Accelerating Your NPI with Fast-Turnaround 

Medical Component Manufacturing

· OEM CNC Manufacturing

· ISO 13485:2016 Certified

· 35+ CNC Machines & Post-Finishing

· 60+ Materials Available

· From Prototypes to Volume Production

Get Instant Quote

Our workshop is equipped with 35+ advanced CNC machines, including CNC turning, milling, 5-axis machining centers, dedicated to high-precision medical device components machining, ensuring stable quality and efficient delivery.

Production Equipments

3-Axis CNC Milling Machine for Medical Device & Implant Machining - ISO 13485 Compliant Production
Wire EDM (Wire Cut EDM) for Precision Medical Component Machining - ISO 13485 Certified
4-Axis CNC Machining Center for Orthopedic Implant & Medical Device Manufacturing
CNC Sinker EDM for Complex Medical Implant Feature Machining - ISO 13485 Compliant
5-Axis Linkage CNC Machining Center for Custom Complex Medical Implant Manufacturing
Dry Sandblasting Machine for Medical Implant Surface Treatment & Osseointegration
CNC Turn-Mill Machine for Precision Medical Component & Implant Parts Manufacturing
Laser Engraving & Marking Machine for Medical Component Traceability - ISO 13485 Certified
Tsugami Swiss-Type CNC Lathe (Swiss Screw Machine) for Precision Medical Component & Implant Machini
Metal 3D Printer for Additive Manufacturing of Custom Medical Implants - ISO 13485 Certified

3-Axis CNC Machine

13X | Rapid Prototyping

4-Axis CNC Machine

5-Axis CNC Machine

6X | Complex Implants

Turn-Mill Machine

4X | Precision Turn-Mill

Tsugami Swiss-type Automatic Lathe

2X | Precision Turning

Wire Cutting Machine

EDM Machine

1X | Hard Machining

Sandblasting Machine

2X | Surface Finishing

Laser Engraving 

2X | Traceability Marking

3D Printer

2X | Custom Implants

1X | Intricate Cutting

10X | Complex Milling

Technical Specifications

1. Multi-Axis CNC Milling Centers

Process Introduction

A full lineup of 3/4/5-axis machining centers supports a wide range of orthopedic parts, from general structural components to complex anatomical implants. Machine selection is matched to part structure and production requirements for efficient and stable manufacturing.

Included Equipment

· 3-axis CNC Machine (13X)

· 4-axis CNC Machine (10X)

· 5-axis CNC Machine (6X)

Technical Specifications

Machine Type
Max. Workpiece Size (mm)
Min. Workpiece Size (mm)
Positioning Tolerance
3-axis CNC
800 × 500 × 450
50 × 30 × 20
±0.03 mm
4-axis CNC
5-axis CNC
600 × 400 × 400
500 × 380 × 320
40 × 25 × 15
30 × 20 × 10
±0.025 mm
±0.02 mm

Typical Orthopedic Applications

· Large implant bases and instrument trays

· Angled screw seats and tapered parts

· Multi-surface joint implants

· Complex anatomical prosthetics

2. Precision Turning & Mill-Turn

Process Introduction

High-efficiency turning and mill-turn centers support shaft-type, threaded and small rotary parts. Swiss-type lathes deliver stable performance for miniature orthopedic fasteners with consistent quality.

Included Equipment

· Turn-Mill Machine (4X)

· Tsugami Swiss-type Lathe (2X)

Technical Specifications

Machine Type
Max. Bar Diameter (mm)
Min. Bar Diameter (mm)
Machining Tolerance
Turn-Mill Machine
52
3
±0.025 mm
Tsugami Swiss-type Lathe
20
0.5
±0.02 mm

Typical Orthopedic Applications

· Bone screws, pins and fasteners

· Shafts, sleeves and instrument handles

· Small precision rotary implants

· Miniature orthopedic instrument parts

3. Wire Cutting EDM Machine

Process Introduction

Wire Electrical Discharge Machining (Wire EDM) uses a thin, continuously fed brass wire (Φ0.2 mm) as an electrode to erode conductive materials via controlled electrical sparks. It excels at cutting intricate, narrow slots, complex internal contours, and delicate features that traditional CNC machining cannot easily achieve—ideal for high-precision orthopedic components where tight tolerances and fine details are critical.

Included Equipment

· Wire Cutting Machine (1X)

Technical Specifications

Parameter
Details
450 × 350 × 200
Max. Workpiece Size (mm)

Typical Orthopedic Applications

· Micro slots and narrow grooves on surgical instruments

· Complex internal contours of spinal implants and orthopedic tooling

· High-precision cutting of hardened titanium/stainless steel components

· Delicate part separation for small-batch implant prototypes

Min. Workpiece Size (mm)
20 × 20 × 5 (stable clamping & machining feasible)
Min. Feature Width (mm)
≥0.25 (matches Φ0.2 mm wire + spark gap)
Machining Tolerance
±0.02 mm
Surface Roughness (Ra)
0.8 μm (standard) / 0.4 μm (fine finish)
Cutting Wire
Φ0.2 mm brass wireΦ0.2 mm brass wire
Compatible Materials
Ti-6Al-4V ELI, 316L stainless steel, CoCrMo, hardened tool steel, and other conductive metals

4. Sinker EDM

Process Introduction

Sinker EDM (Die Sinking EDM) uses a custom-shaped graphite or copper electrode to erode conductive materials into precise 3D cavities, blind holes, or complex internal features. It is the go-to process for machining hard-to-cut materials (e.g., hardened steel, CoCrMo) and intricate geometries that cannot be accessed by cutting tools—critical for orthopedic implants with deep, narrow cavities.

Included Equipment

· Sinker EDM Machine (1X)

Technical Specifications

Parameter
Details
300 × 250 × 180
Max. Workpiece Size (mm)

Typical Orthopedic Applications

· Complex internal cavities of hip/knee implant components

· Blind holes and shaped features in spinal fixation devices

· High-hardness orthopedic tooling with intricate 3D contours

· Micro-features on small-batch implant prototypes

Min. Workpiece Size (mm)
15 × 15 × 3 (stable clamping & electrode alignment feasible)
Min. Cavity / Hole Diameter
≥0.3 mm
Max. Cavity Depth
Up to 50 mm (aspect ratio ≤10:1)
Machining Tolerance
±0.025 mm
Surface Roughness (Ra)
0.4 μm (standard) / 0.2 μm (polished finish)
Electrode Materials
Graphite (large cavities) / Copper (fine details)
Compatible Materials
Ti-6Al-4V ELI, 316L stainless steel, CoCrMo, hardened tool steel, and other conductive metals

5. Sandblasting

Process Introduction

Sandblasting is a non-contact surface treatment that uses high-velocity abrasive media (e.g., glass beads, aluminum oxide) to clean, deburr, or roughen medical component surfaces. For orthopedic implants, controlled roughening is critical to enhance osseointegration (bone-implant bonding), while cleaning removes oxides and contaminants to meet medical device manufacturing standards.

Included Equipment

Sandblasting Machine (2X)

Technical Specifications

Parameter
Details
600 × 500 mm
Max. Working Range

Typical Orthopedic Applications

· Surface roughening of orthopedic implants to promote bone integration

· Removal of oxides, scale, and contaminants from implant/tool surfaces

· Deburring and cleaning of surgical instruments post-machining

· Pre-treatment for coating or bonding processes

Min. Working Range
30 × 30 mm (stable fixture & uniform blasting feasible)
Air Pressure
0.2–0.6 MPa (adjustable)
Surface Roughness (Ra)
1.6–6.3 μm (customizable: lower Ra for cleaning, higher Ra for osseointegration)
Abrasive Media
Glass beads (cleaning/light roughening), aluminum oxide (heavy roughening)
Compatible Materials
Ti-6Al-4V ELI, 316L stainless steel, CoCrMo, PEEK...

6. Laser Engraving

Process Introduction

Laser engraving uses a 20W fiber laser to create permanent, high-resolution marks on medical components without physical contact. It is essential for product traceability (lot numbers, serial numbers, UDI codes) and brand identification, complying with global medical device regulations (e.g., FDA, CE) while preserving material biocompatibility and mechanical integrity.

Included Equipment

Laser Engraving Machine (2X)

Technical Specifications

Parameter
Details
110 × 110 mm
Max. Working Range

Typical Orthopedic Applications

· Lot number, serial number, and UDI (Unique Device Identification) marking for traceability

· Company logo and part number engraving on implants and instruments

· Patient-specific identifier marking for custom orthopedic devices

· Non-damaging surface marking that complies with medical regulatory requirements

Min. Working Range
5 × 5 mm (stable positioning & clear marking feasible)
Laser Power
20W fiber laser
Marking Depth
0.01–0.1 mm (medical use: 0.02–0.05 mm to avoid stress concentration)
Min. Character Size
0.3 mm (high-resolution legible marking)
Marking Durability
Permanent, non-fading, resistant to sterilization (autoclave, EtO)
Compatible Materials
Ti-6Al-4V ELI, 316L stainless steel, CoCrMo, ceramics...

7. Medical Additive Manufacturing (3D Printing)

Process Introduction

Medical-grade 3D printing supports patient-specific implants and porous structure parts. Biocompatible metal materials are used to meet clinical and anatomical customization demands.

Included Equipment

· Medical SLM 3D Printer (2X)

Technical Specifications

Machine Type
Build Volume (mm)
Layer Thickness
Printing Accuracy
Materials
3D Printer
250 × 250 × 300
30–100 μm
±0.1 mm
Ti6Al4V ELI, CoCr...

Typical Orthopedic Applications

· Patient-matched orthopedic implants

· Porous structure prosthetics

· Complex lattice implant parts

· Customized anatomical components

Precision CNC Machining Process for Medical Implant & Component Manufacturing

Get A Quote

Ready to start your project? Send us your drawings, and we’ll reply with a quote in 1-24 hours.

Tel: +86 18718750572

Decorative UI icon

Email: enquiry@honlike.com.cn

WhatsApp: +86 18718750572

101-103, Building 8, Bay Area Intelligence Valley, West District, Zhongshan, 528411, GuangDong, China

COMPANY

Decorative UI icon