Brass Precision CNC machining
High-performance brass CNC machining services for C360, C260, C464 – from free‑machining brass to high‑strength naval brass. We deliver tight tolerances, nickel plating, lead‑free options, and fast turnaround for electrical connectors, precision fittings, and custom turned parts.
STEP / IGES / SLDPRT / PDF accepted
- ±0.00019" tol. • Titanium • Magnesium • 5-axis CNC • ISO 9001
ISO 9001
Material traceability
CMM reporting
Revision Control
Why Brass for CNC Machined Components
Brass is chosen when you need fast, reliable machining, crisp threads, good electrical conductivity, and stable corrosion performance in everyday environments. For many fittings, connector bodies, and precision turned components, brass CNC machining services deliver an excellent balance of part quality and cost—especially when the alloy is selected to match function, compliance requirements, and finishing needs.
Exceptional Machinability
C360 brass CNC machining is a go-to choice for high-volume screw machining and tight-tolerance turned parts. Industry references list C36000 with a machinability rating of 100 (the benchmark for copper alloys), which helps reduce cycle time and improve consistency.
Conductivity + Thread Quality
Brass is widely used for brass CNC machining for electrical connectors, sensor bodies, and terminals because it combines conductivity with strong thread formation—helpful for repeated assembly and reliable torque.
Finish Flexibility
From clean as-machined surfaces to bead blasting, mirror polishing, and nickel plated brass CNC parts, brass supports a wide range of functional and cosmetic finishes. When appearance matters, planning for tarnish protection (clear coat) keeps results consistent.
Brass at a Glance (Useful Numbers)
These reference values help early selection and DFM. Exact properties vary by alloy and temper; we confirm with material certifications when required.
- C36000 (free-cutting brass): machinability rating 100 (benchmark for copper alloys).
- C26000 (cartridge brass): machinability rating 30; often chosen for better cold-formability and drawing.
- C46400 (naval brass): ~1% tin improves resistance to dezincification in seawater environments.
- Typical best-fit parts: fittings, valve stems, manifolds, terminals, threaded inserts, decorative hardware.
Data points above are consistent with industry alloy references (e.g., Copper Development Association / Copper.org; Austral Wright Metals for C464).
Brass Alloys We Machine
In custom brass CNC machined parts, alloy choice determines machinability, corrosion behavior, compliance (lead-free/low-lead), and the finishing route. Start with your end-use: plumbing, electrical, marine, or decorative hardware—then we map the right alloy and process so you get consistent dimensions at competitive cost.
| Best For | Speed / Cost | Machining Notes | Typical Parts |
|---|---|---|---|
| High-volume precision turned parts | Fast cycle time; great cost control | Free-machining behavior supports clean threads and smooth finish; ideal for screw-machine work | Fittings, valve stems, threaded inserts, sensor bodies, connector shells |
| Best For | Formability | Machining Notes | Typical Parts |
|---|---|---|---|
| Parts that may require forming / drawing behavior | Excellent cold workability; deep drawing friendly | Machines slower than C360; use when forming/cold-work performance matters more than pure cycle time | Electrical shells, hardware, brackets, stamped + machined hybrids |
| Best For | Corrosion Environment | Machining Notes | Typical Parts |
|---|---|---|---|
| Marine hardware and seawater-facing components | Tin helps resist dezincification in seawater | Choose for marine corrosion risk; plan sealing surfaces and threads for reliable assembly | Marine fittings, valve stems, condenser plates, baffle plates, pressure components |
| Best For | Material Form | Machining Notes | Typical Parts |
|---|---|---|---|
| Machined parts from extruded shapes | Often supplied as architectural/extrusion profiles | Good machinability for milled features; great when you want profile + secondary CNC work | Decorative hardware, brackets, trims, milled profiles |
Alloy Selection Snapshot
Pick the brass grade by the real constraint: cycle time (C360), formability (C260), seawater corrosion risk (C464), or profile-based machining (C385).
Machinability = Cost Control
Free-machining brass tends to produce short chips and stable finishes—reducing cycle time, tool wear, and deburring effort for precision brass machining.
Finish Options
From as-machined to bead blast, polishing, nickel plating, and clear coat—choose the finish that matches corrosion, cosmetics, and dimensional needs.
C360 vs Lead-Free vs Naval Brass (Quick Rule)
If your priority is fast cycle time and crisp threads, start with C360. If your application requires lead-free/low-lead brass, confirm the compliance requirement early so we can choose a suitable alloy and plan machining accordingly. If your part sees seawater or you’re concerned about dezincification, consider C464 (naval brass) and validate corrosion + sealing strategy.
- C360: free-machining, high-volume fittings, inserts, connector bodies
- Lead-free/low-lead brass: compliance-driven plumbing/consumer applications (specify requirement)
- C464: marine hardware; better dezincification resistance in seawater
- C260: forming/drawing friendly when cold-work behavior matters
Our Capabilities for Brass CNC Machining
We support brass CNC milling and turning for prototypes and production. Our process planning focuses on crisp threads, predictable sealing faces, and burr control—so you receive precision brass components that assemble cleanly and stay cost-competitive.
High-Volume Turning
Perfect for custom brass CNC turned parts like fittings, sensor bodies, and inserts—optimized for short cycle time and stable diameters.
3/4/5-Axis Milling
Manifolds, blocks, and multi-face datums—clean edges and controlled surface finish for sealing and assembly interfaces.
Secondary Ops
Deburr/edge break, polishing, nickel plating coordination, clear coat (anti-tarnish), and assemblies—built around your functional surfaces.
DFM Guide: Threads, Burr Control, and Cost in Brass
Brass is forgiving, but the highest ROI comes from designing for fast threading, predictable sealing faces, and minimal hand-deburr. Align tolerances and finishes to function to keep brass CNC machining cost-competitive.
| Design Item | Recommendation | Why It Matters |
|---|---|---|
| Threads + thread relief | Add thread relief where possible; standardize thread series; avoid overly deep blind taps | Reduces tap risk, improves thread quality, and stabilizes cycle time. |
| Sealing faces / O-ring grooves | Call out the sealing face and groove dimensions as critical; protect them from over-deburr | Sealing performance is usually the real functional risk; measure and protect those surfaces. |
| Burr control | Specify “break sharp edges” vs controlled chamfer; avoid micro-features that require handwork | Over-deburr can damage threads and sealing edges; clear requirements reduce variability. |
| Thin walls near threads | Keep adequate wall thickness around tapped ports; add ribs if needed | Prevents cracking or deformation during assembly torque. |
| Plating-aware design | If nickel plating is required, identify functional fits and mask/allowance as needed | Plating adds thickness; planning prevents fit issues and rework. |
Cost Lever 1: Standardize Threads
Standard threads and tool sizes reduce tool changes and scrap risk—key for high-volume brass CNC turned parts.
Cost Lever 2: Control Burr at the Source
Geometry choices that avoid fragile edges cut handwork. Clear edge-break callouts prevent over-deburr on sealing faces.
Cost Lever 3: Finish Only What Matters
Polish/plating can dominate cost. Define cosmetic faces vs functional faces so you don’t pay for unnecessary finishing.
Surface Finishes for Brass CNC Parts
Brass finishes affect appearance, corrosion behavior, and long-term tarnish. Choose a finish that matches the real requirement—conductivity, cosmetics, cleaning, or corrosion exposure—then design around any dimensional impact from plating/coatings.
| Finish | What It Does | Best For | Notes |
|---|---|---|---|
| As-machined (Ra target) | Controlled toolpath texture | Functional parts, internal features, crisp threads | Great default for cost; define cosmetic faces if you need polish. |
| Bead blasted (matte) | Uniform low-glare texture | Decorative hardware, visible housings | Can soften sharp edges slightly; plan around sealing edges. |
| Polished | Mirror-like reflective surface | Consumer-visible brass parts | Higher cost; specify which faces require polish to keep pricing competitive. |
| Nickel plated | Bright corrosion-resistant plated layer | Wear + cosmetics, tarnish control, premium appearance | Plating adds thickness; mask/allowance on tight fits and threads. |
| Clear coat / lacquer | Slows tarnish while preserving brass color | Decorative parts and hardware | Best for cosmetics; confirm temperature/chemical exposure compatibility. |
Quality Documents for Brass Parts
For brass components used in fittings, connectors, and regulated assemblies, documentation is part of performance. We can align inspection and material evidence to your drawing and supplier quality plan.
Material Traceability
Alloy confirmation and material certifications when required (e.g., specifying C360/C260/C464 or lead-free requirements).
Inspection Evidence
FAI packages, dimensional reports, and CMM/fixture-based measurement tied to critical datums and threads/sealing faces.
Finish Certifications
Plating/coating documentation from approved processors when requested (e.g., nickel plating) with lot tracking.
Case Study: Brass Program for Connectors + Fittings + Manifolds
A customer needed a family of brass CNC machined parts spanning electrical connector bodies (C360), plumbing fittings (compliance-driven brass), and a multi-port manifold. The key was aligning alloy and finish to function—then controlling cost with thread standardization, burr control, and plating-aware tolerancing.
| Program Goal | Constraint | Batnon Approach | Outcome |
|---|---|---|---|
| Best part performance at competitive pricing | Tight threads + sealing faces + cosmetic requirements | Alloy-by-function mapping, thread standardization, burr control plan, plating-aware tolerances, risk-based inspection | Stable assembly torque, consistent cosmetics, predictable lead time and cost |
Electrical Connector Body
Free-machining brass supported clean threads and consistent surface finish for high-volume assembly.
Plumbing Fitting
Thread form and sealing faces were controlled. Deburr intent was defined to protect functional edges.
Multi-Port Manifold
Datum strategy and tool access were tuned to keep ports concentric and sealing faces repeatable.
Nickel Plated Brass Component
Plating thickness was planned around threads and fits to maintain tight tolerance brass machining performance.
What Made It Work (Transferable Lessons)
Brass is one of the best materials for cost-effective precision machining—when the alloy and finish are chosen with intent. Competitive pricing came from engineering choices: using C360 where allowed, applying tight tolerances only to threads/sealing faces, and treating plating as a dimensional feature (not an afterthought).
- Thread standardization: fewer tools, faster cycle time, lower scrap risk
- Burr control plan: protects sealing faces and assembly torque consistency
- Plating-aware tolerances: prevents fit problems after nickel plating
- Risk-based inspection: measure the features that gate leaks, torque, and conductivity
FAQ: Brass CNC Machining
Common questions about brass alloy selection (C360 vs C260 vs C464), lead-free requirements, plating, corrosion risks, and cost control.
Which brass is best for CNC machining—C360 or C260?
C360 is the default for high-speed screw machining and precision turned components because it machines quickly and produces excellent threads and surfaces. Choose C260 when cold-formability or deep drawing behavior matters more than pure machining speed.
Do you offer lead-free / low-lead brass machining services?
Yes. Share your compliance requirement and target standard, and we’ll recommend an appropriate alloy and process plan. Lead-free brasses can machine differently than C360, so early DFM helps keep cost and lead time predictable.
What is dezincification and when should I worry about it?
Dezincification is a corrosion mechanism where zinc can leach from brass in certain waters. For seawater exposure or aggressive environments, alloy selection (e.g., naval brass C464) and proper finishing can reduce risk.
Will nickel plating change dimensions on tight-tolerance brass parts?
Yes. Plating adds thickness. For tight fits, threads, and sealing faces, we plan masking or machining allowances so your functional dimensions remain in spec after plating.
What finishes are common for brass CNC machined parts?
As-machined, bead blasted matte, polished, nickel plated, and clear coat for anti-tarnish are common. The right choice depends on cosmetics, corrosion exposure, conductivity needs, and dimensional requirements.
Can brass CNC parts be used for electrical connectors?
Yes. Brass is widely used for connector bodies and terminals because it combines good conductivity, stable threads, and excellent machinability—ideal for repeatable assembly.
How do you keep brass CNC machining services cost-competitive?
We keep costs down by using the right alloy (often C360), reducing setups, standardizing threads/tooling, applying tight tolerances only where they gate function, and limiting polish/plating to the surfaces that truly need it.
Brass CNC Machining (Global Supply, Local Expectations)
Batnon supports brass CNC machining services for engineering teams across North America, Europe, and Asia—shipping prototypes and production parts worldwide. If you’re searching for C360 brass CNC machining, free machining brass CNC parts, custom brass CNC turned parts, brass machining for electrical connectors, precision brass machining for fittings, or nickel plated brass CNC parts, our quoting workflow is designed for fast engineering alignment: alloy selection, finish planning, tolerance review, and QA documentation.
- Typical applications: fittings, valve stems, manifolds, connector bodies, threaded inserts, decorative hardware
- Industries served: electrical & electronics, plumbing & fluid control, industrial automation, marine hardware, consumer products
- Common alloys: C360 (free-machining), C260 (cartridge), C464 (naval brass), C385
- Finish options: as-machined Ra targets, bead blast, polish, nickel plating, clear coat anti-tarnish
- Engineering handoff: DFM for cycle time, thread/sealing strategy, plating-aware tolerances, inspection plan, material/finish documentation
Tip for fast quoting: include your target alloy/spec (and any lead-free requirement), thread standard, sealing method (O-ring/NPT/flat), finish, and critical datums.
Complete CNC Machining Materials Guide
Explore our comprehensive range of materials. From lightweight aluminum to high-performance plastics, find the perfect material for your precision machining project. All materials are machined in‑house with tight tolerances, inspection reports, and full traceability.
Metals & Alloys
High strength · Excellent machinability · DurableEngineering & High‑Performance Plastics
Lightweight · Wear resistant · High temperature stabilityMaterial Selection Guide
Need help choosing the right material? Compare strength, cost, machinability, and finishing options for your application.
Browse All Materials →Surface Finishes & Post‑Processing
From anodizing to passivation, bead blasting to electropolishing – see which finish matches your performance requirements.
Explore Finishes →Precision CNC Capabilities
3‑axis, 4‑axis, 5‑axis milling, Swiss turning, tight tolerances down to ±0.005mm, CMM inspection, and fast lead times.
View CNC Services →RFQ Readiness Checklist
| • 3D Model – STEP (.stp), IGES (.igs), or SolidWorks (.sldprt) |
| • 2D Drawing (PDF) – Critical dimensions, tolerances, GD&T, surface finish |
| • Material Specification – Exact alloy (e.g., 6061-T6 vs 7075) |
| • Finish Requirements – Anodize (Type II/III), Bead Blast, As-Machined, etc. |
| • Special Processes – Heat treatment, plating, passivation, welding, or secondary operations |
| • Inspection Level – CoC, Standard Report, CMM, or FAI |
| • Quantity – Prototype (1–10) or production (100–10k+) |
| • Special Instructions – Edge breaks, thread class, cosmetic zones, packaging needs |
| • Target Lead Time – Standard or expedited (rush orders) |
| • DFM Feedback Request – Request for design optimization or cost reduction |
Please provide all core information when submitting your RFQ to receive an accurate, fast quote.
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STEP / IGES / SLDPRT / PDF accepted