Overhead Travelling Crane Price

The price of an overhead travelling crane (also known as a bridge crane) can vary significantly depending on several factors, including crane specifications, capacity, and additional features. Here's a brief introduction to the factors influencing its cost:

1. Crane Type

Single Girder: Typically less expensive because it uses one girder, fewer materials, and a simpler design. Prices for single girder overhead cranes can range from $10,000 to $100,000 or more, depending on capacity and span.

Double Girder: More expensive due to the use of two girders, allowing for greater lifting capacities. Prices can start at $50,000 and go upwards, depending on load capacity and additional customizations.

2. Capacity and Span

Cranes with higher lifting capacities (e.g., 10 tons, 20 tons, or more) and longer spans will be more expensive. Larger spans (such as 25 meters or more) require stronger materials and additional engineering.

A higher capacity crane (e.g., 30–50 tons) can cost between $100,000 to $500,000.

3. Hoist and Trolley

The type of hoist (manual, electric, or pneumatic) and the features of the trolley (motorized or manual) will influence the cost.

Electric wire rope hoists and motorized trolleys tend to increase the price.

4. Customization and Special Features

Custom cranes designed for specific industrial applications with additional features like automation, precision controls, and special safety features (e.g., anti-sway technology) will significantly raise the price.

Options like remote controls, advanced safety systems, and special attachments can add to the overall cost.

5. Installation and Setup

Installation costs can vary based on the complexity of the crane system, the height of the facility, and whether new runway beams or structural supports need to be built.

Installation can add anywhere from $5,000 to $50,000 or more to the project cost.

6. Brand and Manufacturer

Well-known manufacturers or cranes with premium components (motors, gears, electrical systems) tend to be more expensive.

Prices can vary between suppliers based on the quality of materials and service offerings.

7. Maintenance and Spare Parts

Long-term costs like maintenance, spare parts, and service contracts should also be considered when calculating the total cost of ownership.

In general, overhead travelling crane prices range from $10,000 to over $500,000, depending on the above factors.

Core Components: Gearbox, Motor

Place of Origin: Henan, China

Warranty: 2 years

Weight (KG): 3000 kg

Video outgoing-inspection: Provided

Machinery Test Report: Provided

Control Method: cabin control/wire rope remote control

Lifting speed: 5-15M/MIN

Trolley running speed: 20-40M/MIN

Power Supply: 380V 50Hz or on request

Crane running speed: 50-100M/MIN

Protection grade: IP54

Insulation grade: F

Working Duty: A3

Color: Requst

 

 

Pictures & Components

 

 

1.Girder(s)

Single Girder: Typically less expensive because only one beam supports the trolley and hoist. This is common for lighter loads and shorter spans. A single girder can reduce the cost of both materials and installation.

Double Girder: More expensive due to two girders, which provide greater strength and support for heavier loads and longer spans. This design increases material, engineering, and installation costs.

2.Hoist

Manual Hoist: Cheaper option, suitable for light loads and less frequent use. Common in small workshops.

Electric Hoist: More expensive but allows for smooth, efficient lifting of heavy loads. It increases the overall cost based on capacity, speed, and power rating.

Wire Rope Hoist: Higher cost than chain hoists, often used for heavy-duty applications. The price also varies depending on load capacity and lifting height.

 

3.End carriage

Explosion-Proof Design:Constructed with materials that prevent sparking, such as non-ferrous metals or specially coated steel.All electrical wiring, motors, and control systems are enclosed in explosion-proof housings to prevent the ignition of any gases or particles present in the environment.The end carriage is sealed to prevent the entry of dust or gas that could lead to ignition.

Structure and Load-Bearing: The end carriage connects securely to the main girder of the single beam, supporting the weight of the load and distributing it evenly across the crane's structure.Built for heavy-duty usage, ensuring that the crane remains stable even when handling the maximum load capacity. Reinforced to prevent any bending or twisting under load pressure.

Wheel System: Often made from materials that don't produce sparks, such as nylon, copper alloys, or rubber-coated wheels.Designed to minimize friction and allow for smooth lateral movement along the crane rail, improving operational efficiency and control.Wheels are highly resistant to wear and corrosion, suited for long-term use in harsh conditions.

Motor and Control Mechanisms: The motors driving the end carriage are specially designed to contain any potential explosions within their casings. Equipped with control systems that allow for precise positioning of the crane, which is essential in hazardous environments.Adjustable speeds ensure safe maneuverability, helping the operator handle sensitive materials without sudden jerks or movements.

Safety Mechanisms: Integrated emergency stop systems that can cut power to the entire crane in case of any malfunction.Sensors that prevent the crane from lifting loads beyond its safe working limit.Stops the crane from over-traveling or moving beyond specified safe zones, reducing the risk of accidents.

 

 

 

4.Crane travelling mechanism

1) Working principle

The travelling mechanism is typically powered by electric motors, which drive the crane's wheels or trolleys along the runway. In explosion-proof cranes, the motors and electrical components are designed to be spark-resistant or enclosed to prevent ignition of flammable gases or dust in hazardous environments.The motor is usually connected to a gearbox that reduces the speed of the motor and transmits the rotational force to the wheels or trolley. The gearbox and transmission system are also designed to meet the explosion-proof standards by being sealed or housed in protective casings.The crane's movement is facilitated by wheels that run along rails (or runways) mounted on the overhead structure. These wheels are often made of materials that can withstand high stresses and resist wear. The wheels are driven by the motor and gearbox assembly, and their movement along the rail provides horizontal travel.

2) Functions of the crane operating mechanism

The motor powers the crane's movement along the runway. It is typically designed with explosion-proof enclosures to ensure that it does not ignite any combustible substances in the air.The motor drives a reduction gear that reduces the speed while increasing the torque. This is necessary for the crane to move smoothly and with sufficient force along its track.The traveling mechanism moves the crane along the girder, which is the main structural beam. The trolley holds the crane's hoist and moves across the girder as part of the traveling system.The crane is equipped with wheels that run along the tracks or rails, typically mounted on the side of the girder. These wheels are designed to carry the load and allow smooth travel. They may have roller bearings or ball bearings to reduce friction and wear.

5.Trolley

Manual Trolley: More affordable but requires manual pushing or pulling to move the hoist along the girder. This is typically used in low-capacity cranes.

Motorized Trolley: More expensive due to the inclusion of motors for automated horizontal movement. It adds convenience, speed, and efficiency, increasing the overall cost.

6.Crane wheel

The crane wheels are mounted on the ends of the crane bridge or trolley. They allow the crane to move along the runway rails or tracks.These wheels are usually made from materials that can withstand high loads and harsh environmental conditions. In explosion-proof cranes, they are often constructed from high-strength steel to prevent sparks and minimize the risk of ignition in explosive atmospheres.

The design of the crane ensures that it meets stringent safety standards. For example, the crane wheel housing may be sealed to prevent the release of sparks or static electricity, which could ignite combustible gases, dust, or vapors in the environment.The explosion-proof design might include explosion-proof motors, electrical components, and control systems, ensuring that all parts of the crane are safe to operate in hazardous locations.

The crane wheels are designed to run smoothly on the overhead rails. They must be durable to endure the constant friction and wear from the movement of the crane, while also providing stability to support heavy loads.The rail system is part of a larger structure that ensures the crane stays aligned and operates with minimal vibration, which could otherwise generate sparks or other ignition risks.

7.Crane Hook

1) The hook and other components of the crane are built to prevent the initiation of sparks or heat that could cause an explosion. This includes using materials that do not easily generate sparks, as well as ensuring that all joints and connections are sealed and protected.The hook is typically made from high-strength, corrosion-resistant materials, like stainless steel or special alloys, to withstand harsh and potentially corrosive environments.

2) The hook is designed to carry heavy loads while maintaining structural integrity under extreme conditions. It usually includes safety features like anti-rotation devices, locking mechanisms, and other safety devices to prevent accidental detachment. Explosion-proof hooks are often custom-designed according to the class and zone of the hazardous area, in compliance with international standards (such as ATEX or IECEx certification)..

8.Motor

Explosion-Proof Motor Design:The motor is housed in an explosion-proof enclosure (often marked as "Ex"). This enclosure is designed to withstand an internal explosion and prevent sparks or flames from escaping, which could ignite the surrounding hazardous atmosphere.These motors are often certified under international standards such as ATEX (Europe) or IECEx (International), indicating that they are safe for use in specific explosive atmospheres.

Features of Explosion-Proof Motors: Explosion-proof motors are equipped with temperature control features to avoid overheating, which can be a source of ignition. These motors are designed to operate at lower temperatures compared to standard motors. Motors used in such cranes are made from high-quality, corrosion-resistant materials to withstand harsh environmental conditions like moisture, dust, and temperature extremes.The motor parts, including the bearings and commutators, are designed to minimize the generation of sparks, which could trigger an explosion.

Power and Speed: Explosion-proof motors for cranes typically range from low power (for lighter cranes) to higher power ratings (for heavy-duty cranes), typically measured in horsepower or kilowatts (kW).Depending on the crane's application, the motor may be coupled with a variable frequency drive (VFD) to control the speed of the crane's movements smoothly.

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Sound and light alarm system & limit switch

1) Sound and light alarm system

An explosion-proof single beam overhead crane typically operates in environments where there is a risk of explosion, such as in chemical plants, refineries, or other hazardous locations. The crane system is designed to handle explosive atmospheres while ensuring safety and preventing ignition.

Light Alarm: Explosion-Proof Signal Lights:These signal lights are used to indicate various crane operation statuses, such as operational readiness, emergency, or maintenance needs. The system generally includes different colored lights for different signals.Red is Emergency, stop, or danger signal.Yellow is Warning or caution signal (e.g., when the crane is in operation or in a limited state).Green is Safe or normal operation, indicating the crane is working as expected.The lights are housed in explosion-proof enclosures to prevent any internal ignition from escaping to the external environment.

Sound Alarms (Horns or Sirens):These alarms alert operators and nearby personnel to critical situations. The sound is loud enough to be heard over the noise of the machinery or equipment.Continuous Horn is Often used to signal an immediate danger or malfunction.Intermittent Horn can signal warnings or when the crane is approaching a danger zone.Multi-tone Alarm provides different tones for various operational states Like the lights, the sound alarms are housed in explosion-proof casings to ensure they do not pose a risk in an explosive atmosphere.

2) Limit switch

Limit switches on outdoor gantry cranes are crucial for safety and operational efficiency. They are used to prevent the crane from moving beyond its designated limits, which helps avoid collisions and accidents.

Functions: The limit switch is built to meet explosion-proof standards (such as ATEX or IECEx) to ensure that it does not cause sparks or heat that could ignite explosive gases, dust, or vapors in the surrounding environment.It helps to prevent the crane from operating beyond its capacity, thus preventing accidents such as tipping or mechanical failure due to excessive load.The limit switch stops the crane's movement once it reaches the maximum allowed travel in any direction, including the horizontal movement of the bridge and trolley, or vertical travel of the hoist.

Types: The limit switch can be mechanical (using a lever or roller mechanism to activate the switch) or electronic (using sensors such as optical, capacitive, or inductive to detect limits).

10.Safety Devices

Explosion-Proof Motor and Electrical Components：Explosion-proof motors and sealed electrical components prevent sparks and other electrical discharges that could ignite flammable substances.Enclosures for these components are usually rated according to standards such as ATEX or IECEx, which certify their ability to operate safely in explosive environments.

Anti-Collision Devices：Anti-collision systems, including infrared or ultrasonic sensors, help prevent collisions with other cranes, objects, or personnel in the work area, reducing risks in hazardous settings.

This device is especially important in areas with multiple cranes or restricted space.

Overload Protection System：Overload limiters prevent the crane from lifting loads exceeding its rated capacity. This helps prevent structural stress, tipping, and equipment damage.

Sensors can detect overload and trigger an alarm or automatically stop operations.

Emergency Stop Button：Emergency stop buttons are strategically placed on both the crane and remote controls, allowing operators or personnel to stop crane movement instantly if there's any danger.

In explosive environments, these buttons are built to withstand shocks and avoid accidental activation.

Spark-Resistant Components：Spark-resistant materials are used in parts that might otherwise cause sparks from friction. These materials include bronze or brass hooks, wheels, and other components in contact with other metals.

Limit Switches：Limit switches prevent the crane from moving beyond set points, such as the upper and lower limits of the hoist and the end of travel for the bridge and trolley.This helps avoid dangerous situations where the crane might move unexpectedly or reach a position that could damage surrounding structures.

Grounding and Anti-Static Measures：Grounding devices and anti-static systems prevent the build-up of static electricity, which could otherwise ignite flammable materials.Conductive grounding brushes, cables, or wheels can help dissipate static safely.

Enclosed and Protected Cables：Electrical cables and control wiring are typically enclosed in protective conduits or metal casings to prevent accidental damage or exposure to explosive gases.Special cable seals are used to ensure that no sparks can escape through wiring paths.

Temperature Control and Monitoring：Temperature sensors on motors, brakes, and other key components monitor for excessive heat that could ignite nearby substances.Systems may automatically shut down the crane if temperatures exceed safe limits.

 

Remote Control Operation：Explosion-proof remote controls allow operators to control the crane from a safe distance, minimizing exposure to hazardous areas.Remote controls are designed with special enclosures to avoid accidental discharges or damage in explosive settings.

11.Control Mode

Pendant Control：A wired pendant control allows the operator to control the crane from a safe distance. The pendant has buttons for moving the crane in various directions, hoisting and lowering, and emergency stopping.Maintains a safe distance from hazardous materials and crane operations. The pendant is explosion-proof and resistant to sparks, making it suitable for hazardous environments.

Remote Control: Wireless remote controls are often used to allow the operator complete freedom to move around the worksite while controlling the crane from a safe distance.Offers greater flexibility in movement and operation, improves safety by enabling the operator to maintain a greater distance from hazardous areas.

Cabin Control: For larger and more complex cranes, a cabin control setup allows the operator to sit in an enclosed, explosion-proof cabin with controls similar to those in pendant or remote configurations.Provides a clear line of sight over the work area and allows for precise control of the crane. Cabins are explosion-proof and often climate-controlled.

PLC (Programmable Logic Controller) and Automated Control Systems: PLCs can be integrated into the crane for semi-automated or fully automated operation. This is particularly useful in repetitive or hazardous tasks where minimal human intervention is preferred.Reduces the need for operator involvement in dangerous areas, ensuring safer operations. Enhances efficiency and consistency in repetitive operations.

Safety and Emergency Control Systems: In addition to the main control mode, explosion-proof cranes are equipped with various emergency stop controls, overload protection, and emergency braking systems to ensure safe shutdown in case of an emergency. Ensures quick response to emergencies and minimizes the risk of accidents in explosive environments.

 

 

 

 

 

 

 

 

 

 

12.Sketch

 

 

 

 

 

 

 

 

 

 

 

 

Main technical

 

 

 

The price of an overhead travelling crane can be seen as an investment due to the significant advantages it offers in industrial operations. Here are some key benefits that justify the price of an overhead travelling crane:

1. Increased Productivity

Efficient Material Handling: Overhead travelling cranes enable quick, smooth, and precise movement of heavy loads across large work areas. This boosts operational efficiency, reducing time spent on manual handling, and improving production output.

Automation Options: More expensive cranes with automation features (e.g., remote control or fully automated systems) further improve workflow and reduce downtime, allowing the crane to operate with minimal human intervention.

2. Cost-Effective in the Long Term

Reduced Labor Costs: Though the initial investment may be high, overhead cranes reduce the need for manual labor and forklifts. This lowers labor costs and increases operational efficiency.

Lower Maintenance Costs: Modern overhead cranes are designed for durability and require relatively low maintenance, especially when equipped with advanced safety and monitoring systems. Over time, this reduces maintenance costs and extends the crane's lifespan.

3. Safety

Enhanced Workplace Safety: Overhead cranes are equipped with safety features such as limit switches, overload protection, emergency stop systems, and anti-sway technology. These systems prevent accidents and protect workers from the dangers of handling heavy loads manually or using less controlled equipment like forklifts.

Fewer Workplace Injuries: The reduced reliance on manual labor for heavy lifting helps to prevent injuries and accidents in the workplace, lowering health and safety risks and associated costs.

4. Space Optimization

Maximizes Floor Space: Overhead cranes operate on elevated tracks, which keeps the floor area clear for other operations, improving facility organization and allowing more efficient use of space compared to ground-based lifting equipment.

Reduces Congestion: By eliminating the need for ground-level handling equipment, such as forklifts or trucks, overhead cranes reduce congestion on the shop floor, making operations smoother and safer.

5. Versatility and Customization

Adaptable to Various Industries: Overhead travelling cranes can be customized to suit different industries and applications, including manufacturing, warehousing, shipbuilding, and construction. This versatility increases the return on investment as it can be used for multiple tasks.

Handling Different Loads: Cranes can be tailored to handle a wide range of loads, from small components to extremely heavy and bulky objects. This adaptability reduces the need for multiple pieces of lifting equipment, further saving costs.

6. High Load Capacity

Heavy-Duty Performance: While the upfront cost may be high, overhead cranes offer high load-bearing capacity, allowing them to handle substantial weights that other lifting equipment cannot. This reduces the need for multiple lifting systems, providing a cost-effective solution for heavy-duty operations.

7. Precision and Control

Accurate Load Placement: Overhead cranes offer precise control over load movement, especially when equipped with advanced features like variable speed drives and remote control systems. This accuracy minimizes the risk of damage to materials and improves the efficiency of positioning and placement in sensitive applications.

Reduced Load Damage: The controlled movement of overhead cranes reduces the risk of material or product damage, helping to minimize losses and save costs in the long run.

8. Durability and Longevity

Long Service Life: Though the initial cost of a high-quality crane may be substantial, overhead cranes are designed to last for many years with proper maintenance. This long lifespan provides excellent value over time, as it reduces the need for frequent replacement or repairs.

Built for Harsh Environments: Many overhead cranes are designed to withstand harsh industrial environments (e.g., extreme heat, cold, or corrosive conditions), making them a durable option that justifies the price.

9. Flexibility of Use

Multi-Tasking Capability: Overhead cranes can handle various tasks, such as lifting, moving, and positioning heavy loads. This flexibility eliminates the need for multiple pieces of equipment, reducing overall investment costs.

Wide Application Range: These cranes can be used in diverse industries like manufacturing, construction, shipbuilding, and mining, making them a versatile investment for companies operating in multiple sectors.

10. Reduced Downtime

Minimal Interruptions: High-quality cranes are designed to operate efficiently with minimal maintenance and downtime. With fewer breakdowns and a longer operational life, companies can avoid costly disruptions to their operations.

11. Faster Return on Investment (ROI)

Increased Operational Efficiency: The improved productivity, reduced labor costs, and enhanced safety features result in faster payback on the initial investment.

Long-Term Savings: The long lifespan, low maintenance costs, and reduced need for additional equipment help companies save money over the long term, ensuring a good ROI.

12. Environmental and Energy Efficiency

Energy-Saving Technology: Modern overhead cranes often incorporate energy-saving technologies that reduce electricity consumption, lowering operating costs and improving sustainability.

Reduced Carbon Footprint: By optimizing material handling processes, overhead cranes contribute to more efficient use of resources, reducing waste and lowering a company's carbon footprint.

In summary, the advantages of investing in an overhead travelling crane-such as increased productivity, enhanced safety, space optimization, and long-term cost savings-make the higher price worthwhile for businesses that require heavy-duty, efficient, and precise material handling solutions.

 

 

 

The price of an overhead travelling crane varies based on its specifications, capacity, and additional features, but it is commonly used across a wide range of industries due to its ability to handle heavy loads efficiently. Here are the primary applications where overhead travelling cranes are used, and how the price is justified in each context:

1. Manufacturing and Assembly Plants

Application: Used to move raw materials, machinery, and components along production lines. They lift heavy parts during the manufacturing and assembly process.

Price Justification: The crane's ability to increase productivity, reduce manual labor, and handle heavy loads makes it a vital investment in manufacturing plants. Depending on the load capacity and automation required, the price can range from $20,000 to $100,000 or more.

2. Warehousing and Logistics

Application: Used for moving and storing heavy or large goods within warehouses, distribution centers, and logistics facilities.

Price Justification: An overhead crane helps optimize space by using vertical storage and reduces the need for forklifts. This can range from $10,000 to $50,000, depending on the size of the warehouse and the load capacity required.

3. Shipbuilding and Ports

Application: Used to lift large ship parts, engines, and heavy materials in shipyards, and for loading/unloading cargo in ports.

Price Justification: Overhead cranes with a large span and heavy load capacity are essential for moving ship components and cargo. Due to the high lifting capacity and durability required, prices can range from $100,000 to $500,000 or more, depending on customization and load capacity.

4. Steel Mills and Metal Fabrication

Application: Used for moving large metal plates, steel beams, and raw materials in steel mills and metal fabrication industries.

Price Justification: The crane's heavy-duty performance is critical for safely and efficiently handling heavy and often high-temperature materials. The price can range from $50,000 to $200,000, depending on the specific operational requirements.

5. Construction and Infrastructure

Application: Overhead cranes are employed for lifting construction materials such as steel girders, concrete panels, and heavy machinery at construction sites.

Price Justification: The crane provides precision in placing heavy materials at the construction site, increasing efficiency and reducing labor costs. Prices typically range from $30,000 to $150,000 depending on the size, load capacity, and site requirements.

6. Automotive Industry

Application: Used to lift vehicle parts, engines, and chassis during the assembly of cars, trucks, and other vehicles.

Price Justification: The ability to handle large and heavy automotive components efficiently improves production line workflow. Costs generally range from $15,000 to $80,000 depending on the type and complexity of the crane.

7. Mining Industry

Application: Used for moving heavy mining equipment, machinery, and minerals, especially in maintenance workshops.

Price Justification: The crane's ability to handle extremely heavy loads in harsh environments justifies its price. Mining operations often require cranes in the range of $100,000 to $500,000 or more, depending on capacity and customization.

8. Power Plants (Thermal, Hydro, Nuclear)

Application: Overhead cranes are used for installing and maintaining large equipment like turbines, generators, and reactors in power plants.

Price Justification: Given the precise and critical nature of the work, along with the need for heavy lifting, the price of cranes used in power plants is usually on the higher end, ranging from $200,000 to $500,000 or more.

9. Aerospace Industry

Application: Used to lift and transport large aircraft components such as wings, fuselages, and engines during manufacturing or assembly processes.

Price Justification: High precision and heavy lifting capabilities are crucial in aerospace, which increases the crane's cost. Prices for cranes in aerospace applications can exceed $300,000 due to the need for custom features and precision controls.

10. Chemical and Petrochemical Plants

Application: Used to move heavy chemical reactors, vessels, and other equipment in chemical and petrochemical production facilities.

Price Justification: These cranes must be designed to operate in hazardous environments, which requires specialized materials and designs. Prices can range from $100,000 to $400,000, depending on the load capacity and safety features.

11. Paper and Pulp Industry

Application: Used to handle large rolls of paper and raw materials in paper mills and processing plants.

Price Justification: The crane provides an efficient way to handle heavy and bulky materials, improving operational efficiency. Prices range from $50,000 to $150,000, depending on the facility's requirements.

12. Wind Turbine and Renewable Energy Sector

Application: Used to lift and position large wind turbine blades, generators, and towers during assembly and installation.

Price Justification: Wind energy projects require high-capacity cranes to handle large and heavy components, especially during installation. Prices can range from $150,000 to $500,000 depending on the size and load capacity.

13. Railway and Locomotive Industry

Application: Used for lifting and handling heavy locomotives, rail components, and machinery in railway workshops.

Price Justification: The crane's ability to lift and position large rail components improves maintenance and assembly efficiency. Costs typically range from $50,000 to $300,000 depending on load capacity and facility requirements.

14. Food and Beverage Industry

Application: Used to lift large equipment and containers in food processing plants, especially in environments where cleanliness and efficiency are critical.

Price Justification: Overhead cranes reduce manual handling and help maintain hygienic conditions by minimizing contact with food products. Prices generally range from $15,000 to $70,000 depending on the facility's needs.

15. Recycling and Waste Management

Application: Used for lifting and moving large waste containers and machinery in recycling and waste processing plants.

Price Justification: Cranes used in waste management must be durable and capable of handling heavy loads in harsh environments, justifying a price range of $30,000 to $150,000.

Summary:

Overhead travelling cranes are versatile and used across a wide range of industries, making them an essential investment. Their price, typically ranging from $10,000 to over $500,000, is justified based on the specific industry requirements, load capacity, customization, and operational efficiency improvements they provide.

 

 

1. Design and Engineering：Begin with an analysis of the explosion-proof requirements and operational environment where the crane will be used.Create specifications to meet industry standards for explosion-proof equipment, typically adhering to ATEX, NEC, or IEC standards, based on the zone classification.Select appropriate materials and components, such as motors, controls, and cables, that are designed for explosion-proof applications.

2. Material Procurement: Procure certified explosion-proof electrical components and materials (motors, wiring, enclosures) from approved suppliers.Select high-grade metals and alloys resistant to corrosion and spark generation, essential for hazardous environments. Use anti-corrosion and anti-static coatings, especially if the crane will operate in environments prone to moisture, chemicals, or dust.

3. Manufacturing and Fabrication: Manufacture the crane's main structural elements (girder, end beams, trolley) using welding and machining techniques to ensure strength and precision.Assemble the explosion-proof motor and hoisting mechanism with careful alignment to prevent sparking and ensure reliability.Manufacture or install explosion-proof electrical enclosures, ensuring they are sealed to prevent any flammable gases from entering. Install and wire explosion-proof control panels with insulated, spark-resistant wiring. Additional measures may include placing the control systems in safe areas or housing them in explosion-proof boxes.

4. Quality Control and Testing: Test the crane's load-bearing capacity to ensure it meets safety and operational standards. Conduct specific explosion-proof tests, such as checking for sparks and ensuring containment, to verify compliance with explosion-proof standards.Verify all electrical systems operate safely without arcing, sparking, or overheating, and ensure controls and safety systems are fully functional. Test coatings and materials for resistance to corrosion, particularly if the crane will be used in chemical-prone environments.

5. Assembly and Final Checks: Assemble the crane components, including the bridge, hoist, trolley, and electrical systems, in a controlled environment. Final InspectionPerform a thorough inspection to confirm that all explosion-proof standards and specifications have been met.Document all tests, inspections, and certification processes to ensure traceability and compliance with safety regulations.

6. Installation and Commissioning: Prepare the installation site, ensuring that it meets explosion-proof requirements and is clear of potential hazards.Assemble and install the crane on-site, following strict safety protocols to prevent damage or misalignment.Conduct load and functional tests post-installation to verify operational reliability and safety in the intended environment.

7. Certification and Handover: Obtain third-party certification for explosion-proof compliance if required by local regulations.Provide operator and maintenance training focused on explosion-proof equipment handling and safety.Provide the customer with full documentation, including maintenance manuals, certification, and operational guidelines.

Workshop view:

The company has installed an intelligent equipment management platform, and has installed 310 sets (sets) of handling and welding robots. After the completion of the plan, there will be more than 500 sets (sets), and the equipment networking rate will reach 95%. 32 welding lines have been put into use, 50 are planned to be installed, and the automation rate of the entire product line has reached 85%.