Electromagnetic Double Beam Gantry Crane

 

 

Key Characteristics

Double Beam Structure: Two parallel main girders provide greater strength and stability, allowing for higher load capacities and better distribution of weight during lifting.

Electromagnetic Lifting Device: Fitted with powerful electromagnets or magnet beams, the crane can lift, move, and release steel products easily through controlled magnetization and demagnetization.

Rail-Mounted or Mobile Gantry: The crane typically moves along fixed rails and can span wide working areas, such as steel yards or warehouses.

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Main Components

Double Main Girders: Structural support for trolley and magnet.

Electromagnet Beam or Magnets: Handles steel material through magnetic force.

Trolley with Lifting Mechanism: Moves along the beams and contains the hoisting system and electromagnet controller.

Gantry Legs and End Trucks: Support and enable crane movement along rails.

Electric Control System: Includes transformer and rectifier for powering electromagnets, along with crane control.

Power Supply: Often includes cable reels or slip lines, and an emergency power backup to prevent dropped loads during power failure.

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Applications

Steel mills and rolling plants

Shipyards

Scrap yards

Metal storage and distribution centers

Rail yards and loading bays

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Advantages

Efficient Handling of Bulk Steel: Fast and safe loading/unloading of heavy magnetic materials.

High Load Capacity: Ideal for lifting 5 to 50+ tons or more, depending on configuration.

Improved Safety: Reduced manual handling, precise load control, emergency power-off protection.

Custom Configurations: Can be fitted with rotating magnets, spreader beams, or adjustable magnet arrays.

 

Rated Loading Capacity：5 ton, 10 TON, 100 ton, customized, 16/3.2 ton, 20/5 ton, 32/5 ton, 50/10 ton

Max. Lifting Height：40m, customized

Span：35m or clients' demands

Warranty：1 Year

Weight (KG)：20000 kg

Core Components：PLC, Engine, Bearing, Gearbox, Motor, Pressure vessel, Gear, Pump

Control way：Cab, wireless remote control or customized

 

 

 

1.Double Main Beams (Girders)

Two parallel horizontal beams spanning the width of the crane.

Support the trolley and ensure load distribution.

Provide track for the trolley's lateral movement.

 

Gantry Legs (Support Frames)

Vertical or sloped supports that connect the beams to the crane's base.

Designed for stability and to support the full load.

 

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Lifting Trolley

Moves along the double beams.

Contains:

Hoisting mechanism

Electric motor and gearbox

Electromagnet control unit

May include a rotating device or magnet beam spreader for handling different material shapes.

 

Electromagnetic Lifting Device

Electromagnets or Magnet Beam: Used to lift ferromagnetic materials.

Rectifier Control System: Converts AC to DC to power the magnets.

Emergency Battery Backup: Keeps the magnet energized temporarily in case of power failure to prevent accidental load drop.

 

 

3.End Carriages / Wheel Assemblies

Located at each end of the crane.

Contain travel wheels and drive motors for longitudinal movement along rails.

Equipped with buffers and rail clamps for safety and stability.

4.Travel Mechanism

Drives the crane forward/backward along the rails.

Includes drive motors, gearboxes, and brakes.

 

5.Trolley travelling mechanism

1.The trolley traveling mechanism of an industrial gantry crane is responsible for moving the hoist or lifting mechanism horizontally along the crane's main beam or gantry. This allows the crane to position the load precisely in the transverse direction.

2.The trolley traveling mechanism consists of several key components:

Components of the Trolley Traveling Mechanism

Drive Unit: Typically an electric motor, the drive unit provides the power to move the trolley. The size and capacity of the motor depend on the crane's lifting capacity and the required speed of the trolley.

Gearbox: The gearbox reduces the high speed of the motor output to a lower speed suitable for the trolley's travel. It also increases the torque, which is necessary to move the hoist mechanism and any attached load.

Wheels or Rollers: The trolley rides on wheels or rollers that are mounted on axles. These wheels or rollers travel along the flanges or tracks on the main beam, allowing the trolley to move back and forth.

Brake System: A braking system is integrated into the trolley to control its movement and to hold it in position when needed. This can be a mechanical brake, an electromechanical brake, or a dynamic braking system.

3.The trolley traveling mechanism is crucial for precise positioning of the load in the transverse direction. It allows the crane to place loads accurately at different points along the length of the gantry. Proper maintenance and regular inspections are essential to ensure that the trolley mechanism operates smoothly and safely. Any issues with this mechanism can significantly impact the crane's operational efficiency and safety, making it vital to address any problems promptly.

 

6.Crane wheel

1.The crane wheel of an industrial gantry crane is a critical component that allows the crane to move along its runway beams or rails. These wheels are designed to support the weight of the crane, its load, and any additional dynamic forces generated during operation.

2.Here are the key features and functions of crane wheels:

Features of Crane Wheels

Material: Crane wheels are typically made from high-strength materials such as steel or cast iron to ensure they can withstand the heavy loads and stresses involved in lifting operations.

Size and Configuration: The size of the wheels varies depending on the capacity and design of the crane. They can be larger for heavier cranes to distribute the load more evenly. The number of wheels per axle and the number of axles per crane can also vary based on design requirements.

3.Crane wheels play a vital role in the mobility and stability of industrial gantry cranes. They are responsible for transferring the weight of the crane and its load to the runway beams or rails while allowing for smooth travel. The durability and efficiency of the crane's movement largely depend on the quality and condition of these wheels.

4.Proper maintenance of crane wheels, including regular inspections and timely replacement of worn components, is crucial for the safe and reliable operation of the crane. Neglecting wheel maintenance can lead to increased downtime, reduced efficiency, and potential safety hazards.

 

7.Crane Hook

1.The crane hook of an industrial gantry crane is a critical component that allows the crane to lift and move various loads. The hook is the point of contact between the crane's hoisting mechanism and the load, making it a crucial interface for safe and efficient operations.

2.Here are the key features and functions of crane hooks:

Features of Crane Hooks

Material: Crane hooks are typically made from high-strength steel or alloy steel to ensure they can withstand the heavy loads involved in lifting operations. The material is chosen for its durability and resistance to wear and tear

Design: The design of the hook includes an opening at the top where it attaches to the hoist rope, chain, or other lifting device. The bottom part of the hook has a curved shape that allows it to securely engage with lifting points on the load.

Safety Latch: Many hooks are equipped with a safety latch or locking mechanism to prevent the load from accidentally slipping off. This latch must be manually opened to release the load at the desired location.

Load Ratings: Each hook is rated for specific maximum loads, and it is essential to use hooks that are rated for the intended loads to ensure safety and compliance with regulations.

 

Motor

The motor of an industrial gantry crane is a critical component that provides the power necessary for lifting and moving loads. Motors in gantry cranes are typically electric and can be categorized into two main types based on their function: the hoisting motor and the travelling (or traversing) motor.

The hoisting motor is responsible for lifting and lowering the hook or grab that engages with the load. This motor's primary function is to control the vertical movement of the crane's loading mechanism.

Crane motors are the powerhouse of industrial gantry cranes, providing the energy required for both lifting and moving operations. The performance, reliability, and safety of the crane are heavily dependent on the motors' efficiency and durability. Proper selection, maintenance, and regular inspections of these motors are crucial for ensuring the crane operates smoothly and safely. Any issues with the motors can lead to operational inefficiencies, increased downtime, and potential safety risks, making prompt attention to motor problems essential.

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Sound and light alarm system & limit switch

1.Industrial gantry cranes are equipped with a sound and light alarm system and limit switches to enhance safety and operational efficiency. These components play crucial roles in preventing accidents and ensuring that the crane operates within its designated parameters.

2.Sound and Light Alarm System

The sound and light alarm system is designed to alert personnel in the vicinity of the crane about its operational status. This system is particularly important in environments where the crane operates in close proximity to workers or where visibility is limited.

3.Limit Switches

Limit switches are electronic devices that serve as critical safety features on industrial gantry cranes. They detect the position of the crane or its components and cut off power when the crane reaches its operational limits, preventing potential accidents and damage.

4.Both the sound and light alarm system and limit switches are integral to the safe operation of industrial gantry cranes. The alarm system ensures that personnel are aware of the crane's movements and operational status, reducing the risk of collisions or other hazards. Limit switches, on the other hand, automate safety by physically preventing the crane from operating beyond its design limits. Together, these systems contribute to a safer workplace and protect both the crane equipment and the personnel working around it. Proper maintenance and regular testing of these systems are essential to ensure they function reliably and effectively.

10.Safety Devices

Overload Protection Devices

Overload protection devices are designed to prevent the crane from operating beyond its safe working load limits. These devices monitor the load being lifted and will either send an alert or shut down the crane if the load exceeds the specified limit. This is crucial for preventing structural damage to the crane and avoiding accidents that can occur due to overloading.

Limit Switches

As mentioned earlier, limit switches automatically stop the crane when it approaches the end of its travel range or when any of its components reach their operational limits. These switches are essential for preventing the crane from exceeding its physical boundaries, which could result in damage to the structure or collision with obstacles.

Anti-Collison Devices

Anti-collison devices are particularly important in environments where multiple cranes operate in close proximity or where there is significant ground traffic. These devices use sensors, cameras, or other technologies to detect the presence of other objects in the crane's path and either alert the operator or automatically halt the crane's movement to prevent a collision.

Emergency Stop Buttons

Emergency stop buttons are manually operated controls that allow the crane operator or any authorized personnel to immediately stop all crane operations in case of an emergency. These buttons are strategically placed within easy reach of the operator and are often red and highly visible.

Brake Systems

Brake systems on industrial gantry cranes are designed to hold the load securely in place when not in motion and to provide controlled stopping during operations. These brakes can be mechanical, electrical, or a combination of both, and they are critical for preventing unexpected load movements that could lead to accidents.

Levelness Indicators

Levelness indicators are used to ensure that the crane is level during operation, especially when lifting precise or delicate loads. Uneven lifting can cause loads to shift, potentially leading to loss of control and accidents. These indicators help operators maintain the crane's balance and stability.

Safe Working Load Indicators

Safe working load indicators clearly mark the maximum safe load capacity for the crane. This information is vital for operators to ensure that the crane is not overloaded and operates within its design specifications.

 

11.Control Mode

1.Manual Control

Direct Intervention: The crane operator directly controls the hoisting and traveling movements of the crane using handwheels, levers, or push buttons. This mode requires skilled operators who can manually synchronize the movements to achieve the desired positioning of the load.

Simple Mechanisms: Manual control systems are generally simpler in design and may be less prone to complex failures.

Limited Precision: The precision of the crane's movements is limited to the operator's skill and experience.

2.Semi-Automatic Control

Assisted Operation: The crane operator uses control devices such as joysticks or paddle switches to command the crane, but the system includes automated features that assist in controlling speed and synchronization.

Enhanced Safety: Semi-automatic systems often include safety features like automatic stops at load limits or travel limits.

Improved Efficiency: These systems can improve operational efficiency by reducing the need for highly skilled operators.

3.Fully Automatic Control

Programmable Logic Controller (PLC): The crane's operations are governed by a PLC, which can be programmed to perform specific sequences of operations automatically.

Precise Control: Fully automatic systems offer precise control over the crane's movements, allowing for complex maneuvers to be executed consistently.

Reduced Human Error: Automated systems reduce the potential for human error, enhancing safety and reliability.

Remote Operation: In some cases, fully automatic cranes can be operated remotely, removing the operator from potentially hazardous environments.

4.Radio Control

Wireless Operation: The crane operator uses radio transmitters to control the crane from a distance, which can be particularly useful in environments where visual contact with the crane is limited.

Increased Flexibility: Radio control allows operators to move freely around the work area while maintaining control of the crane.

Safety Considerations: Proper frequency management and security measures must be in place to prevent interference or unauthorized operation of the crane.

5.Computer Control

Advanced Systems: Some gantry cranes may employ computer systems that integrate advanced features such as machine vision, artificial intelligence, and data analysis to optimize operations.

Data Collection: Computer-controlled cranes can collect operational data, which can be used for maintenance planning and operational optimization.

Interface Options: Operators may interact with the crane through touch screens or other advanced interfaces, providing detailed feedback and control options.

 

12.Sketch

 

 

 

 

Advantages of Electromagnetic Double Beam Gantry Crane

Efficient Handling of Magnetic Materials

Electromagnets allow quick and secure lifting of steel plates, billets, scrap metal, rebar bundles, and coils.

No need for slings, chains, or clamps-reducing manual labor and improving speed.

High Lifting Capacity & Stability

The double beam design offers high structural strength, enabling safe lifting of large and heavy loads, often 10 to 50+ tons.

Better load stability and minimal deflection across long spans.

Enhanced Safety Features

Battery backup system maintains magnet power during outages, preventing sudden load drops.

Built-in limit switches, overload protection, and emergency stop systems improve operational safety.

Improved Productivity

Faster lifting, lowering, and movement cycles compared to mechanical clamps or hooks.

Ideal for high-throughput environments like steel plants and scrap yards.

Versatility

Can be configured with fixed or rotating magnet beams, multiple magnets, or adjustable spacing to accommodate different shapes and sizes of loads.

Reduced Labor Costs

Minimizes manual handling of materials.

Enables a single operator to manage heavy lifting via remote or cabin control.

Customizable Design

Tailored span, lifting height, travel length, and magnet type depending on your operational needs.

Options for indoor or outdoor use, with weatherproofing and anti-wind devices.

No Need for Overhead Support

Gantry structure eliminates the need for overhead building beams or support rails-ideal for outdoor yards or where overhead cranes are not feasible.

 

 

1. Steel Mills and Rolling Plants

Lifting and transporting steel slabs, coils, billets, and bars.

Handling materials during production, storage, or shipment processes.

Moving hot or cold steel components safely and efficiently.

2. Scrap Yards and Recycling Facilities

Collecting, sorting, and transporting scrap metal.

Ideal for loading/unloading trucks or feeding shredders and furnaces.

Rapid cycling reduces processing time.

3. Metal Fabrication and Processing Plants

Moving large steel sheets, plates, and profiles between workstations.

Precise handling during cutting, welding, and assembly processes.

4. Shipbuilding Yards

Transporting magnetic steel components like hull sections, beams, and panels.

Efficient for material staging and large part assembly.

5. Railway Yards

Loading/unloading rails, bogies, or other steel components.

Ideal for maintenance depots or manufacturing plants for rail systems.

6. Ports and Container Terminals

Handling steel containers, beams, and coils for import/export.

Enhances productivity in storage yards with magnetic cargo.

7. Warehousing and Logistics Hubs

Organizing and moving ferrous material inventories in outdoor or covered storage areas.

Useful where quick stacking and retrieval of metal items is essential.

 

 

1. Design and Engineering

Detailed Engineering: Develop detailed engineering drawings and specifications, including the main beam, hoist, trolley, end carriages, and other components.

Simulation and Modeling: Use computer-aided design (CAD) and simulation tools to model the crane's performance and optimize its design.

2. Material Selection

Material Specifications: Select high-quality materials that meet the requirements for strength, durability, and heat resistance. Common materials include high-strength steel, alloys, and specialized coatings.

Procurement: Source materials from approved suppliers, ensuring they meet the necessary quality and certification standards.

3. Component Fabrication

Cutting and Shaping: Cut and shape raw materials into the required components, such as beams, columns, and brackets. This may involve processes like plasma cutting, laser cutting, and machining.Welding and Assembly: Weld components together to form the crane's structural elements. This includes welding the main beam, end carriages, and other load-bearing parts.

4. Assembly

Sub-Assembly: Assemble individual components, such as the hoisting system, trolley, and end carriages, into sub-assemblies. This involves fitting parts together and ensuring proper alignment.Main Assembly: Combine sub-assemblies to construct the complete crane structure. This includes mounting the hoist and trolley on the main beam, attaching the end carriages, and installing the control systems.

5. Integration of Systems

Electrical Systems: Install electrical components, including motors, control panels, wiring, and sensors. Ensure that the crane's electrical systems are properly integrated and tested.

Control Systems: Implement and configure control systems, such as programmable logic controllers (PLCs), remote controls, and safety devices. Verify that the control systems function correctly and are calibrated.

6. Testing and Quality Assurance

Pre-Operational Testing: Conduct pre-operational tests to check the crane's functionality, including load testing, operational testing of the lifting and traveling mechanisms, and control system checks.

Safety Testing: Verify that safety features, such as limit switches, alarms, and emergency stops, are working correctly and meet safety standards.

Inspection: Perform a detailed inspection of the crane's structure and components to ensure compliance with design specifications and quality standards.

7. Final Adjustments and Calibration

Fine-Tuning: Make any necessary adjustments to optimize the crane's performance and ensure smooth operation. This may include calibrating sensors, adjusting controls, and fine-tuning the lifting system.

Documentation: Prepare and review documentation, including operation manuals, maintenance guides, and safety instructions.

8. Delivery and Installation

Transport: Arrange for the transport of the crane to the installation site, ensuring that it is handled and shipped safely to prevent damage.

Installation: Oversee the installation of the crane at the customer's facility, including assembly, alignment, and connection to power sources and control systems.

Training: Provide training for operators and maintenance personnel to ensure they are familiar with the crane's operation and safety procedures.

9. Commissioning and Handover

Commissioning: Conduct final commissioning tests to verify that the crane operates correctly under real-world conditions and meets performance specifications.

Handover: Officially hand over the crane to the customer, providing all necessary documentation, including certificates of compliance, warranty information, and maintenance schedules.

 

 

 

Material Inspection

Quality Inspection: Strict quality inspection is carried out on the purchased raw materials to ensure that they meet the design requirements and national standards.

Material Storage: Qualified materials are stored according to classification to prevent corrosion or damage.

Cutting and Forming

Steel Cutting: Use plasma cutting, laser cutting or flame cutting and other technologies to cut the steel according to the size of the design drawing.

Forming Processing: Form the steel plate through bending, rolling, welding and other processes to manufacture the main beam, end beam and other structural parts.

Welding

Component Welding: The cut and formed steel parts are welded into the main structures such as the main beam, end beam and trolley. The welding process needs to be strictly controlled to ensure the structural strength and welding quality.

Weld Inspection: Use non-destructive testing technology (such as ultrasonic testing, radiographic testing) to inspect the welds to ensure that there are no cracks or other defects.

Machining

Precision Machining: Precision machining is performed on the key components of the crane, such as wheel sets, bearing seats, pulleys, etc., to ensure their dimensional accuracy and surface quality.

Assembly of the whole machine

General assembly: On the basis of pre-assembly, the overall assembly of the crane is carried out, including the final installation of the main beam, end beam, lifting mechanism, walking mechanism, etc.

Commissioning and testing

Under dynamic conditions, the operating performance of the crane is tested, including the testing of lifting, walking, steering and other functions. The overall size of the assembled bridge crane is checked to ensure that all dimensions meet the design requirements.

Spraying and anti-corrosion treatment

Surface treatment Rust removal: Rust removal on the surface of the crane, common methods include sandblasting, pickling, etc. Primer spraying: Spray anti-corrosion primer on the treated surface to prevent metal oxidation and corrosion. Topcoat spraying Color spraying: Spray topcoat according to customer requirements or industry standards to give the crane a protective and decorative effect. Marking: After spraying, mark the crane's identification information in accordance with the specifications, such as model, rated load, etc.

Factory and installation

Packaging and transportation

Packaging protection: Protectively package the key components of the crane to prevent damage during transportation. Transportation arrangement: According to the equipment size and transportation conditions, select a suitable transportation method to transport the crane to the customer's site.

Acceptance and delivery

Customer acceptance

On-site acceptance: The customer conducts on-site acceptance of the crane according to the contract requirements and technical specifications to check the performance and quality of the equipment.

Problem rectification: If any problems are found, the manufacturer needs to rectify them in time to ensure that the equipment fully meets the customer's requirements. Delivery and use Operation training: The manufacturer usually trains the customer's operators to ensure that they can operate the crane correctly and safely.

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