aerospace component

What is Surface Finish in Machining?   At its core, surface finish in machining refers to the small-scale irregularities left on the surface of a part after machining. These irregularities are typically grouped into three categories: Roughness: The fine, closely spaced deviations caused by the cutting process itself. Roughness depends heavily on feed rate, tool sharpness, and cutting speed. Waviness: Larger, more widely spaced variations caused by machine tool vibration, deflection, or thermal distortion. Lay: The direction of the surface pattern, determined by the machining method (e.g., turning leaves circular lay patterns, grinding leaves linear marks). Now picture two extremes: A shaft with poor surface finish that wears down bearings, causes noise, and shortens lifespan. A precision aerospace part with a carefully controlled finish that seals tightly, reduces drag, and performs reliably under stress. That balance between production speed and finish quality is where experience counts. We see this every day when machining parts for clients across industries. The right finish can make the difference between a part that passes inspection and one that ends up in the scrap bin. At Keso, our advanced machining setups and strict process control mean we don't have to choose between efficiency and precision, we get both.       Surface Finish Types and Scales     Not every part needs a mirror-like surface. That's why machinists talk about surface finish types, each suited to a different application: Rough machining finish: Produced by fast cutting, typically acceptable for internal features or non-critical surfaces. Fine machining finish: Achieved with optimized cutting parameters, often used where moderate precision is needed. Ground finish: Obtained with grinding operations, providing tighter tolerances and better smoothness. Polished/mirror finish: Achieved through lapping or polishing, critical for medical implants, optics, or sealing components.     Surface Finish Scales   To measure and compare these finishes, engineers use scales such as: Ra (Roughness Average): The most common measure, representing average roughness in micrometers (µm) or microinches (µin). Rz: Average difference between the highest peak and lowest valley across several samples. RMS (Root Mean Square): Another mathematical way to express roughness, slightly different from Ra but often used in older specifications.   At Keso, we don't just calculate Ra and Rz on paper, we validate them with in-house testing equipment and back it up with real finishing options like bead blasting, anodizing, brushing, and mirror polishing, ensuring that clients get both the numbers and the surface quality their application demands. In machining, these measurements are often tied to a surface finish scale for machining (sometimes shown as N-numbers, like N1 = super fine, N12 = rough). For example: An N7 finish (~0.8 µm Ra) is common on sealing surfaces. An N12 finish (~50 µm Ra) is typical for rough milling where accuracy isn't critical.   Having a standardized surface finish scale for machining allows machinists, engineers, and purchasing managers to “speak the same language” when defining part requirements. And when tolerances come into play, that's where our team's experience across both machining and finishing services ensures the final part performs as intended.       Surface Finish Charts & Real Applications   Surface finish is more than a cosmetic choice, in CNC machining, it determines friction, wear resistance, sealing capability, and even how a component interacts with coatings or mating parts. Understanding finish charts, measurement units, and real-world testing methods ensures your parts meet both functional and aesthetic needs. We advise clients on which surface finishes will give them the best balance of function, durability, and cost. Because sometimes a mirror-polished aerospace component makes sense, and sometimes a basic milled finish is all you need. That's the kind of guidance we bring to every project we handle.       Surface Finish Conversion Chart   Different industries use different metrics for surface roughness. In machining, the most common ones are Ra (average roughness), Rz (mean peak-to-valley height), and N values (grade numbers, mostly ISO-based). Here's a conversion table our engineers actually use: Roughness Grade (N) Ra (µm) Ra (µin) Typical Process Example N1 0.025 1 Superfinishing / Lapping N2 0.05 2 Lapping / Honing N3 0.1 4 Fine Grinding N4 0.2 8 Grinding / Polishing N5 0.4 16 Fine Milling / Turning N6 0.8 32 Standard Milling / Turning N7 1.6 63 General CNC Machining N8 3.2 125 Rough Milling N9 6.3 250 Rough Turning N10 12.5 500 Heavy Cuts, Cast Surfaces   Surface Finish for Stainless Steel     Stainless steel often demands tighter surface finish controls than softer metals, especially in industries like food processing, aerospace, and medical devices. When we machine stainless steel shafts for clients in the food industry, a smooth finish isn't cosmetic, it prevents bacterial build-up and ensures compliance. These are the details we obsess over at JLCCNC.   2B Finish (~Ra 0.3–0.5 µm, close to N5/N6) – The most common mill finish for stainless steel sheets. Smooth, reflective, but not mirror-like. Often used in industrial and food applications. #3 Finish (~Ra 0.8–1.2 µm, around N7) – A coarse, directional polish with visible grit lines. Typically used for kitchen equipment and decorative surfaces. #4 Finish (~Ra 0.4–0.8 µm, N5–N6) – The most popular brushed finish for stainless steel. Clean, consistent, and easy to maintain. Widely used in appliances, elevators, and architectural panels. #8 Mirror Finish (Ra 0.2 µm or below, N4–N2) – A highly reflective, mirror-like surface achieved through successive polishing stages. Common for decorative, medical, and optical components.   Pro tip: Stainless work-hardens. Using sharper tooling, proper coolant, and avoiding rubbing passes helps maintain surface quality.   We've also found that balancing feed rates with the right tool coating makes all the difference. One client in the medical sector came to us with rough implant prototypes, after optimizing parameters, we delivered surfaces smooth enough to pass surgical inspection standards. A rough finish might mean extra friction, faster wear, and sometimes parts not even fitting right. And honestly, this is where a good CNC shop makes all the difference, anyone can cut, but not everyone can deliver that clean, consistent finish that saves you rework and cost later.