Steel is well-known for its incredible durability against various stress factors. The impact tolerance, tensile strength, and heat resistance of steel far outclasses that of plastic polymers. Stainless steel alloys represent a further improvement that grants enhanced resistance to various caustic and corrosive chemicals.
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However, just how tough is stainless steel when paired side by side to other metals? How does the stainless steel melting point compare with other metal melting points? This is a common question from companies looking to order a stainless steel basket or tray for high-intensity applications.
Specifically, many companies with heat treatment, annealing, or sterilization processes wonder “what is the melting point of stainless steel?” because they have to use the steel for a high-temperature process.
How Much Heat Can Stainless Steel Take Before Melting?
This question is a valid one—but it can be hard to answer without first asking “what alloy of stainless steel are we talking about?”
There are countless different formulations of stainless steel out there, from the austenitic stainless steels (such as 304, 316, and 317) to the ferritic stainless steels (such as 430 and 434), as well as the martensitic stainless steels (410 and 420). Additionally, many stainless steels have low-carbon variants. The problem with trying to make a blanket statement about stainless steel melting point is that all of these alloys have different temperature tolerances and melting points.
Here is a list of different stainless steel alloys and the temperatures at which they melt (data based on figures from the BSSA):
- Grade 304. 1400-1450°C (2552-2642°F)
- Grade 316. 1375-1400°C (2507-2552°F)
- Grade 430. 1425-1510°C (2597-2750°F)
- Grade 434. 1426-1510°C (2600-2750°F)
- Grade 420. 1450-1510°C (2642-2750°F)
- Grade 410. 1480-1530°C (2696-2786°F)
You might have noticed that each of these melting points is expressed as a range, rather than an absolute number
This is because, even within a specific alloy of stainless steel, there is still the possibility of small variations in the formulation which can affect the melting point. These are just a few of the more common alloys of stainless steel on the market. There are many more variations of stainless steel that could be used in a range of applications—far too many to cover them all here.
While these are the melting points of these stainless steel alloys, the recommended maximum use temperatures of these alloys tends to be far lower.
Other Metal Melting Points
It’s important to know about the properties of other metals and how they compare to the average stainless steel melting point. Below is a chart displaying the metal melting points of popular industrial alloys and metals.
Metal
Melting Point Celsius (℃)
Melting Point Fahrenheit (℉)
Admiralty Brass
900 - 940
1650 - 1720
Aluminum
660
1220
Aluminum Alloy
463 - 671
865 - 1240
Aluminum Bronze
600 - 655
1190 - 1215
Babbitt
249
480
Beryllium
1285
2345
Beryllium Copper
865 - 955
1587 - 1750
Bismuth
271.4
520.5
Brass, Red
1000
1832
Brass, Yellow
930
1710
Cadmium
321
610
Chromium
1860
3380
Cobalt
1495
2723
Copper
1084
1983
Gold, 24k Pure
1063
1945
Hastelloy C
1320 - 1350
2410 - 2460
Inconel
1390 - 1425
2540 - 2600
Incoloy
1390 - 1425
2540 - 2600
Iron, Wrought
1482 - 1593
2700 - 2900
Iron, Gray Cast
1127 - 1204
2060 - 2200
Iron, Ductile
1149
2100
Lead
327.5
621
Magnesium
650
1200
Magnesium Alloy
349 - 649
660 - 1200
Manganese
1244
2271
Manganese Bronze
865 - 890
1590 - 1630
Mercury
-38.86
-37.95
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Molybdenum
2620
4750
Monel
1300 - 1350
2370 - 2460
Nickel
1453
2647
Niobium (Columbium)
2470
4473
Palladium
1555
2831
Phosphorus
44
111
Platinum
1770
3220
Red Brass
990 - 1025
1810 - 1880
Rhenium
3186
5767
Rhodium
1965
3569
Selenium
217
423
Silicon
1411
2572
Silver, Pure
961
1761
Silver, Sterling
893
1640
Carbon Steel
1425 - 1540
2600 - 2800
Stainless Steel
1510
2750
Tantalum
2980
5400
Thorium
1750
3180
Tin
232
449.4
Titanium
1670
3040
Tungsten
3400
6150
Yellow Brass
905 - 932
1660 - 1710
Zinc
419.5
787
Why Metal Melting Points Shouldn’t Be Your Only Temperature Concern
At extremely high temperatures, many materials begin to lose their tensile strength. Steel is no exception. Even before the stainless steel melting point is reached, the metal itself becomes less rigid and more susceptible to bending when heated.
For example, let’s say a stainless steel alloy retains 100% of its structural integrity at 870°C (1679°F), but at 1000°C (1832°F) it loses 50% of its tensile strength. If the maximum load of a basket made with this alloy were 100 pounds, the basket would then only be able to hold 50 pounds of weight after exposure to the higher temperature. Any more weight, and the basket could bend out of shape under the load.
Also, exposure to high temperatures could have effects other than making stainless steel easier to bend or break. High temperatures can affect the protective oxide layer that keeps stainless steel from rusting—making it more susceptible to corrosion in the future.
In some cases, extreme temperatures can cause scaling on the surface of the metal. This can impact the performance of a parts handling basket or other custom wire form. Or, high temperatures can lead to thermal expansion of the metal in a custom wire basket, causing welded joints to come loose.
So, even if your particular process wouldn’t reach the stainless steel melting point exactly, high temperatures could still do damage in other ways.
It is also important to compare the melting points of steel alloys with other metal melting points to see what would fit your needs best. There are many factors that go into creating a quality basket and deciding what metal to use is a crucial question that depends on the basket’s task and environment.
This is why Marlin Steel’s engineering team runs finite element analyses on each and every basket design. By testing the effects of high temperatures on a design, the engineering team can spot potential issues like scaling, and test alternative materials that can prevent such problems from making the design invalid.
Get more insights into the properties of stainless steel by downloading the Stainless Steel Properties Sheet today!
Melting stainless steel is a complex process that requires precision and expertise. However, with the right equipment and proper preparation, you can efficiently melt stainless steel using an induction furnace. In this article, we will discuss the process of melting stainless steel using an induction furnace in greater detail and provide tips on how to do it effectively.
Induction Furnaces for Melting Stainless Steel
Induction furnaces utilize electromagnetic induction to melt various metals, such as stainless steel. This method involves the passage of electric current through a coil made of copper wire, producing a magnetic field. Once a metal object is positioned within the magnetic field, eddy currents are induced, resulting in the gradual heating and eventual melting of the metal.
Induction furnaces are an excellent option for melting stainless steel because they can reach high temperatures quickly, making the melting process faster and more efficient. They are also energy-efficient, which makes them an environmentally friendly option.
Preparing Stainless Steel for Melting
Before melting stainless steel, it is crucial to prepare it properly. Proper preparation ensures that the steel melts evenly and quickly, and there are no defects in the final product. Here are some steps to follow when preparing stainless steel for melting:
- Remove any coatings or rust from the surface of the steel using a wire brush or sandpaper. This ensures that impurities do not get into the molten steel, affecting its quality.
- Cut the stainless steel into smaller pieces if it is too large to fit into the furnace. Smaller pieces melt more quickly and evenly.
- Ensure that the stainless steel is dry and free of any moisture. Moisture can cause the steel to explode when heated, leading to injuries and damage to the furnace.
Choosing the Right Induction Furnace
Choosing the right induction furnace is crucial to melting stainless steel effectively. Here are some factors to consider when choosing an induction furnace:
- Furnace Size: The size of the furnace should be appropriate for the size of the stainless
steel that you want to melt. A furnace that is too small may not be able to accommodate the steel, while a furnace that is too large may waste energy.
- Furnace Capacity: The capacity of the furnace determines how much steel it can melt in a single cycle. Choose a furnace with a capacity that meets your production needs.
- Power Output: The power output of the furnace determines how quickly it can melt the steel. A higher power output means faster melting times.
- Energy Efficiency: Choose a furnace that is energy-efficient to save on operating costs.
Preparing the Induction Furnace
Before you start melting the stainless steel, you need to prepare the induction furnace properly. Here are some steps to follow:
- Clean the furnace and ensure that it is free of debris. This prevents impurities from contaminating the molten steel.
- Ensure that the power supply is connected and turned on.
- Set the furnace to the appropriate temperature for melting stainless steel.
Melting the Stainless Steel
Once the furnace is ready, it’s time to start melting the stainless steel. Here are some steps to follow:
- Place the stainless steel in the furnace using tongs or a crane.
- Turn on the power to the furnace, and the electromagnetic induction will heat the steel until it reaches its melting point.
- As the steel melts, you may need to stir it to ensure that it melts evenly.
- Use a temperature gauge to monitor the temperature of the molten steel.
Pouring the Molten Steel
Once the stainless steel has melted completely, it’s time to pour it into a mold. Here are some steps to follow when pouring the molten steel:
- Ensure that the mold is clean and dry before pouring the molten steel into it.
- Hold the ladle with the molten steel steadily and carefully to avoid any spillage.
- Pour the molten steel slowly into the mold to prevent turbulence and air entrapment.
- Continue pouring until the mold is completely filled.
- Tap the mold lightly with a hammer or mallet to release any trapped air.
- Allow the steel to cool down and solidify completely before removing it from the mold.
- Once cooled, the stainless steel can be further processed or used as is, depending on the intended application.
Safety Precautions When Melting Stainless Steel
Melting stainless steel can be a hazardous process, and it’s essential to take the necessary safety precautions to prevent accidents and injuries. Here are some safety tips to follow when melting stainless steel:
- To safeguard yourself from high temperatures and flying objects, wear personal protective equipment (PPE) like gloves that can withstand heat, goggles, and aprons.
- Ensure that the melting area is well ventilated to prevent the buildup of harmful fumes and gases.
- Keep a fire extinguisher close by in case of an emergency.
- Never leave the melting furnace unattended while it’s in operation.
- Avoid wearing loose clothing or jewelry that can get caught in the furnace or machinery.
- Be mindful of the weight and stability of the ladle or crucible when handling molten steel.
- Have a first-aid kit on hand in case of burns or other injuries.
Conclusion
Melting stainless steel using an induction furnace is an efficient and reliable process that produces high-quality results. With the right equipment and safety precautions, it’s possible to melt stainless steel quickly and with minimal waste. Whether you’re melting stainless steel for industrial or artisan purposes, the process requires attention to detail and a commitment to safety. By following the steps outlined in this article, you can ensure that your stainless steel melting process is successful and safe. Remember to always follow the manufacturer’s instructions and safety guidelines when operating the furnace to ensure your safety and the quality of the melt.
Are you interested in learning more about melt extracted stainless steel fiber? Contact us today to secure an expert consultation!
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