Stainless Steel Titanium Grade 1 Supplier | SS Titanium Manufacturers in Delhi, India

Titanium CP Grade 1

Chemistry Data

General Information

Principal Design Features

This is an un-alloyed grade designed for excellent weldability, good strength, impact toughness, ductility and corrosion resistance. Beta Transus (F +/- 25) 1630.

Applications

Corrosion resistant applications in the chemical process industry, airframe and other areas where ease of formability is required.

Machinability

As a family, titanium and its alloys have developed a mystique as a nightmare to machine. This is simply not the case Experienced . operators have compared its characteristics to those found in 316 stainless steel. Recommended practice includes high coolan

Forming

May be hot or cold formed using hydropress, power brake, stretch or drop hammer methods. Similar in characteristics to 300 series stainless steels.

Corrosion Resistance

Highly resistant to a wide variety of oxidizing and mildly reducing environments, including chlorides.

Welding

Rated as "good" in terms of weldabilty.

Hot Working

Not hardenable by heat treatment.

Forging

Rough work at 871 C (1600 F), finish at 788-843 C (1450-1550 F)

Hot Working

Hot forming will reduce both the springback and required forming forces, and will increase the overall ductility of the material.

Cold Working

The cold work characteristics of this material is similar to that of a moderately tempered austenitic stainless steel. In multiple cold forming operations, intermediate stress relief is recommended to prevent tearing or other material damage. Post-work an

Annealing

Heat to 704 C (1300 F),hold for 2 hours follow by air cooling. For intermediate stress relieving, heat to 482 F(900 C) and hold for 45 minutes.

Other Physical Props

Beta Transus (F +/- 25) 1630.

• Density (lb / cu. in.)
• Specific Heat (Btu/lb/Deg F - [32-212 Deg F])
• Electrical Resistivity (microhm-cm (at 68 Deg F))
• Melting Point (Deg F)
• Thermal Conductivity
• Modulus of Elasticity Tension
• Reduction of Area

• 0.163
• 0.124
• 56
• 3040
• 9
• 14.9
• 30

• Form
• Condition
• Temper
• Tensile Strength
• Yield Strength
• Elongation
• Reduction of Area

• Strip
• Test Specimen Annealed
• 70
• 35
• 25
• 24
• 30

• Form
• Condition
• Temper
• Tensile Strength
• Yield Strength
• Elongation
• Reduction of Area

• Strip
• Test Specimen Annealed
• 600
• 26
• 15
• 32
• 75

• Form
• Condition
• Temper
• Tensile Strength
• Yield Strength
• Elongation
• Reduction of Area

• Strip
• Test Specimen Annealed
• 800
• 20
• 13
• 26
• 75

• Carbon
• Chromium
• Iron
• Manganese
• Molybdenum
• Phosphorus
• Silicon
• Sulphur

• 0.05 max
• Balance
• 0.5 max
• 0.03 max
• 0.5 max
• 0.01 max

General Information

Principal Design Features

Similar in chemistry and performance to 430 stainless steel, 434 has the addition of molybdenum to increase its resistance to corrosion.The alloy combines a ferritic structure with good fabricability and strength characteristics.

Applications

Primarily used in automotive trim applications and other exterior environments.

Machinability

Although not commonly available in machinable forms, 434 has been successfully machined using all standard methods.

Forming

Excellent ductility allows a wide variety of successful forming operations including shearing, blanking and deep drawing.

Corrosion Resistance

Resistant to mildly corrosive environments and atmospheric conditions. A dense polished finish will make this alloy resistant to all but the most direct salt water exposure.

Welding

434 can be successfully welded using most common methods. Standard type 308 filler material may be used, although if the part will undergo thermal cycling, it is recommended to use a filler material of similar composition. Material must be thoroughly clea

Forging

Begin forging after thorough soaking at 2000-2100 F and finish at 1350 F.

Annealing

Soak thoroughly at 1450-1600 F, air cool.

Hardening

This alloy does not respond to hardening by heat treatment.