What is Induction Furnace?
An induction furnace is an electrically powered furnace that uses electromagnetic induction to melt and heat metal. The furnace passes an alternating current through a copper tubing coil, which generates a magnetic field. When metal is placed inside the coil, the magnetic field causes electric currents called eddy currents to form in the metal, which heats it up and eventually melts it.
Why Choose Us
Production equipment
We produce a complete set of equipment, induction power supply, furnace body, and cooler for 100kw-20000kw medium frequency induction melting furnaces and induction heating furnaces, which can meet the casting, forging, and heat treatment needs of metals in different fields.
Our Company
The company not only has industry-leading technological level, but also has a complete pre-sales and after-sales service process. At present, the cumulative number of customers served by the company has exceeded 3000, and our good reputation among customers has enabled us to continuously expand into new customers.
Production Market
We have successfully won the trust and support of over 2000 customers worldwide, and have successfully sold to multiple countries and regions such as Southeast Asia, the Middle East, North Africa, Eastern Europe, Central Asia, and South America, becoming the preferred brand for many metal processing enterprises in these regions.
Our Certificates
In 2023, Hexinda Electric Furnace received a Copyright Registration Certificate for its computer software used in manufacturing, processing, and production operation control systems. Additionally, we hold two Utility Model Patent Certificates.
An induction furnace is an energy-efficient, clean-melting furnace used to melt all type of metals such as steel, iron, copper, zinc and aluminum.
Because an induction furnace does not require an arc, it is easy to regulate the melting heat, making it a suitable option for preserving valuable alloying elements. Moreover, this type of furnace generates a minimal amount of waste and pollutants, contributing to an overall reduction in carbon footprint.
During the operation of an induction furnace, refractory materials provide an essential barrier between molten material and the furnace induction system. The diversified refractory materials supplied by Saint-Gobain Performance Ceramics & Refractories protect the furnace coil from ferrous and non-ferrous molten metals inside the vessel at high temperature. This protected lining is thus fundamental as a protective barrier against the most intense physical, thermal, and chemical stresses occurring during the operation.
Principles of an Induction Furnace
Faraday's Law describes how a magnetic field interacts with an electric circuit to generate an electromotive force, a phenomenon known as electromagnetic induction.
Therefore, once a piece of conducting material — such as a charge or load within a furnace — is placed in an alternating magnetic field, an electric current is generated. As the current flows, it meets resistance and dissipates energy as heat via the Joule Effect.
Types and Advantages of Induction Furnace
Before you install an induction furnace in your foundry, it's important to understand how they operate. An induction furnace works by transferring heat energy via a high-voltage primary coil that induces a high current, a low voltage, or a secondary coil. These types of furnaces are great for melting a wide array of metals while maintaining a low level of melt loss.
There are two main varieties of these furnaces: coreless and channel.
Coreless: Coils are the primary heating component in a coreless furnace. The coil — from which this furnace gets its name — is created from highly conductive copper tubing and is wound into a helical coil before being placed inside a steel casing. To mitigate the risk of overheating, the coil itself is water-cooled via a recirculating tower. The frequencies used can vary between 50 cycles and 10,000 cycles per second (known as mains frequency and high frequency, respectively). The higher the frequency, the greater the amount of power that can be applied to the furnace.
Once the material has reached a molten state, the interaction between the magnetic field and electrical currents produces a stirring reaction that helps mix alloys and distribute temperature evenly throughout.
Channel: A channel induction furnace is made up of a refractory steel casing that holds the heated metal. Attached to this is the primary induction unit. This unit contains an iron core, around which an induction coil is wrapped. The heat generated causes the metal to circulate into the main well, creating its own stirring action — similar to the one mentioned above. These types of furnaces are good for melting alloys with low melting points or as a holding compartment for metals with higher melting points.
The Benefits of Induction Furnaces
Regardless of the type of induction furnace your foundry needs, there are specific benefits that this type can offer which other alternatives simply can't match. Induction furnaces are good for melting metals such as gold and silver, copper, aluminum, silicon, brass, and zinc. Steel and iron can also be melted for industrial use. They don't require much space to function, making them great for foundries of all sizes. They are also more eco-friendly than some other alternatives. They are highly energy-efficient, which means they won't detrimentally impact a companies bottom line when it comes to energy consumption, and they are great for a foundry that wants to lessen their environmental footprint when it comes to production. They have less burn loss and produce higher yields overall, as well as making automation easier than alternatives.
When considering what furnace is best for your foundry, consider the benefits of induction melting and if an induction furnace would be right for you. Not only can they save on space, but they reduce loss, save energy, and can melt the most commonly used types of metal.
5 Popular Applications Induction Furnaces Are Known For




Approximately 16% of the world's steel is used for mechanical equipment such as robotics and manufacturing. Yet, one of the first steps to producing a useful steel product in many industries is melting.
Induction melting furnaces provide fast melting rates at maximum efficiency. This allows companies like yours to get the best metal quality possible for your products.
But what are the different applications that induction melting furnaces can be used for? Here are five of the many applications that induction furnaces can be used for in your melting, heating, holding, and pouring operations.
Investment Casting. Induction melting is often used for investment casting because they come in a wide variety of air and vacuum furnaces. These furnaces work great for nearly all metals.
Precious Metals Melting. Steel is precious for many, but induction furnaces can also be used to melt precious metals such as platinum group metals. This allows them to be refined and used for jewelry manufacturing.
Copper Melting. Induction furnaces can be used to melt custom castings or casting large bronze structures. They're built to provide the melting you need for most copper applications with low metal loss and precise temperature control.
Alloy Manufacturing. Induction furnaces are popularly used in alloy manufacturing for optimal uniformity and flexibility. Those in alloy manufacturing companies can count on induction furnaces to provide them with the correct amount of induction stirring each and every time so every product comes out exactly the same.
Aluminum Melting. Aluminum melting is another popular application used for induction melting. Because induction furnaces are energy efficient, they're considered optimal for converting alumina into pure aluminum and then into aluminum alloys. This is because this process consumes a lot of energy and so the more energy that can be saved the better.
Induction Furnace Daily Maintenance
An induction furnace is an alternating current (AC) electric furnace in which the primary conductor is coiled and generates a secondary current by electromagnetic induction that heats the metal charge.
Furnace Components
A coreless induction melting furnace consists of a refractory lining to hold the material to be melted that is surrounded by a helical coil made of hollow electrolytic copper tubing. For protection, the coil is usually housed in a box made of high-strength thermal board or a fabricated steel shell, sometimes with electromagnetic shunts for shielding to prevent stray heating. The furnace may be stationary such that the crucible is picked up and carried away for pouring the molten metal or may be supported on trunnions for tilt pouring.
The refractory lining has the ability to retain its strength and shape at high temperatures and may consist of a rammed lining or a crucible. A rammed lining is made up of a mixture of course- and fine-grained oxide aggregates, with fluxes added for bonding. It is installed using a melt-out or removable form to create the cavity to hold the molten metal. A crucible is a preformed containment vessel for molten metal and may be made of similar materials as rammed linings, or conductive materials like silicon carbide or machine graphite.
A power supply converts the main's voltage and frequency to that which is required for proper operation of the furnace. Typical output frequencies range from 50 Hz to 10 kHz, at power levels from 5 kW to 16.5 MW. Today, most induction power supplies use solid-state technology, based on thyristors (SCRs) or IGBTs. The power supplies are usually water-cooled, as are the furnace coils. Cooling water is typically recirculated between the equipment and an open or closed cooling tower, to remove the heat.
The current in the induction coil creates the magnetic field, which in turn induces a current in the charge. The interaction of the magnetic field and the current in the charges creates the electromagnetic forces that create the stirring. The stirring has a "figure eight" pattern with metal flowing up the center and down the sides on the top half of the bath (opposite directions on the bottom half of the bath) with the characteristic inverse meniscus. The stirring action within the bath is important as it helps with mixing of alloys and melting of turnings as well as homogenizing of temperature throughout the furnace. However, excessive stirring can increase gas pick up, lining wear, and oxidation of alloys.
Most modern-day induction power supplies are frequency converters, consisting of a rectifier and an inverter. The rectifier converts AC to DC and the inverter converts DC back to AC. The purpose of doing this is to be able to control the power level and in most cases, operate the furnace at a frequency that's different from the line frequency.
Most induction power supplies have a single output, sometimes with switches to be able to connect multiple furnaces, but not at the same time.
A multiple or dual output power supply allows two furnaces to be powered at the same time, so you could melt at high power on one furnace while you're holding at low power on the other one.
Ancillary Systems
Many ancillary systems come into play with an induction furnace.
The first is the water pumps. There are many different types of configurations for pumps, inside and outside of the unit. The idea is to pump enough water to cool the equipment. The power supply and furnace are water cooled.
Daily Maintenance
Providing the most efficient operation of induction melting and holding equipment and maximizing its useful service life are worthy goals for a foundry maintenance program. The most important goal, however, is the safe operation of equipment and the protection of workers and visitors. Poor, improper, or delayed maintenance is a major contributor to accidents involving induction equipment in foundries.
Following Are Daily Furnace Maintenance Tasks.
1) Check refractory lining before melting. When checking the refractory linings, you are looking for signs of finning, spalling, erosion, or build-up. Linings can fail for several reasons, including:
Wrong refractory material was used for a particular application.
Improper installation.
Lining allowed to wear too thin.
Physical shocks or mechanical stress damage the lining.
Excessive temperatures or thermal shock (damage).
Slag/dross build-up.
The furnace's refractory lining is all that stands between a worker and the molten metal in the furnace. Therefore, it is important that the lining is selected, installed, and sintered properly. The lining should be inspected frequently and removed immediately when worn out or damaged. The safety of those operating the furnace and who are in the vicinity depends on how well every lining is installed and maintained.
2) Check fault/limit indicating lights. The circuit monitor display will tell you that the system is ready for operation (no lamps lit). First, set the power control knob to Zero. Then press the green "ON" button to start the inverter. The green LED will illuminate indicating "INVTR ON." Check the circuit monitor to make sure that no new alarms have appeared and to confirm the inverter is running. Turn the power control knob to the desired kilowatts.
3) Check hydraulic fluid level. During daily maintenance, the operator is looking for the level and temperature of the hydraulic fluid.
4) Check internal and external water levels and look for leaks. Power lead and hose connections need to be checked for leaks during the preventive maintenance procedure. Water leaks can cause coil arcing, resulting in short coil life.
5) Check operation of ground/leak detector. The ground/leak detector comes on in the tripped mode. It must be reset so it can be tested, and the operator will need to reset it again after testing. First, press "reset" to ready the ground leak detector (GLD) for operation. Then test the GLD to ensure it is functioning properly. Hold the TEST button until the GLD Current Trip Red LED illuminates (7-12 seconds).
6) Keep work area around furnace and power unit clean. On a daily basis, make sure the work area is clean—both around the furnace and the power unit.
Our Factory
Shandong Hexinda Electric Furnace Co., Ltd. was established in 2014. After 10 years of development, the company has become a production-oriented company that integrates research and development, production, sales, and after-sales service, and has passed ISO9001 quality system certification. We produce a complete set of equipment, induction power supply, furnace body, and cooler for 100kw-20000kw medium frequency induction melting furnaces and induction heating furnaces, which can meet the casting, forging, and heat treatment needs of metals in different fields. The company not only has industry-leading technological level, but also has a complete pre-sales and after-sales service process.

FAQ
We're well-known as one of the leading induction furnace manufacturers and suppliers in China. If you're going to buy customized induction furnace, welcome to get more information from our factory.
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