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Aluminum is strong, light, and versatile-but how hot does it need to get before it melts?

The melting point of pure aluminum is approximately 660.3°C (1220.5°F), which plays a critical role in how it’s processed, shaped, and applied in various industries.

Knowing the melting point is not just academic. It affects welding, casting, machining, recycling, and structural safety. Let’s explore what it really means and why it matters.

How Is Aluminum’s Melting Point Determined?

Melting point isn’t something we guess-it’s measured using precise tools and repeatable lab methods.

Aluminum’s melting point is determined by heating a pure sample and recording the exact temperature at which it transitions from solid to liquid.

There are several ways to do this accurately:

1. Capillary Tube Method

This technique is common in labs. A small sample of aluminum is packed into a thin glass capillary tube. As the tube is heated in a controlled environment, the melting point is observed when the solid aluminum becomes a liquid.

2. Differential Scanning Calorimetry (DSC)

This is a more modern and scientific method. DSC detects the exact temperature at which heat flow changes as aluminum changes state. It’s very accurate and often used for metals and alloys.

3. Hot Stage Microscopy

In this method, aluminum is heated on a transparent stage. Scientists observe the sample under a microscope to record when melting begins and ends.

4. Furnace Testing with Thermocouples

This method involves placing aluminum inside an industrial furnace and using thermocouples to measure internal temperature during heating.

These tests help determine two key points:

• ソリダス: The temperature where melting starts
• リクイダス: The temperature where the metal is fully liquid

For pure aluminum, solidus and liquidus are the same, around 660.3°C. But for alloys, these points can be 100°C or more apart.

How Does Alloying Affect Aluminum’s Melting Point?

Pure aluminum melts at a consistent temperature. But when we add other elements to create alloys, everything changes.

Alloying aluminum with elements like magnesium, silicon, copper, or zinc lowers its melting point and creates a melting range rather than a single temperature.

Why Does This Happen?

Each element has its own atomic structure and melting behavior. When mixed into aluminum, they disrupt the uniform crystalline lattice. That interference causes atoms to melt at slightly different temperatures-hence the melting range.

Effects of Common Alloying Elements:

This change is important for manufacturing. Wrought and cast alloys behave differently during heating, welding, and forming. For instance, alloys with lots of silicon are great for casting because they melt smoothly without gumming.

Melting Range vs Point

Pure aluminum melts sharply at 660.3°C. In contrast, alloys might start melting at 500°C but not fully liquify until 650°C. This wide range is key when choosing alloys for welding or heat treatment.

What Is the Melting Point of Common Aluminum Alloys?

Aluminum alloys are used more often than pure aluminum, especially in construction, transport, and consumer goods. Each alloy melts differently.

Common aluminum alloys melt within a range between 475°C and 660°C, depending on their specific composition and series classification.

Wrought Aluminum Alloys

Cast Aluminum Alloys

These ranges affect how each alloy is processed. Lower-melting alloys are easier to cast, while higher-melting alloys may be better for structural applications.

Why Does Melting Point Matter in Aluminum Processing?

The melting point affects nearly every stage of aluminum’s life cycle-from casting to recycling.

Melting point matters in aluminum processing because it controls how the metal behaves under heat, affects weld quality, and influences manufacturing efficiency.

1. キャスティング

Foundries need precise temperatures. If aluminum gets too hot, it can oxidize or form gas bubbles. If it’s not hot enough, the mold won’t fill.

2. 溶接

Knowing the solidus and liquidus points of aluminum alloys helps welders avoid cracking, warping, and incomplete fusion.

3. 熱処理

Processes like annealing and precipitation hardening rely on heating just below melting point. Overheating destroys grain structure.

4. 機械加工

During cutting or milling, heat builds up. Alloys with lower melting points need coolant or low-speed tools to avoid deformation.

5. リサイクル

In smelting facilities, aluminum scrap is melted and reformed. Predictable melting points improve efficiency and reduce waste.

6. Safety in Design

Aluminum structures must maintain strength even when hot. If exposed to temperatures near melting, parts may fail.

Understanding melting behavior also helps in alloy selection. Engineers must pick the right alloy for the right job-not just for strength or cost, but for thermal compatibility too.

結論

Aluminum melts at around 660.3°C, but that number changes with alloys. Whether you’re welding, casting, machining, or recycling, knowing the melting range is essential.

The next time you see an aluminum part-be it an airplane wing, soda can, or window frame-remember: the heat it can handle depends on its melting point. And choosing the right alloy means knowing when things start to melt.