Automated container handling in port terminals
Automation Integrator Guide: Motion control and automation integration challenges reside where containers are stacked. Multiple automation container terminals operate and more are in development, presenting a grand-scale motion control opportunity.
Shipping containers revolutionized the movement of goods, driving change and efficiency throughout the global supply chain. The next revolution in container handling is the application of automation to operating the container terminal. At this time there are multiple automated container terminals in operation and more in development globally.
The automation challenge has been in the part of the terminal where the containers are stacked, called the block. One end of the block services the ships being loaded and unloaded, and the other end services trucks and trains being loaded and unloaded. A typical layout is shown in Figure 1. Stacks are usually five containers high with a narrow space between the rows, and there are typically eight rows of containers side by side per section, stretching for up to a quarter mile (400 meters), to the right in the photograph. The sections are duplicated in a parallel manner.
Rail-mounted gantry cranes are not new to the industry; however, they are now gaining traction in the marine terminal world. The large cranes, called automatic stacking cranes (ASC), are typically 80 ft high and 110 ft wide and have been developed to handle up to 10 rows of containers. Two ASCs share a pair of rails, moving up and down the rails carrying containers, continually stacking and unstacking them. These cranes are blue in Figure 1. Innovative crane engineering allows the cranes to work without operators. This significant advancement has been brought about by sophisticated optical systems on the cranes which
recognize the containers, and new scheduling software in the port management supervisory computer. The complete system provides a huge improvement in terminal productivity, and also in the reliability of the container handling.
Unmanned gantry cranes can position containers typically within +/- 50 mm using laser-based guidance systems. This doesn’t sound difficult until you consider the 40 ft container may weigh 40 tons and be moving at speeds of 5 m/sec in gantry travel mode. The cranes handle all ISO standard 20 ft, 40 ft, and 45 ft containers.
Each crane typically has more than 20 three-phase, 460 V motors, each with its own variable frequency drive to vary the speed in both directions. The table shows the main crane functions.
- - - - - - - - - - - - - - -
Quantity of motors
Troley for across the stack motion
Gantry motion along the rails
Spreader skew/sway control
- - - - - - - - - - - - - - -
Advanced automation systems
Sophisticated sensors are mounted on the crane to detect the position of the moving parts, the load, and target destination. These sensing systems include encoders and scanning laser rangefinders as shown in Figure 3.
The automatic position indication system makes direct measurements of the gantry, trolley, and hoist position via laser rangefinders, so as to compensate for factors such as rope stretch and wheel slippage. The automatic landing system uses laser scanners on the trolley to measure the position of the spreader (the container pickup assembly) relative to the container below.
Gantry position along the rails is determined using an antenna which picks up signals from transponders embedded in the surface.
The optical positioning system uses laser scanners which measure the distance and angle to surfaces, such as the container, the lifting spreader, and target container, as shown in Figure 3. A second axis scanner picks up the ends of the containers. With these measurements the crane control can automatically pick and land containers in the stacks, based on instructions issued by the yard management computer system.
There is a remote control room in the operations building with operator stations and video screens to allow the crane to be switched to manual control if unexpected conditions occur. Currently, human control is used when the automated crane interfaces with a manned over-the-road truck at the delivery gate. Safety is paramount for automated ASCs and as such a wide variety of systems and controls are in place to assure that automated ASCs and people never have an unfortunate moment.
Programmable logic controller
Variable frequency drives power the motors providing the hoist, trolley, and gantry functions. The drives run using dc power supplied by a common regenerative central converter, and independent inverters provide 3-phase ac, pulse width modulated power to the motors.
A PLC controls the drives’ speed over a local area network. The PLC takes the position data, compares it with the desired position supplied by the yard computer, and directs the variable frequency drives. The main PLC functions are:
- Sequence control for unmanned container handling
- Absolute measurement of gantry, trolley, and hoist position
- Spreader sway control in the gantry and trolley directions
- Collision avoidance with the other crane in the same block
- Interface to the terminal operating system and remote operator station over fiber optic Ethernet.
In addition a PC is dedicated to the laser scanners and to four video cameras, which supply video to the remote operator stations. The only manned cranes in the terminal are those loading and unloading the ships, and small shuttle cranes which move containers from the dock to the container stacking area.
Crane automation allows unmanned, 24/7 operation of all the stacking cranes, providing the terminal with significant cost savings. In addition, mechanical damage caused by operator skill or diligence is reduced, and container tracking is improved with reduced losses through miscommunication and human errors during container handling.
- Paul Blaiklock is marketing manager, TMEIC, Roanoke, Va. Edited by Mark T. Hoske, content manager, CFE Media, Control Engineering and Plant Engineering, mhoske(at)cfemedia.com.
What previously “impossible” motion control application might be practical with today’s integrated automation technologies?
- Automation increases container handling efficiency
- Reliability increases with automation
- Safety and position control are critical
Case Study Database
Get more exposure for your case study by uploading it to the Plant Engineering case study database, where end-users can identify relevant solutions and explore what the experts are doing to effectively implement a variety of technology and productivity related projects.
These case studies provide examples of how knowledgeable solution providers have used technology, processes and people to create effective and successful implementations in real-world situations. Case studies can be completed by filling out a simple online form where you can outline the project title, abstract, and full story in 1500 words or less; upload photos, videos and a logo.
Click here to visit the Case Study Database and upload your case study.
Annual Salary Survey
In a year when manufacturing continued to lead the economic rebound, it makes sense that plant manager bonuses rebounded. Plant Engineering’s annual Salary Survey shows both wages and bonuses rose in 2012 after a retreat the year before.
Average salary across all job titles for plant floor management rose 3.5% to $95,446, and bonus compensation jumped to $15,162, a 4.2% increase from the 2010 level and double the 2011 total, which showed a sharp drop in bonus.