What Are the Standard Specifications of a RMG Crane?

Rail Mounted Gantry (RMG) cranes are a core piece of lifting and handling infrastructure in modern ports, intermodal terminals, rail yards, and large industrial facilities. Unlike rubber tyred gantry cranes, RMG cranes operate on fixed rails, providing higher precision, stability, and suitability for heavy-duty and high-cycle operations.

Understanding the standard specifications of a Rail Mounted Gantry Crane is essential for project planners, engineers, procurement teams, and terminal operators. These specifications define not only lifting capacity and size, but also structural design, electrical systems, safety features, and environmental adaptability.

This article provides a comprehensive overview of the standard rail mounted gantry crane specifications, explaining what they typically include, why they matter, and how they relate to real-world operating requirements.

rail mounted gantry crane specifications

1. Rated Lifting Capacity Specifications

The rated lifting capacity is the most fundamental specification of an RMG crane. It defines the maximum safe working load (SWL) the crane can lift under standard operating conditions.

Typical RMG crane capacities include:

30–40 tons for industrial material handling
40–50 tons for single-container handling
65 tons (under spreader) for twin-lift container operations
Higher customized capacities for special loads or project cargo

Capacity specifications often distinguish between:

Rated load under spreader
Rated load under hook (if hook operation is required)

The capacity directly influences structural dimensions, hoisting mechanism selection, wheel loads, and foundation design. Over-specifying capacity increases cost, while under-specifying reduces operational flexibility and safety margins.

2. Span and Gauge Specifications

The span of a Rail Mounted Gantry Crane refers to the horizontal distance between the centerlines of the two rails. This dimension determines how many container rows or work lanes the crane can cover.

Common span ranges include:

15–25 meters for rail yards and industrial plants
25–35 meters for intermodal terminals
35–45 meters or more for container stacking yards

Closely related is the rail gauge specification, which defines:

Rail type (e.g., QU70, QU80, QU100)
Rail installation tolerance
Maximum allowable deviation in alignment and elevation

Span and gauge specifications must align with yard layout, container stacking strategy, and ground bearing capacity.

3. Lifting Height and Clearance Specifications

Lifting height specifies the maximum vertical distance the load can be raised from ground or rail level.

Standard lifting height considerations include:

Container stacking height (e.g., 1-over-5, 1-over-6, or higher)
Clearance above highest container stack
Allowance for spreader and lifting gear

Typical RMG lifting heights range from:

12–18 meters for rail-mounted industrial gantry cranes
18–25 meters for container yard RMG cranes

In addition to lifting height, specifications also define:

Under-spreader clearance
Maximum and minimum hook approach
Safe distance to structural components

RMG crane specifications

4. Hoisting, Trolley, and Travel Speed Specifications

Motion speed specifications determine productivity and cycle time.

Hoisting Speed

Light load: higher speed for efficiency
Full load: reduced speed for safety and motor protection

Typical hoisting speeds range from 10 to 30 m/min depending on capacity.

Trolley Travel Speed

The trolley carries the hoist across the girder.

Standard range: 40–70 m/min

Gantry Travel Speed

Defines how fast the crane moves along rails.

Standard range: 60–120 m/min

These speeds are often controlled by Variable Frequency Drives (VFDs) to ensure smooth acceleration, reduced sway, and lower mechanical stress.

5. Structural Design Specifications

RMG crane structures are typically designed using box girder construction, which provides high torsional rigidity and long-term fatigue resistance.

Standard structural specifications include:

Single girder or double girder gantry crane configuration
Steel grade selection based on stress and climate
Deflection limits (e.g., L/700 or L/800 under rated load)
Allowable stress and fatigue class

The gantry legs may be:

Rigid leg + hinged leg configuration
Both rigid legs for high stability applications

Structural design specifications must comply with international standards such as FEM, ISO, or CMAA.

6. Wheel Load and Rail Load Specifications

Wheel load specifications are critical for rail design, foundation engineering, and long-term reliability.

Key parameters include:

Maximum static wheel load
Dynamic wheel load factor
Distribution of load across wheels

Typical RMG cranes use:

8, 12, or 16 wheel configurations
Double-flange or guide wheels for anti-derailment

These specifications directly affect:

Rail section size
Concrete beam reinforcement
Allowable settlement and alignment tolerances

7. Power Supply and Electrical Specifications

Rail Mounted Gantry Cranes typically use electric power, offering high efficiency and lower emissions.

Common power supply specifications include:

Voltage: 380V, 400V, 415V, or higher
Frequency: 50Hz or 60Hz
Power delivery method: conductor bar or cable reel

Electrical system specifications usually define:

Motor insulation class (F or H)
Protection level (IP55 or higher for outdoor use)
Control voltage and safety circuits

8. Control System Specifications

Modern RMG cranes are equipped with advanced control systems designed for precision and safety.

Standard control options include:

Cabin control
Ground pendant control
Radio remote control

Control system specifications may also cover:

PLC-based automation
Positioning accuracy
Anti-sway and soft-start functions
Interlocks and fault diagnostics

For container terminals, RMG container cranes often integrate with Terminal Operating Systems (TOS).

9. Safety System Specifications

Safety specifications are a critical part of any RMG crane standard configuration.

Typical safety features include:

Overload protection system
Upper and lower limit switches
Emergency stop circuits
Rail clamps and storm brakes
Wind speed monitoring devices

Outdoor RMG cranes are usually designed for:

Working wind speed (e.g., ≤20 m/s)
Non-working storm condition (≥40 m/s with anchoring systems)

10. Environmental and Operating Condition Specifications

RMG cranes often operate in challenging environments, making environmental specifications essential.

Standard environmental parameters include:

Ambient temperature range (e.g., -20°C to +40°C)
Humidity tolerance
Dust and corrosion protection level
Optional cold-climate or tropical adaptations

Special coatings, sealed bearings, and low-temperature lubricants may be specified depending on site conditions.

11. Standards, Testing, and Documentation Specifications

RMG crane specifications are incomplete without compliance and verification requirements.

Typical standards include:

ISO and FEM design standards
Electrical standards (IEC)
Local safety regulations

Testing specifications often include:

Factory Acceptance Test (FAT)
Load testing at 100% and 125% rated capacity
Functional and safety system checks

Documentation usually covers:

Technical drawings
Electrical schematics
Operation and maintenance manuals
Spare parts lists

Conclusion

The standard specifications of a Rail Mounted Gantry Crane go far beyond basic lifting capacity. They form a comprehensive technical framework covering structural design, motion performance, electrical systems, safety, environmental adaptability, and compliance requirements.

A clear understanding of these specifications allows engineers and buyers to:

Select the right crane configuration
Ensure compatibility with site infrastructure
Balance performance, safety, and lifecycle cost
Avoid costly redesigns or operational limitations

In practice, most RMG cranes are semi-standard products, built on proven specification ranges but customized to match exact operating conditions. Knowing the standard specification framework is the first step toward making informed, technically sound procurement decisions.