Our CNC Mill-Turning Services

Transform your complex part production with our CNC Mill-Turning services—the ultimate multi-tasking machining solution that combines milling and turning in one setup. Using advanced mill-turning centers, we craft high-precision components (tolerances down to ±0.001mm) from metals, compuestos, and exotic materials—eliminating repositioning errors, cutting lead times, and delivering consistent results for aerospace, médico, and automotive industries. Whether you need cylindrical parts with intricate milled features or custom components requiring both turning and milling, our single-setup approach boosts efficiency without compromising quality.

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What Is CNC Mill-Turning?

Torneado de fresado CNC—also called multi-tasking machining—is an advanced manufacturing tecnología that integrates both turning and milling operations into a single mill-turning center. Unlike traditional machining (which requires separate lathes for turning and mills for milling, plus manual part repositioning), it lets you complete complex parts in one setup—reducing errors, saving time, y mejorar la consistencia.

El descripción general del proceso revolves around a hybrid machine: A mill-turning center combines a rotating spindle (for turning cylindrical features) with multi-axis tool turrets (for milling flat surfaces, drilling holes, or adding slots). The part is held in a chuck or collet, rotated by the spindle (torneado), while tools move along linear (incógnita, Y, z) and rotational (A, C) axes to add milled features—all under CNC control.

To explain “how it works” simply: Imagine a machine that can first turn a metal bar into a shaft (cylindrical turning), then immediately mill a slot on its side, drill cross-holes, and add threads—all without moving the part to another machine. Por ejemplo, a medical bone screw (which needs a turned cylindrical body, milled flat drive, and threaded end) can be fully machined in one run. This seamless combination of turning and milling is what makes Torneado de fresado CNC ideal for parts with both rotational and prismatic features.

Our CNC Mill-Turning Capabilities

We offer comprehensive mill-turning capabilities tailored to complex part requirements, con un enfoque en niveles de precisión, tolerance achievements, and multi-tasking flexibility. Below is a detailed breakdown of our key capacities:

Capacidad	Especificación
Machine Configuration	– Spindle: 2-axis turning (C-axis for rotation, Z-axis for linear movement)- Tool Turret: 5-axis milling (incógnita, Y, z + A/B-axis for angular positioning)- Herramientas en vivo: Drills, taps, fresas finales (for in-line milling/drilling)
Precision Levels	– Torneado: ±0,001 mm (diámetro), ±0,002 mm (longitud)- Milling: ±0.0015mm (positioning), ±0,001 mm (repeatability)- Rugosidad de la superficie (Real academia de bellas artes): 0.02μm–0.8μm
Tolerance Achievements	– Estándar: ±0.003mm (rieles), ±0,005 mm (non-metals)- Critical Parts: ±0,001 mm (p.ej., aerospace sensors, implantes medicos)- Cumple con ISO 2768-1 (extra-fine grade) and ASME Y14.5
Maximum Part Size	– Diameter: 0.5mm–150mm (piezas cilíndricas)- Longitud: Up to 800mm (length-to-diameter ratio up to 15:1)- Weight: Up to 300kg
Espesor del material	– Rieles: 0.5mm–100mm (acero inoxidable), 0.5mm–120mm (aluminio), 0.5mm–80mm (titanio)- Non-Metals: 1mm–80mm (plástica), 1mm–60mm (compuestos), 1mm–50mm (acrílico)- Special Materials: 0.5mm–50mm (exotic metals like inconel), 1mm–60mm (polímeros de alto rendimiento)
Mecanizado personalizado	– Features: Turned diameters, milled slots/pockets, cross-holes (0.3mm de diámetro), trapos (0.2mm pitch), socavados- Compatibility: CAD/CAM files (DXF, DWG, PASO, STL, IGES)- Volume: Prototipos (1–50 unidades) to high-volume (200,000+ unidades/mes)
Opciones de herramientas	– Turning Tools: Carbide inserts (for metals), diamond tools (for plastics)- Milling Tools: End mills (0.1mm–20mm diameter), ejercicios, taps, reamers- Tool Changers: Automatizado (arriba a 48 herramientas) for high-volume runs
Mecanizado de alta velocidad	– Spindle Speed: Arriba a 12,000 RPM (torneado), 20,000 RPM (molienda)- Feed Rate: Up to 1,000mm/min (lineal), 500°/min (rotational)
Seguro de calidad	– In-line Inspection: Laser micrometers, touch probes (for real-time dimension checks)- Post-mecanizado: CMM (Máquinas de medición de coordenadas), comparadores ópticos- Compliance: ISO 9001, AS9100 (aeroespacial), ISO 13485 (médico)

Si necesitas 100 titanium aerospace shafts (with milled keyways) o 50,000 brass electronics connectors (with turned bodies and milled slots), our mill-turning capabilities scale to match your project’s complexity.

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The CNC Mill-Turning Process (Paso a paso)

Nuestro proceso paso a paso is optimized to leverage the multi-tasking power of mill-turning centers, ensuring efficiency and precision from design to finish:

Design and CAD Modeling: We start by reviewing your CAD model (or creating one from sketches) to identify all features—turned diameters, milled slots, agujeros, etc.. Our engineers optimize the design for mill-turning—e.g., ensuring milled features are accessible without spindle interference and turning diameters are compatible with chuck size. Para piezas complejas, we use 3D simulation to test tool paths.

CAM Programming: The CAD model is imported into CAM software (Mastercam Mill-Turn, GibbsCAM) to generate integrated tool paths for both turning and milling. We sequence operations logically: first turning (to create the cylindrical base), then milling/drilling (to add prismatic features), and finally finishing (polishing/threading). We also program C-axis rotation (for angular milling) and live tooling activation.

Setup and Calibration: The raw material (bar stock or blank) is loaded into the machine’s chuck/collet. We calibrate the spindle (for turning speed) and tool turret (for milling accuracy) using laser measuring tools. Cutting tools are loaded into the turret, y coolant systems are activated—directed to both turning and milling zones. A test part is run to verify tolerances and tool alignment.

Turning Execution: The spindle rotates the part, and turning tools move along the Z (longitud) and X (diámetro) axes to shape cylindrical features—OD (outer diameter), ID (inner diameter), cirios, or chamfers. For long parts, a tailstock provides additional support to prevent deflection.

Milling Execution: After turning, the spindle stops rotating (or indexes to a fixed angle via C-axis), and the tool turret moves along X/Y/Z (and A/B if needed) to mill flat surfaces, tragamonedas, pockets, or drill holes. Live tooling (rotating tools in the turret) enables drilling and tapping without repositioning.

Post-Machining Inspection: Parts undergo rigorous control de calidad—we measure turning dimensions (diameter/length) with micrometers, milling features (slot depth/hole position) with CMMs, and check surface finish with profilometers. Parts requiring finishing move to desbarbado o pulido.

Materials We Work With

Torneado de fresado CNC excels with a wide range of materials, though tool selection and parameters vary based on material hardness and machinability. Below is a breakdown of our supported materials, key properties, and ideal uses:

Categoría de materiales	Ejemplos	Propiedades clave	Machinability Notes	Aplicaciones ideales
Rieles	Acero inoxidable	Resistente a la corrosión, fuerte, moderate machinability	Use carbide turning inserts; high-pressure coolant for milling	Sujetadores aeroespaciales, herramientas medicas
	Aluminio	Ligero, soft, excellent machinability	High spindle speeds (10,000–15,000 RPM); minimal tool wear	Piezas automotrices, cajas de electrónica
	Titanio	High strength-to-weight, duro, low machinability	Slow speeds (2,000–4,000 RPM); sharp carbide tools	Implantes ortopédicos, turbine blades
	Latón	Maleable, conductivo, excellent machinability	Fast turning speeds; smooth finishes without coolant	Conectores electricos, piezas decorativas
	Cobre	Highly conductive, soft, moderate machinability	Use coolant to avoid melting; sharp tools for milling	Intercambiadores de calor, wiring terminals
Non-Metals	Plástica (ABS/Polycarbonate)	Ligero, durable, low melting point	Low speeds (3,000–5,000 RPM); mist coolant to prevent warping	Consumer goods casings, prototipos
	compuestos	Alta resistencia, ligero, abrasive	Use diamond-coated tools; low feed rates for milling	Racing car parts, aerospace panels
	Madera	Natural, soft, prone to splintering	Sharp HSS tools; low pressure to avoid splitting	Custom fixtures, componentes decorativos
	Acrílico	Transparente, rígido, brittle	Slow feed rates; sharp tools to prevent cracking	Vitrinas, componentes ópticos
Special Materials	Metales exóticos (Inconel)	A prueba de calor, duro, low machinability	Ceramic tools; high-temperature coolant	Piezas de motores aeroespaciales, chemical equipment
	Polímeros de alto rendimiento (OJEADA)	A prueba de calor, resistente a químicos	High-speed steel tools; air cooling	Medical device casings, sellos industriales

We test all materials to optimize spindle speeds, feed rates, and tool selection—ensuring consistent precision across every part.

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Tratamiento superficial & Opciones de acabado

After mill-turning, ofrecemos una gama de tratamiento superficial y finishing options to enhance part durability, funcionalidad, y estética. Our most popular services include:

Finishing Option	Descripción del proceso	Beneficios clave	Compatibilidad de materiales	Costo (por parte, avg.)	Mejor para
Molienda	Uses abrasive wheels to smooth turned/milled surfaces	Tightens tolerances (±0,001 mm); removes tool marks	Rieles, ceramics	10–40	Engine shafts, bearing surfaces
Pulido	Uses buffing wheels + compounds to create glossy finishes	Mejora la estética; reduce la fricción	Acero inoxidable, latón, aluminio	8–35	Medical tools, bienes de consumo
Cuadro	Applies corrosion-resistant paint (matte/gloss) via spray or dip	Protects against rust; custom colors	Rieles, plasticos	5–25	Outdoor automotive/industrial parts
Revestimiento	Recubrimiento en polvo (thick, resistente a los arañazos) or PVD coating (delgado, resistente al desgaste)	Durabilidad; heat/corrosion resistance	Rieles, compuestos	15–50	Heavy-duty machinery parts
Anodizado	Adds protective oxide layer to aluminum (dyed or clear)	Resistencia a la corrosión; decorative finish	Aluminio	10–30	Cajas electrónicas, piezas aeroespaciales
Tratamiento térmico	Heats/cools metals to strengthen (hardening) or reduce brittleness (tempering)	Improves fatigue resistance; increases hardness	Acero, titanio, inconel	20–60	Estampación, high-stress components
Desbarbado	Removes sharp edges (via tumbling, brushing, or manual tools)	Improves safety; prevents assembly issues	All materials	3–15	Dispositivos médicos, electronics pins
galvanoplastia	Coats parts with metal (oro, plata, níquel) via electrolysis	Enhances conductivity; resistencia a la corrosión	Latón, cobre, acero	10–45	Conectores electricos, joyería

Por ejemplo, we use anodizing for aluminum automotive trim (to resist scratches) and electroplating for brass electronics connectors (to improve conductivity).

Tolerancias & Seguro de calidad

Tolerancias for CNC Mill-Turning focus on both turning (diameter/length) and milling (feature position/size) precision—critical for parts where fitment depends on multiple features. Nuestro quality control processes ensure strict adherence to standards:

Materiales	Turning Tolerance (Diameter)	Milling Tolerance (Position)	Rugosidad de la superficie (Real academia de bellas artes)	Accuracy Standard Used	Técnica de medición
Acero inoxidable	±0.001–0.003mm	±0.0015–0.003mm	0.02–0.2μm	ISO 2768-1 (extra-fine), ASME Y14.5	MMC + Laser Micrometer
Aluminio	±0.002–0.005mm	±0.002–0.005mm	0.05–0.4μm	ISO 2768-1 (bien), AMS 2750	MMC + Digital Calipers
Titanio	±0.0015–0.004mm	±0.002–0.004mm	0.03–0.3μm	ISO 2768-1 (extra-fine), AMS 4928	MMC + Comparador óptico
ABS Plastic	±0.005–0.01mm	±0.005–0.01mm	0.2–0.8μm	ISO 2768-1 (medium), ASTM D638	MMC + micrómetro
Inconel (Exotic)	±0.002–0.004mm	±0.002–0.004mm	0.1–0.4μm	ISO 2768-1 (extra-fine), AS9100	MMC + X-Ray Fluorescence

Nuestro quality control processes incluir:

Pre-machining: Inspecting raw materials for defects (p.ej., cracks in titanium, unevenness in composites) and verifying dimensions.

En proceso: Real-time monitoring of spindle speed, tasa de avance, and tool wear via CNC software; touch probe checks (for critical features like hole position).

Post-mecanizado: 100% inspección de piezas críticas (medical/aerospace); statistical sampling (5–10%) para pedidos de gran volumen. We also document every step (machining parameters, inspection results) for compliance.

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Key Advantages of CNC Mill-Turning

Compared to traditional separate turning/milling or single-process machining, Torneado de fresado CNC offers transformative benefits:

Mecanizado de configuración única: Completes all operations (torneado, molienda, perforación, enhebrar) in one setup—eliminating part repositioning errors (common in traditional machining) and reducing tolerance stack-up.

Alta precisión: Achieves tolerances as tight as ±0.001mm—critical for parts like medical implants (where fit directly impacts patient safety) or aerospace sensors (where precision affects performance).

Consistency and Repeatability: CNC programming ensures every part is identical—even for high-volume orders (p.ej., 200,000 brass connectors). No variation from manual repositioning.

Geometrías complejas: Handles parts with both rotational (turned) and prismatic (milled) features—e.g., a shaft with milled slots, a screw with a hex drive, or a valve with cross-holes.
Tiempo de configuración reducido: One setup instead of 2–3 (mecanizado tradicional) cuts setup time by 60–80%—speeding up production for prototypes and high-volume runs.

Increased Efficiency: High-speed machining (arriba a 20,000 RPM for milling) and automated tool changers reduce per-part cycle time by 30–50% compared to traditional methods. Por ejemplo, a brass connector that takes 5 minutes to make with separate turning/milling takes just 2 minutes with CNC mill-turning.

Versatilidad: Handles almost all materials (rieles, non-metals, exotics) and part types—from tiny medical screws (0.5mm de diámetro) to large aerospace shafts (150mm de diámetro). It also supports low-volume prototypes and high-volume production (200,000+ unidades/mes).

Rentabilidad: While mill-turning centers have higher upfront costs, reduced labor (one operator runs 2–3 machines), fewer setups, and lower scrap rates (due to fewer errors) cut long-term costs by 25–40%.

Tolerancias estrictas: The single-setup approach eliminates tolerance stack-up (errors from repositioning), enabling tighter tolerances (±0,001 mm) than traditional machining (which often struggles with ±0.005mm for multi-feature parts).

High-Quality Surface Finish: Integrated finishing operations (p.ej., pulido, enhebrar) in one setup reduce tool marks and improve surface roughness (Ra down to 0.02μm)—eliminating the need for secondary finishing in many cases.

Aplicaciones industriales

Torneado de fresado CNC is indispensable across industries that require complex, high-precision parts with both rotational and prismatic features. Here are its most common applications:

Industria	Usos comunes	Key Benefit of CNC Mill-Turning
Aeroespacial	Turbine shafts (titanio), fuel injector nozzles (acero inoxidable), carcasas de sensores (aluminio)	Single-setup precision for safety-critical parts
Automotor	Transmission gears (acero), componentes de suspensión (aluminio), fuel system valves (latón)	High-volume consistency + fast cycle times
Dispositivos médicos	Orthopedic screws (titanio), surgical tool shafts (acero inoxidable), catheter connectors (OJEADA)	Tolerancias estrictas + biocompatible material compatibility
Manufactura Industrial	Hydraulic cylinder rods (acero), pump shafts (latón), conveyor system components (aluminio)	Durable parts with complex features
Electrónica	Pines del conector (latón), heat sink shafts (aluminio), micro-switch components (plástico)	Pequeño, precise parts with mixed turning/milling features
Defensa	Weapon sight components (aluminio), vehicle armor fasteners (acero), communication device shafts (titanio)	Reliability in harsh environments + tolerancias estrictas
Tool and Die Making	Mold cores (acero), stamping die shafts (carburo), custom cutting tool holders (acero)	Geometrías complejas + long tool life
Creación de prototipos	Rapid prototypes of new products (plastics/aluminum)	Fast turnaround for design validation
Bienes de consumo	Watch components (brass/steel), eyeglass hinge pins (titanio), cosmetic packaging parts (plástico)	Estética + precision fit
Energía	Wind turbine gear shafts (acero), solar panel mounting bolts (aluminio), battery connector pins (cobre)	Durability for outdoor/heavy use

Por ejemplo, in the energy industry, our CNC-mill-turned wind turbine gear shafts (acero, ±0.002mm tolerance) reduce friction and extend turbine life by 20% compared to traditionally machined shafts. In medical devices, our titanium orthopedic screws (with milled drive slots and turned threads) ensure a perfect fit for patients—reducing surgical complications.

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Advanced Manufacturing Techniques in CNC Mill-Turning

To maximize the performance of CNC mill-turning, we leverage specialized machining techniques and optimized processes tailored to complex parts:

9.1 Core Mill-Turning Techniques

Live Tooling Machining:

The cornerstone of CNC mill-turning—live tooling (rotating tools in the turret) enables milling, perforación, and tapping while the part is held in the chuck. Por ejemplo, after turning a shaft’s outer diameter, we use a live drill to add cross-holes and a live tap to create threads—all without repositioning. Usamos:

Radial Live Tools: For features perpendicular to the part’s axis (p.ej., cross-holes, tragamonedas).

Axial Live Tools: For features parallel to the part’s axis (p.ej., end-face holes, trapos).

C-Axis Indexing/Rotation:

The C-axis (rotational axis of the spindle) lets us position the part at precise angles (indexing) or rotate it continuously (for circular milling). Por ejemplo:

Indexing: Rotating the part 90° to mill a slot on its side, then 180° for another slot—ensuring perfect symmetry.

Continuous Rotation: Rotating the part while milling to create helical features (p.ej., spiral grooves on a turbine shaft).

Y-Axis Machining:

The Y-axis (linear axis perpendicular to both X and Z) enables off-center milling—critical for parts with features not aligned to the spindle axis (p.ej., an eccentric slot on a camshaft). It eliminates the need for specialized fixtures to offset the part.

Bar Feeding & Unattended Operation:

Para producción de gran volumen (p.ej., 200,000 brass connectors), usamos automatic bar feeders (3–6 meter capacity) to load raw material into the machine. This enables unattended operation for 8–12 hours, reducing labor costs and increasing efficiency.

9.2 Supporting Technologies

Optimización de la ruta de la herramienta:

CAM software generates integrated tool paths that minimize tool travel and prioritize operations by material removal:

Rough turning (removes most material quickly).

Rough milling (shapes prismatic features).

Finish turning (refines cylindrical surfaces).

Finish milling (polishes slots/holes).

Operaciones secundarias (enhebrar, desbarbado).

For hard materials like titanium, usamos trochoidal milling (circular tool paths) to reduce cutting force and extend tool life.

Cutting Tool Selection:

We match tools to material and operation:

Turning Tools: Carbide inserts (TiAlN-coated for heat resistance) for metals; diamond tools for plastics.

Milling Tools: Solid carbide end mills (for precision) for metals; acero de alta velocidad (HSS) fresas finales (rentable) for plastics.

Drills/Taps: Cobalt drills for hard metals (titanio, inconel); HSS taps for soft metals (latón, aluminio).

Coolant Systems:

Directed coolant ensures optimal performance:

Flood Coolant: For metal machining—high-pressure (50–80 bar) coolant directed to the cutting zone reduces heat and flushes chips.

Mist Coolant: For plastics/exotics—atomized coolant prevents melting/warping without residue buildup.

Through-Spindle Coolant: For deep-hole drilling—coolant flows through the drill’s center to reach the cutting tip, improving chip evacuation.

Fixture Design:

Custom fixtures enhance stability and precision:

Collets: For small-diameter parts (≤20mm) to ensure concentricity (±0,001 mm).

Chucks: For large-diameter parts (20–150mm)—3-jaw chucks for round parts, 4-jaw chucks for irregular shapes.

Tailstocks: For long parts (≥300mm) to prevent deflection during turning/milling.

Estudios de caso: CNC Mill-Turning Success Stories

Nuestro CNC Mill-Turning services have solved complex part challenges for clients across aerospace and medical industries. Below are two successful projects showcasing our expertise:

Estudio de caso 1: Aerospace Turbine Shaft Manufacturer (Titanium Shafts)

Desafío: El cliente necesitaba 500 titanium turbine shafts (80mm de diámetro, 600mm length) for jet engines—each requiring a turned outer diameter, 4 milled keyways (120° apart), 6 cross-holes (0.8mm de diámetro), and a threaded end. Tolerances were ±0.002mm (critical for engine balance), and the client’s previous supplier used separate turning/milling (3 setups), causing 10% of shafts to fail due to misaligned keyways. Lead time was 5 semanas, delaying engine production.

Solución: Usamos un 5 ejes mill-turning center with live tooling and C-axis rotation. We machined each shaft in one setup: first turning the outer diameter and threading the end, then using C-axis indexing to mill the 4 keyways (120° apart) and radial live tools to drill the cross-holes. We used carbide turning inserts (TiAlN-coated) and high-pressure coolant (80 bar) to handle titanium’s low machinability. Our in-line touch probe checked keyway alignment mid-production, rejecting out-of-tolerance parts immediately.

Resultados:

Misalignment rate dropped from 10% to 0.5%—only 3 shafts failed per batch (vs. 50 previously).

Lead time shortened from 5 semanas para 2 weeks—helping the client meet their engine launch deadline.

Production cost per shaft decreased by 35% (reduced labor from 3 setups to 1).

Client Testimonial: “The single-setup mill-turning eliminated our biggest pain—misaligned keyways. The shafts balance perfectly, and the fast delivery saved our production line. We’ve made them our exclusive supplier for turbine shafts.” — Raj P., Aerospace Engineering Director.

Before and After: Traditionally machined shafts had uneven keyway spacing; mill-turned shafts featured perfectly aligned keyways and cross-holes that met engine balance requirements.

Estudio de caso 2: Medical Device Company (Titanium Orthopedic Screws)

Desafío: El cliente necesitaba 10,000 titanium orthopedic screws monthly (5mm de diámetro, 30mm length)—each with a turned cylindrical body, milled hex drive (for surgical tools), and threaded end. Tolerances were ±0.001mm (to ensure compatibility with bone plates), and the screws required a smooth surface finish (Ra ≤ 0.1μm) to reduce tissue irritation. The client’s previous supplier used separate turning/milling, conduciendo a 8% of screws having mismatched hex drives and threads.

Solución: We used a compact mill-turning center with live tooling and C-axis indexing. We loaded titanium bar stock into an automatic bar feeder (for unattended operation) and programmed the machine to: 1) turn the screw’s body and threads; 2) index the C-axis to 60° increments to mill the hex drive; 3) polish the surface with a fine-grit live tool. We used diamond-coated milling tools for the hex drive (to ensure sharp edges) and mist coolant to prevent titanium oxidation. Post-mecanizado, we inspected 100% of screws with a CMM and profilometer.

Resultados:

Defect rate dropped from 8% to 0.2%—only 20 screws failed per month (vs. 800 previously).

Surgeons reported a 40% reduction in screw insertion time (due to precise hex drive/thread alignment).

The client’s patient satisfaction score increased by 25% (thanks to the smooth surface finish).

Challenge Overcome: Separate turning/milling caused hex drives to be off-center relative to threads; CNC mill-turning’s single setup ensured perfect alignment.

Client Testimonial: “These screws fit better than any we’ve used—no more struggling with misaligned hex drives. The smooth finish also means less post-surgery irritation for patients. We’ve doubled our order.” — Dr. Lisa M., Orthopedic Surgeon.

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Why Choose Our CNC Mill-Turning Services?

With numerous CNC mill-turning providers, here’s what sets us apart as a trusted partner for complex part production:

Expertise in CNC Mill-Turning: Nuestro equipo tiene 22+ years of specialized experience—we master advanced techniques like live tooling, C-axis rotation, and Y-axis machining. Our engineers are certified in AS9100 (aeroespacial) y ISO 13485 (médico) and can solve complex challenges (p.ej., ±0.001mm tolerances in titanium, multi-feature small parts) that other providers struggle with.

Experience in Various Industries: hemos servido 750+ clientes en todo 10 industries—from aerospace giants to medical startups. This cross-industry experience means we understand sector-specific requirements: FAA compliance for turbine shafts, FDA regulations for orthopedic screws, and ISO/TS 16949 for automotive parts.

High-Quality Equipment: We invest in state-of-the-art mill-turning centers—15 systems (5-axis and 3-axis) with live tooling, automatic bar feeders, and in-line inspection (laser micrometers, touch probes). All machines are calibrated weekly (using laser interferometers) to maintain ±0.001mm precision.

Excelente servicio al cliente: Nuestro equipo está disponible 24/7 to support your project—from design consultation (optimizing parts for mill-turning) to post-delivery follow-up. We offer free CAD reviews (identifying features that can be consolidated into one setup) and free samples (so you can verify quality before placing large orders). Para proyectos urgentes (p.ej., medical supply shortages), we assign a dedicated project manager.

Tiempos de respuesta rápidos: Our optimized processes deliver industry-leading lead times:

Prototipos (1–50 unidades): 1–3 días

Low-volume orders (50–1.000 unidades): 3–7 días

High-volume orders (1,000+ unidades): 7–14 días

For rush orders (p.ej., aerospace emergency replacements), we can deliver parts in 48 horas (para lotes pequeños) by running machines 24/7.

Soluciones rentables: We help you save money through:

Single-setup machining: Eliminates 2–3 setups, reducing labor costs by 40–50%.

Unattended operation: Automatic bar feeders let us run machines overnight, lowering per-part labor costs.

Volume discounts: 10% off orders over 10,000 units and 15% off orders over 50,000 units—ideal for automotive/electronics high-volume parts.

Commitment to Quality: Somos ISO 9001, AS9100, y ISO 13485 certified—our quality control processes asegurar 99.9% of parts meet your specifications. We also offer full traceability (each part is labeled with a unique ID linked to machining logs and inspection data) for compliance.

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Preguntas frecuentes

When should I choose CNC Mill-Turning over separate turning/milling?

Choose CNC mill-turning if your part has both rotational (turned) and prismatic (milled) features (p.ej., a shaft with slots, a screw with a hex drive). It’s also ideal if:
You need tight tolerances (≤±0.005mm) (single setup eliminates repositioning errors).
You want to reduce lead time (30–50% faster than separate processes).
You’re producing high-volume parts (unattended operation cuts labor costs).
For parts with only turning features (p.ej., a simple shaft) or only milling features (p.ej., a flat bracket), separate machines are more cost-effective.

Can CNC Mill-Turning handle small, micro-components (p.ej., 0.5mm de diámetro)?

Yes—we specialize in micro-CNC mill-turning for parts as small as 0.5mm diameter. To ensure precision:
Usamos collets (instead of chucks) to hold small parts securely (concentricity ±0.001mm).
We use micro-live tools (0.1mm diameter end mills/drills) for milling tiny features (p.ej., 0.3mm cross-holes).
We run machines at lower speeds (2,000–5,000 RPM) to avoid vibration and tool breakage.
We regularly produce micro-components like medical needle hubs (0.8mm de diámetro) and electronics micro-pins (0.5mm de diámetro) with ±0.001mm tolerance.

How does CNC Mill-Turning ensure consistency for high-volume orders (p.ej., 200,000 regiones)?

Consistency in high-volume orders is guaranteed through three key steps:
Automated Programming: CAM software generates identical tool paths for every part—no manual adjustments that cause variation. We also program in-line inspections (p.ej., touch probe checks for keyway alignment or laser micrometer scans for diameter) to catch deviations early (p.ej., if a tool starts to wear, the system alerts operators before defects occur).
Calibrated Equipment: Our mill-turning centers are laser-calibrated daily (using NIST-traceable standards) to maintain ±0.001mm precision. We follow a strict tool replacement schedule—for example, carbide turning inserts are swapped after 500 regiones, and micro-milling tools after 300 parts—to avoid wear-related defects (p.ej., uneven slots or rough surface finishes).
Control estadístico de procesos (proceso estadístico): We sample 5% of parts per batch (p.ej., 10,000 parts for a 200,000-unit order) and analyze dimensions/finish with CMMs and profilometers. SPC software tracks trends (p.ej., if thread pitch drifts by 0.0005mm over time) and triggers adjustments (p.ej., tool offset tweaks) to keep production consistent. Para piezas críticas (p.ej., automotive transmission components), we also use automated vision systems to inspect 100% of parts for cosmetic and dimensional defects.
This combination of automation, calibración, and proactive monitoring ensures 99.5% of high-volume parts meet your specifications—no matter how large the order.