What Temperature Does Stainless Steel Melt?

A Practical, Buyer-Focused Guide by YISHANG

Why This Question Matters for Procurement Teams

Most procurement professionals searching “what temperature does stainless steel melt”, “stainless steel melting point”, or “stainless melting temp” are not looking for classroom definitions—they are making real sourcing decisions. They want to know whether a chosen stainless steel grade will survive high heat during use, assembly, transport, or cleaning cycles. Before we go deeper, here is the clear, snippet-ready answer:

Most stainless steels melt between 1370°C and 1530°C (2500°F–2785°F), depending on grade.

This number satisfies search intent but does not help buyers predict real-world product behavior. In mass production and OEM/ODM manufacturing, stainless steel parts rarely approach their melting temperature. Components typically fail much earlier due to distortion, strength loss, discoloration, creep, and thermal expansion. At YISHANG, we work with global wholesale buyers who manage large-scale stainless steel product lines—racks, enclosures, brackets, frames, trays, housings, and custom fabrications. This article explains melting temperature in a practical, procurement-oriented way: how it affects material selection, design decisions, and long-term performance in high-temperature environments.

What “Melting Point” Really Means in Stainless Steel

Stainless steel is an alloy, not a pure metal. It does not melt at one exact temperature. Instead, it transitions from solid to liquid over a melting range, defined by two key points:

• Solidus temperature – where softening and partial melting begin
• Liquidus temperature – where the alloy becomes fully molten

This explains why terms like melting point of SS steel, stainless melting temperature, and ss melting point often refer to slightly different values. Different stainless families have different melting behaviors:

• Austenitic (304, 316) – high corrosion resistance, widely used
• Ferritic (430) – magnetic, lower nickel content, good oxidation resistance
• Martensitic (410, 420) – stronger, used in wear-resistant applications

Because composition varies within a grade (e.g., nickel 8–10.5% for 304), the melting range shifts slightly between batches. For buyers, the takeaway is simple:

The melting point is the upper safety ceiling, not a performance predictor. Real behavior changes long before melting begins.

The Actual Melting Range of Stainless Steel

Most stainless steels melt between 1370°C and 1530°C. Below is a corrected, clean version of the melting table:

Stainless Steel Melting Point Chart

Stainless Family	Melting Range (°C)	Typical Use Cases
Austenitic (304/316)	1370–1450	Racks, baskets, enclosures, food equipment, OEM parts
Ferritic (430)	1425–1510	Decorative panels, appliance parts, exhaust components
Martensitic (410/420)	1450–1530	Blades, wear parts, tools

Comparison with Low Carbon Steel

To help buyers searching “melting temperature of low carbon steel”, here is a direct comparison:

Low carbon steel (mild steel) melts at about 1300–1400°C, slightly lower than stainless steel.

However, material selection between the two is rarely about melting point—it depends on corrosion resistance, hygiene requirements, oxidation behavior, weldability, and strength retention at temperature.

Short Answer to Key Variants

• What temp does stainless steel melt? → 1370–1530°C
• What temperature does stainless steel melt? → Depends on grade; see chart above
• Stainless steel melting temperature? → Same range; varies by alloy composition

But melting temperature is not where failures occur in real applications—which leads to the next section.

Why Stainless Steel Fails Long Before It Melts

High-temperature failures happen far below the stainless steel melting temperature. Understanding this is critical for accurate sourcing and design evaluation.

Strength Loss at Elevated Temperature

Stainless steel loses strength as temperature rises. For example, 304 stainless can lose over 40% of its yield strength around 700–800°C. This affects:

• Load-bearing racks sagging
• Brackets bending under heat cycles
• Welded frames deforming faster than expected

This is why strength retention, not stainless melting point, dictates performance.

Thermal Expansion and Distortion

With a thermal expansion coefficient of 16–18 × 10⁻⁶/°C, stainless steel expands significantly when heated. Common outcomes include:

• Sheet-metal doors no longer aligning
• Flat trays warping into a curve
• Misaligned mounting holes
• Sliding racks losing smooth fit

These problems occur at 150–400°C—nowhere near melting.

Oxidation, Creep, and Microstructural Change

At moderate to high temperatures:

• Oxide layers form → surface discoloration
• Continuous load causes creep → slow, irreversible deformation
• Grain structure changes → reduced toughness and corrosion resistance

These transformations permanently affect function and appearance long before reaching melting range.

“How Hot Is Too Hot?” – A Better Question for Buyers

The practical procurement question is not “what is the stainless steel melting temperature?” but:

“At what temperature will this material still meet performance expectations?”

This is what maximum service temperature describes.

General Guidelines

• 304 stainless steel: usable up to ~870°C intermittently; strength drops above ~600–700°C
• 316 stainless steel: better corrosion performance; heat + chlorides accelerate breakdown at lower temperatures
• Ferritic (430/446): excellent oxidation resistance; lower toughness

For OEM and wholesale projects such as oven racks, furnace carriers, or food equipment, discussing these conditions early avoids redesigns and quality disputes.

Why Two “304 Stainless” Parts Perform Differently

Even within the same grade, stainless steel performance varies due to manufacturing factors.

Composition and Batch Variations

ASTM allows composition ranges. Differences in nickel, carbon, or trace elements influence heat behavior. Stable sourcing and mill certificates help buyers ensure consistency.

Geometry, Thickness and Fabrication

• Thin mesh, perforated sheet, and wire heat faster
• Thick plate builds internal thermal gradients
• Welded areas behave differently from bent areas
• Long spans are more susceptible to creep

Identical materials do not guarantee identical high-temperature performance.

Surface Finish and Coatings

• Polished surfaces resist oxidation better
• Rough surfaces oxidize faster
• Organic coatings may burn off

Appearance under heat is critical for customer-facing products.

A Practical Framework for Evaluating Heat Suitability

Instead of focusing on the stainless melting temp, use this engineering mindset:

Temperature Profile

• Peak temperature
• Duration
• Heating/cooling cycles
• Ramp rate

Environment

Different media accelerate aging differently:

• Steam, moisture, combustion gases
• Food acids, oils, detergents
• Salt or chlorides

Mechanical Load

• Static vs. dynamic loads
• Point loads vs. distributed loads
• Support points and span length

Geometry and Lifetime Expectations

• Thin vs. thick sections
• Flat surfaces vs. reinforced corners
• Required lifespan vs. acceptable consumable behavior

This approach is far more accurate than relying on melting temperature alone.

Misconceptions That Affect Purchasing Decisions

Misconception 1: “Higher melting point = better performance.”

High-temperature performance depends on oxidation, strength retention, and corrosion—not melting point.

Misconception 2: “If it doesn’t melt, it won’t fail.”

Most failures occur hundreds of degrees below melting.

Misconception 3: “All 304 stainless is the same.”

304, 304L, 304H and different batch compositions behave differently.

Misconception 4: “Discoloration = defect.”

Color shifts often indicate oxidation, not structural failure.

Misconception 5: “Thicker = better.”

Thickness alone cannot prevent thermal distortion.

When Melting Temperature Actually Matters

Laser / Plasma Cutting

Melting behavior affects kerf quality, burrs, and HAZ.

Welding / Brazing

Solidus-liquidus range determines penetration, bead stability, and distortion.

Casting

Fluidity and solidification behavior depend on liquidus temperature.

Heat Treatment

Processes must stay safely below solidus to avoid microstructural damage.

Fire / Extreme Testing

Exact melting data is used for safety modeling.

Final Takeaway for Wholesale Buyers and OEM Teams

The melting point of stainless steel is real and scientifically defined—but it does not determine real-world performance. Most failures stem from:

• Strength loss
• Thermal distortion
• Oxidation
• Creep
• Microstructural change

All happening far below melting. If you remember one thing:

Base your purchasing decisions on service conditions, not melting temperature.

For high-volume stainless steel parts—racks, enclosures, trays, brackets, frames—YISHANG provides engineering-based suggestions and reliable OEM/ODM production. If you’d like technical guidance or a quotation, feel free to share your drawings and project requirements.

FAQ: Quick Answers Buyers Often Search

Q1: What temp does stainless steel melt? Most stainless steels melt at 1370–1530°C. Q2: What is the melting temp of stainless steel compared to low carbon steel? Low carbon steel melts at 1300–1400°C, slightly lower than stainless. Q3: Does stainless steel fail before it melts? Yes—distortion, creep, and oxidation occur long before melting. Q4: How should buyers use melting temperature in sourcing? Treat it as a reference number. Base decisions on service temperature, load, environment and geometry.