Alonics, Ltd. List of Products and Services

We would like to introduce examples of the application of induction heating in the manufacturing of optical fiber cables. Fast heating times and temperatures below 260°C (500°F) are desired for soldering heat-sensitive optical fibers. However, it is difficult to achieve this with commonly used heating methods such as resistance heating and hot air, making automation for high-speed production not easy. *For more details, please download the PDF or feel free to contact us.*

• Other heating equipment

Induction heating, which provides precise and reproducible heat to very small areas, helps researchers advance their studies, from cancer research to material testing for improving manufacturing methods. *For more details, please download the PDF or feel free to contact us.*

• Other heating equipment

Induction heating is also utilized for thermal treatment that raises and manages the temperature of nanoparticle solutions in vivo and in vitro. High-frequency induction heating devices that use induction heating power supplies offer adjustable output levels from 1kW to 10kW and configurable frequencies from 150kHz to 400kHz, according to the power and frequency needs required for research. The core magnetic field strength can reach up to 125kA/m. 【Nanotechnology Kit】 The induction heating nanotechnology kit includes the following: ■ Induction heating power supply EASYHEAT: 1kW–10kW, frequency 150kHz–400kHz ■ Three coils designed for thermal therapy: inner diameters: 1", 2.5", 4" ■ Optical fiber temperature sensor (with optional controller) ■ Serial data link cable for PC connection ■ Starter kit: plastic and glass vials, insulating paper *For more details, please download the PDF or feel free to contact us.

• Other heating equipment

We would like to introduce a case study of the application of induction heating in a needle manufacturing company. The manufacturing process necessary to maintain the strength of the needle is "quenching." Each needle manufacturer has its own know-how for quenching that is suitable for their specific needles, but induction heating (IH) can apply that know-how accurately and improve yield. At Alonix, we are working on quenching needles by leveraging the characteristics of induction heating, which allows for pinpoint heating, and we have a proven track record even in injection needles where high precision results are required. Induction heating can not only be used for quenching needles but also for welding the needle hub of injection needles. It can instantaneously heat ultra-fine injection needles (SUS pipes) and weld them to the needle hub. Induction heating enables non-contact and highly reproducible heating in a short time. *For more details, please download the PDF or feel free to contact us.

• Other heating equipment

We would like to introduce examples of the application of induction heating in the manufacturing of medical devices. Induction heating, which heats small areas with pinpoint accuracy and without contact, is suitable for the medical field where precision and cleanliness (sterility) are particularly required, such as in the processing of catheter tips, welding of injection needles, brazing of small fixtures, annealing, and the welding of metals to plastics. 【Typical Medical Applications [Heating Temperature/Time] Examples】 ■ Annealing in inert gas (steel tube): 1093°C / 15 seconds ■ Adhesion (plastic handle of surgical scalpel): 232°C / 2 seconds ■ Brazing (medical heat sensor probe): 704°C / 60 seconds ■ Hardening (steel surgical scalpel): 1093°C / 2 seconds ■ Heating and forming (steel mandrel (Teflon tube)): 371°C / 2.7 seconds ■ Plastic reflow (catheter tube): 121°C / 3.5 seconds *For more details, please download the PDF or feel free to contact us.

• Other heating equipment

We will introduce examples of the application of induction heating in aluminum brazing. Aluminum is a lightweight and strong material, used in various parts such as piping components and automotive parts. However, due to its high thermal conductivity and low melting point, it has been said that thermal processing is difficult. ■ High thermal conductivity The thermal conductivity is about three times that of iron. When heating only the desired area, heat can also transfer to other areas, causing distortion. ■ Low melting point The melting point of aluminum is 660°C. In brazing, the melting points of commonly used silver brazing and copper brazing are close to this, requiring advanced skills from experienced workers for aluminum brazing. By using induction heating, which excels in temperature control, and brazing materials specifically designed for aluminum brazing, efficient aluminum brazing becomes possible. *For more details, please download the PDF or feel free to contact us.*

• Other heating equipment

We would like to introduce examples of the application of induction heating in tube and pipe processing. Induction heating, known for its reliability and reproducibility, is effective for heat treatment of tubes and pipes. High-frequency induction heating enables efficient heat treatment for tubes and pipes, including hot bending, stress relief welding, coating, and brazing. *For more details, please download the PDF or feel free to contact us.

• Other heating equipment

Here are some examples of the application of induction heating in the aerospace industry. In the aerospace industry, engine parts are expensive, making repair much more economical than replacement. Traditionally, brazing has been done using batch-type vacuum furnaces when applying heat for repairs, but induction heating can be utilized in various scenarios. 【Examples of Applied Heating [Temperature/Time]】 ■ Turbine engine fan blades: 982°C/5 minutes, welding ■ Inconel billets: 260°C/12 seconds ■ Titanium blades: 260°C/4 minutes, melting and expelling wax from the inside *For more details, please download the PDF or feel free to contact us.

• Other heating equipment

Here are some examples of the application of induction heating in the manufacturing of fasteners (bolts, screws, rivets, etc.). In the production of industrial fasteners, processes such as heading and threading often utilize heated forming. Traditionally, heating was done using gas furnaces or flames, which were inefficient in terms of time and energy, and there was variability in precision due to the skill level of the operators. By using induction heating equipment, the necessary heating can be provided efficiently, accurately, and with maximum reproducibility. *For more details, please download the PDF or feel free to contact us.*

• Other heating equipment

Here are some examples of the application of induction heating in the automotive industry. By using induction heating for the protective coating applied to automotive brake rotors, energy costs and valuable production time can be saved. Additionally, compactly designed induction heating devices are easy to integrate into production lines. 【Examples of Applied Heating [Temperature/Time]】 ■ Brazing in an inert gas (hydraulic hose assembly): 1204°C/7 seconds ■ Bonding (vinyl trim): 260°C/7 seconds ■ Bonding (rubber gasket and steel gas intake manifold): 160°C/8 seconds ■ Hardening (rotating shaft): 927°C/2.5 seconds ■ Copper brazing (oil suction assembly): 1010°C/15 seconds ■ Curing (adhesion of aluminum auto trim): 260°C/10 seconds *For more details, please download the PDF or feel free to contact us.

• Other heating equipment

Here are some examples of the application of induction heating in the EV manufacturing process. - Shrink fitting of the housing and stator The stator is fitted into a lightweight aluminum housing through shrink fitting. The aluminum housing is heated to 200-300°C due to the interference fit between the housing and the stator, allowing the aluminum to expand and making it easier to place the stator inside the housing. - Shrink fitting of the steel shaft inside the rotor The rotor inside the stator of the electric motor is made of laminated steel to suppress heat generation from eddy currents during operation, as it is difficult to remove the heat generated. Induction heating coils can be designed to heat the steel from the outside or the inside. - Drying of the steel rotor After being machined to the tight tolerances required for efficient motor operation, the steel rotor assembly is heated by induction heating to remove the machining fluid. Induction heating allows for precise control of the rotor's temperature through closed-loop control. There are several other application examples as well. *For more details, please download the PDF or feel free to contact us.

• Other heating equipment

Here are some examples of the application of induction heating in the automotive industry. Induction heating, known for its reliability and reproducibility, provides manufacturing processes with high precision and no variation in many heat-utilizing treatments such as brazing, soldering, hardening, and shrink fitting. Additionally, the compact design of induction heating equipment makes it easy to integrate into production lines. [Examples of Heating [Temperature/Time]] ■ Brazing in an inert gas (hydraulic hose assembly): 1204°C/7 seconds ■ Joining (vinyl trim): 260°C/7 seconds ■ Joining (rubber gasket and steel gas intake manifold): 160°C/8 seconds ■ Hardening (rotating shaft): 927°C/2.5 seconds ■ Copper brazing (oil suction assembly): 1010°C/15 seconds ■ Curing (adhesion of aluminum auto trim): 260°C/10 seconds *For more details, please download the PDF or feel free to contact us.

• Other heating equipment

Ambrell's EASYCOIL is a flexible induction heating coil that is ideal for heating large and irregularly shaped workpieces, which is difficult with traditional copper coils. The 7.6m (25-foot) flexible coil can be used in combination with the EKOHEAT system (up to 250kW, 5-45kHz). It can be connected with up to five coils and can be easily wrapped around the workpiece shape, making installation and setup straightforward. With a fiberglass coating, it offers excellent heat resistance and can accommodate a wide range of heating from low temperatures to beyond the Curie point. If the surface temperature of the heating target exceeds 427°C, ceramic insulation materials can also be utilized. It is effective in various applications such as preheating before welding, annealing, stress relief, mold heating, and decomposition heating.

• Heating device

The Optris PI 640i MO2X is an infrared thermal imaging camera that boasts a high resolution of 640×480 pixels and a spatial resolution (IFOV) of 8μm. Equipped with a newly developed 2x microscope lens, it enables accurate temperature distribution measurement of small targets such as electronic components and printed circuit boards. The temperature measurement range is from -20 to 900°C (with sub-range settings available), and it supports high-speed process monitoring with a high frame rate of 32Hz (up to 125Hz). It features manual focus, interchangeable optics, a USB 2.0 interface, a robust IP67 design, and comes standard with the free PIX Connect analysis software. It achieves high-precision infrared temperature measurement for a wide range of applications, from research and development to manufacturing sites.

• Thermography

Induction heating can efficiently heat only the desired parts, significantly reducing energy waste and increasing thermal efficiency. Additionally, there is no need for preheating, allowing for immediate heating when needed, which also minimizes energy consumption during standby. Since the components themselves generate heat through non-contact heating, there is less wear on the equipment, leading to reduced maintenance costs. In this way, induction heating has the effect of significantly lowering the overall running costs of the production process through improvements in energy efficiency, production efficiency, and maintainability. By automating the heating process, it can greatly reduce the labor required for traditionally manual processes, contributing to cost reduction from the perspective of labor savings. Thus, the introduction of induction heating promotes the automation and labor-saving of production processes, achieving both labor cost reduction and productivity improvement.

• Heating device

Induction heating (IH) is a non-contact heating method that directly generates heat without using flames to heat conductive materials such as metals and carbon. Since it does not use flames or fuel, there are no exhaust gases or smoke produced, keeping the air in the workplace clean. This helps to suppress temperature increases within the workspace, creating a comfortable working environment. Additionally, unlike heating methods that involve contact with a heat source that itself generates heat, the workpiece itself generates heat, which also contributes to the suppression of temperature rises in the workplace. As a safe heating method that does not use open flames, the risk of fire is significantly reduced, allowing for safe operation even in environments where open flames are restricted. The ability to finely control the heating range and temperature allows for efficient heating of only the necessary areas, preventing energy loss and unnecessary heat generation. This results in a lower overall temperature in the workplace, reducing the air conditioning load during the summer.

• Heating device

Induction heating (IH) is a non-contact heating method that directly generates heat without using flames to heat conductive materials such as metals and carbon. **Benefits of Induction Heating** - **Improvement of Cycle Time/Takt Time** The output of induction heating is consumed directly on the workpiece as self-generated heat, allowing for rapid temperature rise. - **Improvement of Yield and Ensuring Reproducibility** Due to electrical control of the heating, the reproducibility of the heating process is enhanced. With high responsiveness, fine temperature control is also possible, making it useful even for heating processes that require precise temperatures, such as aluminum brazing. - **Improvement of Workpiece Quality** The shape of the heating coil allows for control over the heating area. Additionally, rapid heating reduces heat conduction to areas that do not require heating, which is expected to improve quality. - **SDGs/Decarbonization** By directly transmitting energy to the object being heated, thermal losses are minimized. Efficiency can reach up to 90-95%, significantly reducing energy consumption and carbon emissions in the manufacturing process.

• Heating device

Induction heating (IH) is a non-contact heating method that uses no flames to heat conductive materials such as metals and carbon. By generating eddy currents in the heating target, the oscillated output is directly consumed as self-heating due to Joule heating on the workpiece. This allows for rapid temperature rise at a pace that is difficult to achieve with indirect heating through heat conduction from a heat source like flames. The time required to reach the target temperature is determined by the balance of the material and size of the target, the target temperature, the heating range, and the output of the induction heating power supply used.

• Heating device

Induction heating is not a new technology, but it is a green technology. It does not consume fossil fuels and does not emit harmful substances or carbon dioxide. 【Features as a Green Technology】 ■ High speed, high efficiency - Fast heating due to direct heating (self-heating of the workpiece) - Heats only the necessary amount when needed ■ Localized heating - Can heat only the required areas ■ Clean - No use of open flames, no gas generation - The workpiece itself generates heat, making it difficult for the surrounding environment to warm up (improving the working environment) ■ Energy-saving, decarbonization - Low CO2 emissions due to high efficiency (vs fossil fuel methods) - Reduced running costs Compared to gas heating, it provides a safer, cleaner, and more comfortable working environment. Compared to torch heating, induction heating is flame-free and generates less heat in the working environment. In addition to its environmental advantages, induction heating is beneficial for workers and companies as it does not produce smoke, waste heat, harmful emissions, or noise. Many processes that generate emissions, such as the following, can be converted to induction heating: ■ Flame preheating ■ Gas combustion furnace heating ■ Welding torch ■ Torch brazing ■ Flame melting ■ Flame hardening ■ Shrink fitting

• Heating device

The "Wideband RF Amplifier Module Forte-50" is an extremely robust amplifier module suitable for ultrasonic applications, various tests, research and development, and more. It can be used as a signal source with most commonly used signal generators, frequency synthesizers, and sweep generators, demonstrating excellent waveform reproduction for AF, FM, SSB, pulse, and complex modulated waves. 【Features】 ■ 250 kHz to 50 MHz ■ Class A amplification across the entire bandwidth *For more details, please refer to the catalog or feel free to contact us.

• Amplifier

The "Wideband RF Power Amplifier GS50" is designed and manufactured as a product that embodies the high quality, durability, and robustness that is also the policy of E&I. It is a "high-efficiency RF power amplifier" that can be safely used in a variety of applications such as ultrasound, various tests, and research and development. 【Features】 ■ 20kHz – 1.5MHz ■ GaN Switch Mode Technology ■ Instantaneous Bandwidth (IBW) ■ V/I Sample Port Included ■ Compact Design ■ Higher Power Density ■ Solid-State Reliability *For more details, please refer to the catalog or feel free to contact us.

• Amplifier

Optris's non-contact thermometers come in various series with different measurement methods, including spot-type, video-based visible aiming, and thermal cameras. They offer a range of detection wavelengths suitable for various materials such as resin, glass, metal, and circuit board component inspection. Some models also feature dual-wavelength radiation thermometers. They are suitable for both experimental/research applications and industrial uses.

• Radiation thermometer

Induction heating (IH) is a non-contact heating method that uses no flames to heat conductive materials such as metals and carbon. **Benefits of Induction Heating** - **Improvement of Cycle Time/Takt Time** The output of induction heating is consumed directly on the workpiece as self-heating, allowing for rapid temperature rise. - **Improvement of Yield and Assurance of Reproducibility** Due to the electrical control of heating, the reproducibility of the heating process is enhanced. - **Improvement of Workpiece Quality** The shape of the heating coil allows for control of the heating area, and rapid heating reduces heat conduction to areas that do not require heating, leading to quality improvements. - **Improvement of Workplace Environment** Unlike heating methods that burn combustible materials, it does not produce combustion byproducts, thus reducing the emission of pollutants. The absence of open flames and high-temperature surfaces of furnace bodies helps to minimize the rise in ambient temperature. - **SDGs/Decarbonization** By directly transmitting energy to the heated object, thermal losses are minimized. Efficiency can reach up to 90-95%, significantly reducing energy consumption and carbon emissions in the manufacturing process.

• Heating device

By adopting high heat-resistant, low-loss SiC modules, we have simplified the water cooling circuit and reduced the required flow rate, achieving a 20% reduction in size compared to the conventional EKOHEAT series and lowering the failure rate. Additionally, we have incorporated Modbus TCP alongside the traditional RS485 and Modbus RTU, enabling high-speed communication to support Industry 4.0.

• Heating device

CSvision is a dual-wavelength infrared radiation thermometer that provides reliable measurement data even when the visibility of the measurement target is low, making it ideal for temperature management in difficult-to-access metal processing. With video aiming, laser aiming, and motorized focus, it allows for accurate and easy marking of measurement targets in hard-to-reach locations. Additionally, the two-stage brightness reduction filter ensures optimal visibility even for bright objects.

• Radiation thermometer

We will manufacture IH automatic machines that significantly reduce the burden of conventional heat treatment, starting with applications for brazing. By utilizing induction heating, we provide easy control and safe operation in a compact configuration. - High speed: Rapid heating due to the self-heating of the workpiece - High controllability: Startup time of 5 milliseconds, high-speed automatic frequency tuning compact induction heating power supply - Clean heating: Non-contact direct heating using the IH (induction heating) method. No flames are used, and no exhaust gases are produced. - Energy-saving: Power consumption occurs only during heating time; there is no need for constant output. - Compatible with low-resistance materials: Heating of aluminum and copper is also possible. - Temperature feedback control: Temperature control using a temperature controller allows for joining of dissimilar metals, among other applications.

• Heating device

Broadband phased array system manufactured by E&I Corporation, USA.

• power supply

The induction heating technology by EKOHEAT contributes significantly to reducing heating energy with high power conversion efficiency and a power factor of 0.9 or higher. Induction heating, which is non-contact and does not use flames, minimizes energy waste by concentrating energy only on the area of the workpiece that needs to be heated.

• Heating device

The induction heating power supply "EASYHEAT" comes in six models ranging from 1.2kW to 10kW, achieving highly reproducible and ideal non-contact heating. The frequency range is broad, from 150kHz to 400kHz, and it features an auto-tuning function that continuously tracks the resonant frequency within the entire frequency range not only during heating but also when the heat is on. All models are designed with a convenient remote work head type, with a standard cable length of 3.5m (extendable). This allows for flexible use of installation space as the power supply and work head can be set up separately. It is equipped with a programmable heating controller that can save four types of heating recipes.

• Heating device

The broadband RF power amplifier manufactured by E&I in the United States reproduces the broadband RF power amplifier that was well-known for its durability, ease of use, and high reliability from ENI. E&I, established by former engineers of ENI, designed this new device while maintaining ENI's excellent features, aiming for further miniaturization and high performance.

• Other laboratory equipment and containers