CNC加工, 公差 are the unsung heroes of part quality. They define how much a part’s actual dimensions can vary from the design blueprint—and getting them right means the difference between a part that fits perfectly (例えば。, エンジンコンポーネント) and one that’s useless (例えば。, a loose door handle). Whether you’re a designer drafting a new part or a manufacturer choosing a CNC service, understanding CNC machining tolerances helps you avoid costly reworks, 生産をスピードアップします, and ensure your parts meet functional needs. このガイドは、あなたが知る必要があるすべてを分解します: from what tolerances are to how to design them, with real-world examples and actionable tips.
What Are CNC Machining Tolerances?
基本から始めましょう: a CNC加工耐性 is the allowable range of variation for a part’s physical dimensions or properties (like temperature or stress). Think of it as a “safety net”—as long as the part’s actual size stays within this range, it will work as intended.
Tolerances have two key limits:
- Upper limit: The largest acceptable dimension (例えば。, 0.65 mm for a small pin).
- Lower limit: The smallest acceptable dimension (例えば。, 0.55 mm for the same pin).
CNC加工, tolerances have two critical meanings—don’t mix them up:
- CNC machine tolerance: The maximum precision a specific CNC machine can achieve. 例えば, a high-end CNC mill might hit ±0.0025 mm (について 1/40 the thickness of a human hair!), while a standard machine often uses ±0.02 mm (a common industry average). Machine tolerances are set by the manufacturer, and good CNC service providers will share these specs upfront.
- Design tolerance: The range a designer sets based on the part’s function. 例えば, an engine piston needs a tight tolerance (±0.01 mm) to fit snugly in a cylinder, but a door handle only needs a looser tolerance (±0.1 mm)—it doesn’t affect performance if it’s slightly bigger or smaller.
実世界の例
A car parts manufacturer once mixed up these two tolerances: They designed an engine valve with a ±0.005 mm tolerance but used a CNC machine that only achieved ±0.02 mm. 結果? 80% of the valves were too loose, causing engine leaks. They had to switch to a higher-precision machine—costing them $20,000 in reworks.
The 4 Main Types of CNC Machining Tolerances
Not all tolerances work for every part. The type you choose depends on the part’s function, フィット, and assembly needs. Below’s a breakdown of the most common types, with examples and use cases.
1. Limit Tolerances
Limit tolerances are the simplest type—they list the upper and lower limits directly. Any dimension between these two values is acceptable.
- 形式: Written as [lower limit] - [upper limit] (例えば。, 0.55–0.65 mm).
- に最適です: Parts where you need clear, straightforward guidelines (例えば。, small pins, ワッシャー).
例: A CNC-machined washer for a bike chain has a limit tolerance of 2.9–3.1 mm. If the washer’s actual diameter is 3.05 mm, it’s acceptable; if it’s 3.15 mm, it’s too big and gets rejected.
2. Unidirectional Tolerances
Unidirectional tolerances let the dimension vary in only one direction—either above or below the base size (not both).
- 形式: Written as [base size] +[upper limit]/-[lower limit] (例えば。, 1.5 mm +0.000/–0.005 mm). ここ, the dimension can only get smaller (に 1.495 mm)—it can’t be bigger than 1.5 mm.
- に最適です: Parts where one side of the dimension is critical. 例えば, a bolt hole that needs to be slightly smaller (not bigger) to grip a bolt tightly.
ケーススタディ: A furniture maker uses unidirectional tolerances for table leg holes: 10 mm +0.000/–0.03 mm. The holes can’t be bigger than 10 mm (or the legs would wobble), but they can be slightly smaller (10–0.03 = 9.97 mm)—the legs still fit snugly.
3. Bidirectional Tolerances
Bidirectional tolerances are symmetrical—they let the dimension vary equally above and below the base size.
- 形式: Written as [base size] ±[許容範囲] (例えば。, 5.0 mm±0.02 mm). This means the dimension can be 4.98 mm (5.0 –0.02) に 5.02 mm (5.0 +0.02).
- に最適です: Parts where small variations in either direction don’t affect function (例えば。, プラスチックブラケット, 装飾的な部分).
例: A custom phone case has a bidirectional tolerance of 150 mm ±0.1 mm for its length. If the case is 150.05 MMの長さ, it still fits the phone—no problem.
4. Geometric Tolerances (GD&t)
Geometric Dimensioning and Tolerancing (GD&t) is the most advanced type—it controls not just size, but also the part’s shape, position, and alignment. Unlike the other types (which focus on linear dimensions), GD&T ensures features like flatness, concentricity, and parallelism are correct.
- Key Features Controlled by GD&t:
- 平坦さ: How smooth a surface is (例えば。, a circuit board needs a flat surface to attach components).
- Concentricity: How well a hole lines up with a shaft (例えば。, a gear’s center hole must align with its teeth).
- Parallelism: How straight two surfaces are relative to each other (例えば。, a bookshelf’s shelves need to be parallel).
- に最適です: 複雑な, 高精度部品 (例えば。, 医療機器, 航空宇宙コンポーネント).
Tolerance Type Comparison Table
| Tolerance Type | Format Example | 重要な利点 | 理想的なユースケース |
| Limit Tolerance | 0.55–0.65 mm | Simple to understand | ワッシャー, small pins |
| Unidirectional Tolerance | 1.5 mm +0.000/–0.005 mm | Controls critical one-way variation | Bolt holes, エンジンバルブ |
| Bidirectional Tolerance | 5.0 mm±0.02 mm | Symmetrical flexibility | 装飾的な部分, プラスチックブラケット |
| 幾何学的耐性 (GD&t) | 平坦さ: 0.01 mm | Controls shape/position | 医療ツール, 航空宇宙コンポーネント |
5 Critical Tips for Designing CNC Machining Tolerances
Designing tolerances isn’t just about picking a number—it’s about balancing precision with cost and manufacturability. Here are the most important tips to avoid mistakes:
1. Only Tolerate Key Features
You don’t need to set tight tolerances for every part of a design—only the features that affect fit or function. 例えば:
- A laptop case’s outer edge only needs a loose tolerance (±0.2 mm)—it doesn’t affect how the laptop works.
- But the case’s hinge holes need a tight tolerance (±0.05 mm)—if they’re off, the hinge won’t align.
なぜそれが重要なのか: Tolerating non-critical features wastes time and money—machinists have to spend extra time measuring, and you’ll get more rejected parts.
2. Avoid Overly Tight Tolerances
Tight tolerances sound good, but they’re expensive. その理由は次のとおりです:
- A tolerance of ±0.005 mm requires a high-precision CNC machine (原価計算 \(100,000+), while ±0.02 mm uses a standard machine (\)50,000).
- Tight tolerances also mean more rejected parts: A ±0.005 mm tolerance might have a 15% rejection rate, vs. 5% for ±0.02 mm.
例: A startup designed a plastic toy with a ±0.01 mm tolerance (unnecessary for a toy!). They paid 3x more for machining and had to reprint 20% of the parts. Loosening the tolerance to ±0.1 mm cut costs by 60%.
3. Check Your CNC Machine’s Capacity
Your design tolerance can’t be tighter than the CNC machine’s ability. Always ask your CNC service provider:
- What’s the machine’s maximum precision? (例えば。, ±0.0025 mm for high-end mills, ±0.02 mm for standard machines)
- Can it handle your material? (Soft materials like aluminum are harder to hold tight tolerances than steel—they bend during machining.)
ヒントの場合: If you use a service like Xometry, they’ll match your design to a machine that meets your tolerance—no guesswork needed.
4. Account for Material Properties
柔らかい素材 (例えば。, アルミニウム, プラスチック) are trickier to machine to tight tolerances—they can bend, ワープ, or shrink after machining. 例えば:
- A steel part can hold a ±0.005 mm tolerance easily.
- An aluminum part of the same size might only hold ±0.01 mm—aluminum bends more during cutting.
ケーススタディ: A tool manufacturer tried to machine an aluminum wrench with a ±0.005 mm tolerance. The wrench warped after machining, making it too loose. They switched to steel (which holds tighter tolerances) 問題を修正しました.
5. Label Tolerances Clearly on Drawings
Always mark tolerances next to the applicable dimensions on your 2D/3D drawings. Vague labels (例えば。, “tight tolerance”) lead to mistakes. 例えば:
- Instead of writing “bolt hole: 厳しい耐性,” write “bolt hole: 10 mm ±0.02 mm.”
- For GD&t, use standard symbols (例えば。, a flatness symbol for surface smoothness)—machinists are trained to recognize these.
Yigu Technology’s Perspective on CNC Machining Tolerances
Yiguテクノロジーで, わかります CNC machining tolerances as the bridge between design intent and real-world functionality. あまりにも頻繁に, clients set overly tight tolerances (wasting cost) or too-loose ones (causing fit issues)—our job is to guide them to the sweet spot. We’ve helped medical device clients adjust their design tolerances from ±0.003 mm to ±0.005 mm (still meeting safety standards) そして、機械加工時間を削減します 30%. For automotive parts, we match designs to our fleet of CNC machines (from ±0.0025 mm high-precision mills to ±0.02 mm standard models) 一貫性を確保するため. Tolerances aren’t just numbers—they’re about making parts that work, 時間と予算内.
よくある質問
- Can I use a ±0.02 mm tolerance for all my CNC parts?
No—it depends on the part’s function. A ±0.02 mm tolerance works for non-critical parts (例えば。, decorative brackets) but is too loose for high-precision parts (例えば。, エンジンピストン, which need ±0.005 mm). Always base the tolerance on how the part will be used.
- Why is GD&T better than standard tolerances for complex parts?
Standard tolerances only control size, but GD&T controls shape and position—critical for complex parts. 例えば, a medical drill bit needs GD&T to ensure its tip is perfectly centered (concentricity) and its surface is smooth (flatness). Without GD&t, the drill bit might be the right size but wobble during use, causing errors.
- How do I know if my CNC service provider can meet my design tolerance?
Ask them two questions: 1) What’s the maximum precision of their machines? (例えば。, ±0.0025 mm) 2) Have they worked with similar parts/tolerances before? Reputable providers will share machine specs and even test a sample part for you. 例えば, if your design needs ±0.01 mm, make sure their machine can achieve at least that (not just ±0.02 mm).