In this guide, we’ll look into what magnetic lifting is, how magnetic lifting devices work, and how SimScale improves their design through its electromagnetics simulation tool.

What is Magnetic Lifting?

Magnetic lifting is a method used in mechanical and industrial settings to move heavy metal objects without direct contact. The lifting process is both safe and efficient, particularly when moving large metal items. This technique relies on magnets to create a strong magnetic field that securely attaches to ferrous (iron-containing) materials like steel (not stainless steel, due to its specific metal structure, which makes it non-magnetic).

Smaller magnetic lifting devices can lift between 200 and 400 pounds (~ 100 to 200 kg), suitable for lighter tasks. Larger models are capable of handling hefty loads ranging from 6,000 to 13,000 pounds (~ 2700 to 6000 kg), ideal for more demanding industrial operations. These devices are particularly useful for transporting steel plates, forgings, die castings, and other similar items commonly found in workshops, warehouses, and processing plants.

Types of Magnetic Lifting Devices

Magnetic lifting devices are essential tools in various industrial settings, each type designed for specific applications and capacities. Here are the main types:

Electromagnetic Lifting Magnet

Electromagnetic lifting magnets use an electrical current to create a magnetic field, enabling them to attract and lift ferromagnetic materials. They consist of a coil wound around a ferromagnetic core. When electricity flows through the coil, it generates a magnetic field, allowing the magnet to hold a load securely. The lifting capacity of these magnets can be adjusted by varying the electric current.

They differ from permanent magnets as they require a continuous power source to maintain their magnetic field. Electromagnetic lifting magnets are widely used in industries like scrap yards, manufacturing, and recycling.

Permanent Lifting Magnet

Permanent lifting magnets are built with permanent magnet materials like neodymium or ferrite. These magnets produce a constant magnetic field without needing an external power source. They’re typically used for lifting smaller objects and have a fixed lifting capacity.

These magnets include a block with a main body and a rotor, each containing two magnets. When these magnets are aligned, they generate a magnetic flux that reaches the metal objects to be lifted. One key advantage is their functionality, even during power failures. They’re often found in material handling, sorting, and assembly line applications.

Electropermanent Lifting Magnet

Electropermanent lifting magnets use a mix of permanent magnets and electromagnets to create a magnetic field. Once established, this magnetic field can be maintained without a continuous power supply but can also be turned on or off using an electrical control system. This feature makes them useful when power failure is a concern, such as in steel mills, shipyards, and heavy equipment manufacturing.

When the two sets have the same magnetic direction, the magnet can attract ferromagnetic workpieces. If their magnetic directions are opposite, they cancel each other out, and no magnetic force is generated for clamping. These magnets consist of two magnetic power sources: one set of high intrinsic coercive force (Hci) magnets and another set of low Hci magnets wrapped in electrical wire coils. Changing the direction of the current pulse in the coils can alter the direction of the magnets’ orientation.

Applications of Magnetic Lifting

Here are some examples of magnetic lifting applications in different sectors.

Optimizing Magnetic Lifting Performance through Electromagnetic Simulation

Electromagnetic simulation plays a crucial role in enhancing the performance and efficiency of magnetic lifting devices. Here are several ways in which simulation can optimize magnetic lifting performance.

Detailed Magnetic Field Analysis

Electromagnetic simulations can provide a detailed map of the magnetic field’s strength across the lifting surface. For example, they help in ensuring uniform field strength when lifting irregularly shaped objects like curved metal plates or cylindrical steel rolls.

Through magnetic lifting analysis, engineers can detect areas where magnetic flux leakage occurs, which could lead to reduced lifting efficiency or unintended attraction to nearby metal objects.

Load Capacity Optimization

By simulating various load types, including asymmetric and unevenly distributed loads, designers can optimize the magnetic lifter for a wide range of scenarios, such as adapting the lifter design to handle elongated steel beams safely.

It’s easy to simulate how different ferrous materials respond to the magnetic field, considering factors like:

• Material thickness
• Alloy composition
• Surface condition

Enhancing Operational Safety

Engineers can focus more on operational safety by simulating mechanical stresses and strains on the lifting device under different load conditions, such as analyzing the stress distribution on the lifting arm when lifting near the device’s maximum capacity. Magnetic lifter designers can assess the durability of the insulation and electrical wiring, particularly under extreme conditions like high temperature or humidity.

The multiphysics post-processing results, including electromagnetics and thermal analysis, can predict heat generation in the coils and other components during operation. For devices meant for continuous use, simulation helps design systems that can operate for extended periods without overheating.

Energy Efficiency and Sustainability

Engineers can test how quickly the magnetic field can be altered in response to changing conditions, which is crucial in automated systems where rapid adaptation to different loads is required. By adjusting parameters such as the number of coil turns, wire diameter, and coil dimensions, designers can achieve the desired magnetic field strength with lower energy input.
For example, a simulation might reveal that reducing the wire diameter in the coil while increasing the number of turns achieves the same lifting strength with less electrical power required.

Magnetic Lifting Simulation with SimScale Electromagnetics

SimScale’s electromagnetic simulation capabilities offer a comprehensive solution for engineers and designers working on magnetic lifting devices.

Browser-Based Electromagnetic Simulation

SimScale allows you to simulate the electromagnetic (EM) performance of electromechanical devices without the need for expensive hardware or complex software installations. You can run multiple simulations in parallel directly in your web browser. This approach significantly accelerates the design process, enabling faster innovation and real-time collaboration.

Magnetostatics Tool for Detailed Analysis

The Magnetostatics simulation tool is a core feature of SimScale for magnetic lifting applications. It enables engineers to perform various low-frequency electromagnetics simulations, such as analyzing:

• Magnetic flux density
• Magnetic field strength
• Linear magnetic permeability
• Non-linear magnetic permeability

Simulate Your Magnetic Lifting Machines Using SimScale

Magnetic lifting devices offer a safe, efficient, and contactless method of transport in various industries. SimScale’s Electromagnetic Simulation simplifies the complex task of designing and testing magnetic lifters. Sign up now to start using SimScale, or request a demo to see it in action. You can also learn through our step-by-step tutorial focused on magnetic lifting simulations.

Get started right away with SimScale’s easy-to-use, web-based platform by clicking below—no need for special software or hardware.

The post Magnetic Lifting – Mechanism, Types, and Simulation appeared first on SimScale.

Electromagnetics (EM) simulation is an advanced technique to investigate the performance of electronic devices and systems virtually, minimizing the need for expensive and time-intensive legacy physical prototyping. With cloud-native simulation capabilities, engineers can go even further and eliminate their reliance on expensive hardware and complex installations of software by simply running all their simulations in parallel directly in their favorite web browser — no installation required. This not only accelerates the design cycle but also enables engineers to innovate faster, collaborate more easily in real time, and apply multiple physics simulations all in one place.

A Deeper Look into SimScale’s Electromagnetics Simulation

Electromagnetic fields play a pivotal role in countless technological innovations, from motors and transformers to medical devices and beyond. That’s why it’s crucial for engineers and designers to have access to state-of-the-art analysis tools that enable them to explore, understand, and optimize electromagnetic phenomena with unprecedented precision.EM systems often present challenges of different scales, particularly when it comes to frequency ranges. In our first roll-out, SimScale is offering low-frequency electromagnetics analysis capabilities with a dedicated magnetostatics solver powered by our partner, EMWorks. This will enable various low-frequency applications, such as linear actuators, sensors, and motors.

The SimScale EM solver enables engineers to visualize and analyze various electromagnetic parameters in magnetostatics, including:

• Magnetic flux density
• Magnetic field strength
• Current density
• Linear and non-linear magnetic permeability
• B-H curves
• Permanent magnets
• Inductance matrix
• Coil resistance
• Forces and torques

Thanks to the power of cloud computing, engineers can run as many simulations as needed at the same time and iterate on their designs following the results of their simulations to reach the optimal design.

Simulate Magnetostatics in SimScale

Magnetostatics is a model that describes magnetic fields when currents are temporally constant (stationary) or approximately constant. It has numerous applications in engineering and science that can be used in a wide variety of industries, including automotive, aerospace, consumer products, healthcare, electronics, and more. Of these applications, one can utilize the magnetostatics analysis type to answer various design questions on:

• DC machines
• Electromagnetic brakes and clutches
• Magnetic levitation devices
• MEMS
• Motors and generators
• Permanent magnet motors
• Relays
• Sensors
• Solenoids

In SimScale, engineers can simulate various low-frequency electromagnetics by simply using the electromagnetics solver, as shown in the figure below.

Electromagnetics Simulation Examples in SimScale

Switched Reluctance Motor (SRM)

Switched Reluctance Motors (SRMs) are distinct electric motors operating on the principle of variable magnetic reluctance. Yet, they do suffer from the presence of torque ripples, which result from the abrupt switching of currents during motor operation. These lead to vibrations, noise, and undesirable mechanical stresses.

With SimScale’s electromagnetics solver, engineers can run magnetostatics simulations that provide a comprehensive understanding of the torque generation mechanisms, torque ripple effects, and efficiency of the motor under different operating conditions.

Electromagnetic-Toothed Brake

The electromagnetic-toothed brake is a sophisticated braking mechanism that operates through the manipulation of magnetic forces to control its engagement and disengagement. It shares structural similarities with the conventional power-on brake, but it boasts a distinct advantage in terms of static torque, which stems from the interlocking teeth between the driving and driven components. By incorporating these teeth into its design, the toothed brake achieves a notably higher torque capacity compared to devices of similar size, thus offering precise and efficient control of motion. When the coil is energized (power-on), the toothed brake engages to provide effective braking, making it a valuable tool for halting the rotation of a load when electrical power is applied.

In the image below, we provide a visual representation of electromagnetics simulation results in SimScale, illustrating the magnetic toothed brake in action. The image showcases both the engaged and disengaged states of the brake.

Linear Solenoid (Actuator)

Linear solenoids are electromagnetic devices that generate linear push or pull motion using magnetic fields. By adjusting the number of coil turns, material properties of the parts, or the applied current through the solenoid, engineers can optimize the stroke length of a linear direct-pushing solenoid. In other words, by controlling the magnetic field, engineers can tailor the solenoid’s stroke to suit specific application requirements, such as valves, locks, actuators, and other linear-motion devices.

More Electromagnetics Simulations Coming Soon

Low-frequency electromagnetics is just the beginning for SimScale. In the near future, we plan to introduce additional modules that will enable simulations of AC magnetics, transient magnetics, electrostatics, AC electrics, and high-frequency applications at last.

All these modules contribute to the multiphysics capabilities that SimScale provides, enabling engineers to run all the necessary simulations and analyses to ensure proper testing and validation before the need for any physical prototyping.

SimScale’s EM simulation software is the new kid on the block, but it is a game changer in terms of minimizing go-to-market time and costs for electromagnetic products.

In our effort to enable engineering organizations to deploy simulation broadly while maintaining central control over simulation knowledge and usage, SimScale is integrating electromagnetics into its comprehensive suite of simulation tools, delivered via a single consistent GUI and API.

The post Low-Frequency Electromagnetics Simulation — Now in Your Browser appeared first on SimScale.