole to a stainless steel sensor housing (to route wires). The CNC mill couldn’t cut the curve, so the team had to scrap 20 النماذج الأولية. They ended up redesigning the hole as two straight holes connected by a small channel—simple for the CNC to machine.
كيفية إصلاحه:
- Avoid curved holes entirely for CNC parts. Use straight holes, or split the path into multiple straight sections.
- If you must have a curved feature (على سبيل المثال, for a custom pipe), يستخدم تصحيح التفريغ الكهربائي (EDM) بدلاً من. EDM uses electrical sparks to cut complex shapes—no straight tool paths required.
3. خطأ 3: Overusing Tolerances
التسامح (the allowed variation in part size) are important for mating parts (على سبيل المثال, a lid that fits a box). But adding tight tolerances to every surface wastes time and money.
لماذا هي مشكلة:
- التحمل الضيق (على سبيل المثال, ± 0.001 مم) require slower cutting speeds, special tools, and extra quality checks—all of which increase cost.
- Most CNC machines can’t even hit extremely tight tolerances. على سبيل المثال, a basic 3-axis mill has a maximum accuracy of ±0.01 mm—any tolerance tighter than that is impossible.
Tolerance Guidelines by Machine Type:
| نوع آلة CNC | دقة نموذجية (تسامح) | الأفضل ل |
|---|---|---|
| Basic 3-axis Mill | ± 0.01 مم | النماذج الأولية, non-mating parts |
| Advanced 5-axis Mill | ± 0.005 مم | أجزاء الفضاء, tight-fitting components |
| مخرطة CNC | ± 0.008 مم | أجزاء أسطواني (البراغي, مهاوي) |
كيفية إصلاحه:
- Only add tight tolerances to mating surfaces (على سبيل المثال, the hole where a bolt fits). Leave non-critical surfaces (على سبيل المثال, the outer edge of a bracket) with loose or no tolerances.
- Don’t assign numerical dimensions (like radius or diameter) to surfaces that don’t need precision. على سبيل المثال, a decorative notch doesn’t need a tolerance—just a general size.
4. خطأ 4: Designing Unnecessary Aesthetic Features
It’s tempting to add complex shapes (على سبيل المثال, 3D logos, الحواف المنحنية) to make parts look nice—but these features often require extra machining time and material removal.
لماذا هي مشكلة:
- Aesthetic features like deep engravings or custom curves need 5-axis machining (more expensive than 3-axis) or multiple tool changes.
- Removing extra material for looks increases scrap—for example, أ 1 kg aluminum block might become a 0.5 kg part with unnecessary cuts, wasting $10–$20 per part.
مثال حقيقي:
A consumer electronics brand added a 3D engraved logo to the back of an aluminum phone case. The logo required 2 extra tool changes and 15 minutes of machining time per case. When they switched toالصدمة الكهربائية (a post-processing step that smooths the surface) and a simple printed logo, they cut production time by 25% وحفظ $5 لكل حالة.
كيفية إصلاحه:
- بسأل: “Is this feature necessary for function?" إذا لم يكن كذلك, skip it.
- Use post-processing for aesthetics: الصدمة الكهربائية (smooths surfaces), الأنود (adds color), or laser engraving (سريع, cheap logos) are better than machining complex shapes.
5. خطأ 5: Designing Too Deep Cavities
تجاويف (hollowed-out sections) are useful for lightweight parts—but CNC tools have a limited cutting length. Too-deep cavities cause tool failure or poor quality.
لماذا هي مشكلة:
- Milling tools work best when cavities are 2–3x the tool’s diameter. على سبيل المثال, أ 15 mm tool can safely cut cavities up to 35 مم عميق (2.3x its diameter).
- Deeper cavities lead to:
- Tool deflection: The tool bends under pressure, leaving uneven walls.
- Chip buildup: Debris gets stuck in the cavity, scratching the part.
- Tool breakage: The tool protrudes too far from its holder and snaps.
مثال حقيقي:
A designer created a 50 mm deep cavity in a plastic part using a 15 mm tool (3.3x the tool’s diameter). The tool deflected, making the cavity walls 2 mm thicker on one side—rendering the part useless. They fixed it by reducing the cavity depth to 35 mm and adding a small ledge (no loss in functionality).
كيفية إصلاحه:
- Follow the tool diameter rule: Keep cavity depth ≤3x the tool’s diameter.
- لتجويف أعمق:
- Use a longer tool holder (to reach the bottom without bending).
- Cut in small increments (1–2 mm at a time) to reduce tool stress.
- Use high-pressure coolant to flush out chips.
6. خطأ 6: Designing No Radius for Internal Corners
CNC milling tools are cylindrical—they can’t cut sharp internal corners. Designing sharp edges forces the machine to use smaller tools (أبطأ, أكثر تكلفة) or leaves uneven corners.
لماذا هي مشكلة:
- A sharp internal corner requires a tool with a tiny diameter (على سبيل المثال, 1 مم) to fit into the corner. Small tools cut slowly and break easily.
- Even if you design a sharp corner, the CNC will automatically leave a small radius (equal to the tool’s radius)—so your part won’t match the CAD design.
Internal Corner Radius Guidelines:
| Cavity Depth | Minimum Recommended Corner Radius | Tool Size Needed |
|---|---|---|
| 10 مم | 3 مم (1/3 of depth) | 6 mm tool |
| 20 مم | 7 مم (1/3 of depth) | 14 mm tool |
| 30 مم | 10 مم (1/3 of depth) | 20 mm tool |
كيفية إصلاحه:
- إضافة أ corner radius to all internal corners in your CAD design. Make the radius slightly larger than the tool’s radius (على سبيل المثال, أ 6 mm tool needs a 3.5 mm corner radius).
- If you need a sharp edge (على سبيل المثال, for a part that fits into a rectangular slot), design an Undercut (درجة صغيرة) بدلاً من. Undercuts let the tool reach the corner without leaving a radius.
7. Yigu Technology’s Perspective on CNC Design Mistakes
في Yigu Technology, we’ve seen every one of these mistakes delay projects or waste money. The biggest takeaway? Design for manufacturability first. Before finalizing a CAD model, بسأل: Can a CNC machine actually cut this? Is this tolerance necessary? Small tweaks—like adding a corner radius or simplifying a curved hole—save time and avoid rework. We often work with designers early on to review plans, catching issues before they become costly problems. By aligning design with CNC capabilities, you’ll get parts that work right the first time.
8. التعليمات: Common CNC Design Questions
س 1: What’s the thinnest wall I can safely design for CNC aluminum parts?
Stick to a minimum of 0.8 mm for aluminum (6061). Thinner walls (0.6 mm or less) will vibrate and break during machining. If you need something thinner, use sheet metal instead.
Q2: Can I use EDM for all impossible-to-machine features?
EDM works for complex shapes like curved holes or sharp internal corners, but it’s slower and more expensive than CNC. Use EDM only when CNC is impossible—for most parts, simplifying the design (على سبيل المثال, straight holes) أفضل.
س 3: Do I need to add tolerances to every surface of my CNC part?
لا! Only add tight tolerances to mating surfaces (على سبيل المثال, holes for bolts). Non-critical surfaces (على سبيل المثال, the top of a bracket) can have loose tolerances or no tolerances at all—this cuts machining time and cost.