Introduction
This article offers an in-depth exploration of heating elements. By delving into the following aspects, readers will gain a thorough understanding:
Table of Contents
Heating Elements
1: Unraveling the Heating Element
A heating element is a remarkable material or device that transforms electrical energy into heat via a process known as Joule heating. When an electric current courses through a conductor, the electrons or charge carriers collide with the atoms or ions of the conductor. These atomic-level collisions generate friction, which manifests as heat. This heat production is quantified by Joule’s first law (or Joule-Lenz law), expressed as either or ². Here, the amount of heat generated hinges on the current, voltage, and the resistance of the conductor. Resistance plays a pivotal role in designing heating elements.
Joule heating occurs to varying extents in all conductive materials, with the exception of superconductors. Materials with low electrical resistance tend to produce less heat as charge carriers flow more freely through them. In contrast, those with high resistance generate more heat. Superconductors allow electrical current to pass without any heat production. Typically, the heat generated by conductors is regarded as an energy loss, like the unwanted heating in electrical equipment known as copper loss, which doesn’t contribute to useful work.
Electrical heating elements are highly efficient in converting electrical energy into heat, with nearly 100% of the supplied energy being transformed into thermal energy. They may also emit energy in the form of light and radiation. However, this ideal efficiency pertains mainly to resistors. Minor losses can occur due to the material’s inherent capacitance and inductance, which convert electrical energy into electric and magnetic fields respectively. Moreover, the overall system efficiency can be affected by heat dissipation into the external environment from the process fluid or the heater itself. Thus, for optimal utilization of the generated heat, a well-insulated heating system is essential.
2: Properties that Define Heating Elements
Nearly all conductors produce heat when an electric current passes through them, yet not all are suitable for use as heating elements. The ideal heating element material must possess a specific blend of electrical, mechanical, and chemical properties.
Resistivity: To generate heat, the heating element requires adequate electrical resistance. However, it shouldn’t be so high that it becomes an insulator. Electrical resistance is calculated as the resistivity multiplied by the length of the conductor divided by the conductor cross-section. For a given cross-section, a material with high resistivity is used when a shorter conductor is desired.
Oxidation Resistance: Heat generally accelerates oxidation in both metals and ceramics. Oxidation can consume the heating element, reducing its capacity or compromising its structure, thereby limiting its lifespan. For metallic heating elements, alloying with an oxide former helps form a passive layer to resist oxidation. Ceramic heating elements commonly have protective oxidation-resistant scales like SiO₂ or Al₂O₃. Some heating element types, such as graphite, are not suitable for use in oxidizing environments and are typically used in vacuum furnaces or those with non-oxidizing atmosphere gases like H₂, N₂, Ar, or He, where the heating chamber is evacuated of air.
Temperature Coefficient of Resistance: The resistivity of the material changes with temperature. In most conductors, as the temperature rises, so does the resistance. This phenomenon has a more pronounced effect on certain materials. A higher temperature coefficient of resistance is often utilized in heat-sensing applications. For heat generation, a lower value is usually preferable. However, in some cases where the change in resistance can be accurately predicted, a sharp increase in resistance can be advantageous to deliver more power. To account for the changing resistivity, control or feedback systems are employed.
Mechanical Properties: Rigid heating elements can deform when used at high temperatures. As the material approaches its molten or recrystallization phase, it weakens and deforms more easily compared to its state at room temperature. A good heating element can maintain its shape even at elevated temperatures. Dessutom, ductility is a desirable mechanical property, especially for metallic heating elements. It enables the material to be drawn into wires and formed into shape without sacrificing its tensile strength.
Melting Point: Besides the temperature at which oxidation significantly increases, the material’s melting point also restricts its operating temperature. Ceramics generally have higher melting points than metallic heaters.
Leading Heating Element Manufacturers and Companies include Backer Hotwatt, Inc., Ulanet™, Hi-Heat Industries, Inc., Tutco-Farnam, and National Element, Inc. (You can mouse over the company names to see their previews.)
3: Materials Used in Heating Elements
The material properties discussed earlier narrow down the selection to several key materials.
Nickel-Chromium (Ni-Cr) Alloy: Among the most commonly used materials for heating elements, nickel-chromium alloys are prized for their ductility, high resistivity, and resistance to oxidation even at elevated temperatures. Typically composed of 80% nickel and 20% chromium (though other compositions may be available from different manufacturers), these alloys are often formed into wires for use as heating elements, such as in hot-wire foam cutters. They can reach maximum heating temperatures of approximately 1,100 to 1,200°C.
Iron-Chromium-Aluminum (Fe-Cr-Al) Alloy: Often known by the trademark Kanthal, ferritic iron-chromium-aluminum alloys usually consist of 20 to 24% chromium, 4 to 6% aluminum, with iron making up the remainder. These alloys are favored for their pliability and lower density compared to nickel-chromium alloys. They can achieve higher temperatures, reaching around 1,300 to 1,400°C. Although they tend to be less expensive due to the lower price volatility of iron compared to nickel, they have reduced strength at elevated temperatures compared to nickel-chromium alloys. They can be enhanced through powder metallurgy, where the alloy ingot is ground into a powder, compressed into a die, and sintered or hot-pressed in a controlled atmosphere. Dispersoids are added to improve mechanical properties, increasing strength and toughness at higher temperatures.
Molybdenum Disilicide (MoSi₂): A refractory cermet (a ceramic-metallic composite), molybdenum disilicide is predominantly used as a heating element material. It is well-suited for high-temperature furnaces due to its high melting point and excellent corrosion resistance. MoSi₂ heating elements are manufactured through various energy-intensive methods, including mechanical alloying, combustion synthesis, shock synthesis, and hot isostatic pressing. They can reach temperatures up to 1,900°C. However, they have drawbacks such as low toughness at ambient temperatures and susceptibility to high-temperature creep. At room temperature, MoSi₂ is brittle and requires careful handling. Toughness improves significantly at its brittle-ductile transition temperature of around 1,000°C, but a higher creep rate can cause deformation at high temperatures. The most common MoSi₂ element design is the 2-shank hairpin type, which is often suspended from the furnace roof and positioned around the furnace walls. Other configurations are available and are frequently combined with ceramic insulation formers to provide both mechanical support and thermal insulation in a single package.
Silicon Carbide (SiC): Silicon carbide heating elements are made from a ceramic produced by recrystallizing or reaction bonding SiC grains at temperatures above 2,100°C. These elements are typically porous (8-25%) allowing the furnace atmosphere to interact through the material. Over time, the heating element may undergo gradual oxidation, which increases its electrical resistance in a process known as “aging.” To maintain consistent power output, a variable voltage supply is often used to incrementally raise the voltage as the element ages. This aging process eventually limits the heating element’s lifespan and performance. Silicon carbide is ideal for high-temperature applications due to several key properties. It lacks a liquid phase, meaning it doesn’t sag or deform due to creep at high temperatures, and no internal supports are necessary within the furnace. SiC sublimates directly at around 2,700°C, making it suitable for extreme conditions. Dessutom, it is chemically inert to most process fluids, has high rigidity, and a low coefficient of thermal expansion. Silicon carbide heaters can achieve temperatures of approximately 1,600 to 1,700°C.
Graphite: Graphite, a mineral with a hexagonal atomic structure composed of carbon, is an excellent conductor of both heat and electricity. It can generate heat at temperatures exceeding 2,000°C. At high temperatures, its electrical resistance increases significantly. It also withstands thermal shocks well and remains resilient without becoming brittle during rapid heating and cooling cycles. However, graphite has a notable drawback: it tends to oxidize at around 500°C, leading to material degradation with prolonged exposure. Consequently, graphite heating elements are predominantly used in vacuum furnaces, where oxygen and other gases are removed from the heating chamber to prevent oxidation of both the molten metals and the heating element itself.
Molybdenum, Tungsten, and Tantalum: Refractory metals like tungsten and molybdenum exhibit properties similar to graphite when used as heating elements. Among these metals, tungsten can operate at the highest temperatures but is also the most expensive. Molybdenum, while less costly and more commonly used, is still more expensive than graphite. Like graphite, these metals must be used in vacuum conditions because they have a strong affinity for oxygen, hydrogen, and nitrogen. They begin to oxidize at temperatures between 300 to 500°C.
Positive Thermal Coefficient (PTC) Materials: Typical PTC materials include rubber and ceramics. PTC rubber is commonly made from polydimethylsiloxane (PDMS) infused with carbon nanoparticles. PTC heaters are distinguished by their ability to regulate current flow through an increase in electrical resistance as temperature rises. This characteristic makes them safe and suitable for applications such as clothing. Initially, the heater draws full power and heats up due to its resistivity. As the temperature increases, the material’s resistance grows, eventually acting as an insulator. This self-regulation occurs without the need for an external feedback loop.
4: Types of Heating Elements
A heating system encompasses more than just the heating element. It also includes terminations, leads, insulation, packing, sheath, and seals. Heaters come in diverse forms and configurations to meet specific application needs.
Air Process Heaters: As the name implies, these heaters are used to heat flowing air. They consist of a heated tube or pipe, with one end for introducing cold air and the other end as the hot air exit. Coils of heating elements, insulated by ceramics and non-conducting gaskets, are placed along the walls of the pipe. They are typically used in high-flow, low-pressure applications such as heat shrinking, laminating, adhesive activation or curing, drying, baking, etc.
Cartridge Heaters: In this type, the resistance wire is coiled around a ceramic core, usually made of compacted magnesium oxide. Rectangular configurations are also available where the resistance wire coils pass three to five times along the length of the cartridge. The resistance wire or heating element is positioned near the walls of the sheathing material for maximum heat transfer. The sheath is usually made of corrosion-resistant materials like stainless steel to protect the internals. The leads are usually flexible, with both terminations located on one end of the cartridge. Cartridge heaters are used in die or mold heating, fluid heating (immersion heaters), and surface heating.
Rörformade värmare: The internals of tubular heaters are similar to those of cartridge heaters. The main difference is that the lead terminals are on the opposite ends of the tube. The whole tubular construction can be bent into different forms to suit the heat distribution required by the space or surface to be heated. They can also feature fins that are mechanically bonded onto the sheath surface to aid in effective heat transfer. Tubular heaters are as versatile as cartridge heaters and are used in similar applications.
Band Heaters: Designed to wrap around cylindrical metal surfaces or containers such as pipes, barrels, trummor, extruders, etc., band heaters feature bolted locking tabs to securely clamp onto the surface of the container. Inside the band, the heater is a thin resistance wire or ribbon typically insulated by a mica layer. The sheathing is made of stainless steel or brass. An advantage of band heaters is that they indirectly heat the fluid inside the vessel, preventing the heater from being subjected to chemical attack from the process fluid and also preventing possible ignition when used for oil and lubricant service.
Strip Heaters: These heaters are flat and rectangular in form and are bolted onto the surface to be heated. Their internals are similar to band heaters, but the insulating material, aside from mica, can be ceramics such as magnesium oxide and fiberglass. They are typically used for surface heating of dies, molds, platens, tankar, ducts, etc. They can also be used for air or fluid heating by having finned surfaces. Finned strip heaters are seen in ovens and space heaters.
Etched Foil Heaters: Also known as thin-film heaters, etched foil heaters have the resistive heating material etched and bonded onto a foil, usually made of aluminum. If more flexibility and tear resistance is required, the substrate can also be made of heat-resisting synthetic rubber or thermoplastic polyurethane (TPU). The tight spacing of the heating elements, an advantage of photochemical etching, enables even heat distribution with a larger heat density in small forms. Their applications are more specialized compared to conventional wire heaters and are usually seen in medical devices, electronics and instrumentation, aerospace, and clothing. One side can be lined with an adhesive layer for easy mounting.
Ceramic Heaters: These heaters use ceramics with high melting point, high thermal stability, high-temperature strength, high relative chemical inertness, and small heat capacity. Note that these are different from ceramics used as an insulating material. Due to their good thermal conducting properties, they are used to conduct and distribute heat from the heating element. Notable ceramic heaters are silicon nitride and aluminum nitride. They are commonly used for rapid heating as seen on glow plugs and igniters. However, when subjected to quick high-temperature heating and cooling cycles, the material is prone to cracking due to fatigue caused by thermal stresses. A special type of ceramic heaters is a PTC ceramic, which can self-regulate its power consumption to prevent it from becoming red hot.
Ceramic Fiber Heaters: In this type of heater, the ceramic fiber is used as an insulator to concentrate the heat into the surface to be heated to prevent system losses. A resistance wire is wound on one side of the ceramic fiber pad, and this side is bonded onto the surface to be heated, which can reach up to 1,200°C.
5: Factors to Consider When Selecting a Heater
Although heating elements generally operate on the same principle, their performance and service life are influenced by several factors. Key specifications for heaters include power or wattage, maximum operating temperature, type of process fluid, sheath material, and power supply (voltage and frequency). Dessutom, factors such as fluid flow and temperature control must also be considered to optimize performance.
Watt Density: Watt density is the heat delivered by a heating element per unit area. The appropriate watt density must be chosen for a specific application to fully utilize the service life of the heater. For a given wattage, both high and low-density heaters will deliver the same amount of heat but at different temperatures. High-density elements can reach much higher temperatures, which may lead to premature burning or failure of the element. When selecting a heating element, it is essential to check the manufacturer’s recommended watt densities for a particular application.
Temperature: The target operating temperature directly affects the watt density. There must be a balance between these two factors. In designing a process heater, the temperature is usually determined first as it is a process parameter required by the system.
Power Supply: The heating element must be able to operate with the available power supply. Check the voltage rating, which is typically 120V or 240V. When selecting a target wattage, verify the amperage produced. Be careful not to exceed the power supply circuit breaker tripping point or the ratings of the power cables.
Fluid Flow: Intuitively, stagnant fluids are easier to heat with a controlled temperature than flowing fluids. Air or other gases do not generally absorb heat quickly due to their low density. To address this, heaters with large surface areas are required. Finned surfaces and long wire coils (low-density heating elements) are common features of air heaters.
Temperature Sensor Location: Conventional heaters come with a temperature sensor and a controller. In most applications, the sensing device only measures the temperature of the process fluid. However, this does not usually represent the actual heating element temperature. Before installing the heater and the temperature sensing device, it is crucial to check if its location is appropriate for the heater unit. If the sensor is too far, the temperature reflected may be much lower due to heat dissipation and low heat transfer rate. This can lead to very high temperatures that can burn the heating element.
Corrosion: Corrosion can stem from the process fluid or the external environment. The sheathing material protects the heating element, leads, and insulators from chemical attack. Thus, the sheath must be able to maintain its strength in high temperatures while being resistant to corrosion. Widely used sheathing materials are stainless steel, brass, koppar, and other special alloys such as Monel and Incoloy. Moreover, the integrity of the sheath and terminal sealing must be sufficient for the application. For demanding applications, hermetic sealing is the best option to provide complete protection from the process fluid.
Conclusion
A heating element is a material or device that converts electrical energy into heat or thermal energy through the principle of Joule heating. The crucial characteristics of a heating element include sufficient resistivity, high oxidation resistance, low-temperature coefficient of resistance, high toughness, and high melting point. Widely used heating elements are nickel-chromium alloy, iron-chromium-aluminum alloy, molybdenum disilicide, and silicon carbide, followed by graphite and other refractory metals with generally higher oxidation rates. Besides the heating element, a heater comprises terminations, leads, insulation, packing, sheath, and seals. These heaters come in various forms and configurations to suit particular applications. Typical heater ordering specifications involve the power or wattage, maximum operating temperature, type of process fluid, sheath material, and power supply (voltage and frequency).
