TC4 Titanium Alloy
TC4 (Ti-6Al-4V) is the most widely used alpha-beta dual-phase titanium alloy, featuring low density, high specific strength and outstanding corrosion resistance. It is a core lightweight structural material for aerospace, medical and precision equipment industries.
Typical Chemical Composition
- Aluminum (Al): 5.5%–6.75% – Reinforces alpha phase, improves tensile strength and high-temperature stability
- Vanadium (V): 3.5%–4.5% – Stabilizes beta phase, enhances ductility and forming performance
- Iron (Fe): ≤0.25%
- Oxygen (O): ≤0.20%
- Carbon (C): ≤0.08%
- Balance: Titanium (Ti)
Core Material Properties
- Ultra-Low Density & High Specific Strength Density only around 4.43 g/cm³, roughly 60% of stainless steel. Its strength-to-weight ratio far outperforms steel and aluminum alloys, enabling lightweight design without sacrificing load capacity.
- Excellent Universal Corrosion Resistance A dense inert titanium oxide film spontaneously forms on the surface, resisting seawater, salt mist, sweat, organic solvents, weak acids and alkalis. Corrosion resistance surpasses 316 stainless steel in chloride-rich environments.
- Outstanding Biocompatibility Non-toxic and non-irritating to human tissue, no metal ion precipitation. Fully compliant with medical implant standards for long-term bodily contact.
- Stable Extreme Temperature Performance Works reliably at cryogenic temperatures without brittleness; maintains stable mechanical properties up to 400°C for continuous service.
- Non-magnetic Characteristic Completely non-magnetic under all working conditions, suitable for magnetic resonance equipment and magnetic-sensitive electronic precision parts.
- Moderate Forming & Machining Performance Higher forming difficulty than stainless steel due to low thermal conductivity; MIM requires tailored powder sintering processes to avoid oxidation defects.
Machining & MIM Process Adaptability
- Metal Injection Molding (MIM) TC4 titanium powder can produce complex thin-walled lightweight components via MIM. Sintering must be carried out under high-purity inert atmosphere to prevent surface oxidation and oxygen embrittlement. Ideal for miniature lightweight structural parts with tight weight and tolerance requirements.
- Compatible Surface Treatments Supports sandblasting, mirror polishing, anodizing, PVD coating and passivation. Anodization forms colorful protective oxide layers for both decorative and anti-corrosion functions.
- Heat Treatment Options Can be stress-relieved, solution treated and aged to adjust strength and ductility; aging significantly improves tensile strength for high-load lightweight parts.
Advantages & Disadvantages
Advantages
- Ultra-light weight with superior specific strength, obvious weight reduction effect
- Top-tier corrosion resistance in salt, sweat and marine environments
- Medical-grade biocompatibility for implants and surgical instruments
- Non-magnetic, no interference to precision magnetic equipment
- Excellent low-temperature toughness, no brittle fracture under cryogenic conditions
Disadvantages
- Much higher raw material and processing cost than stainless steel
- Poor thermal conductivity leads to higher machining difficulty
- Strict inert atmosphere protection required during sintering, increasing MIM production cost
- Surface easily absorbs oxygen at high temperature, causing brittleness if process is not controlled properly
Typical Applications
- Medical Devices: Bone implant accessories, minimally invasive surgical instruments, dental structural parts
- Aerospace & Aviation: Miniature lightweight fasteners, sensor brackets, thin-wall structural fittings
- High-end Smart Wearables: Luxury watch cases, lightweight bezels, skin-friendly buckles
- Marine & Fluid Equipment: Seawater corrosion-resistant lightweight connectors, valve miniature parts
- Precision Electronic Hardware: Non-magnetic structural brackets for MRI and magnetic sensors