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The use of
simulation in terminal design and operation is becoming increasingly important.
Installing terminal infrastructure is costly, and the layout of the terminal
determines its capacity and the equipment that can be used. Simulation is also
used to identify potential problems that may arise during operation, allowing
for the development of countermeasures in advance. As a result, simulation is a
crucial tool in the design and operation stages of a terminal, ensuring
efficiency and credibility of the system.
■ Types of Simulation Utilized in the Terminal
There are three
types of simulation utilized in the terminal, namely design stage simulation,
operation simulation, and test-purpose simulation used equipment emulator.
Design
Stage Simulation
Design stage
simulation is utilized for both greenfield and brownfield terminals to
determine the optimal design for various layouts and equipment compositions.
This simulation focuses on verifying estimated terminal volume information,
including transshipment, targeted terminal volume space occupancy, and
equipment occupancy based on the estimated monthly ship on depot volume and
vessel volume. The simulation outcome helps to ensure that the physical
terminal design meets the business goal.
Operation
Simulation
Operation
simulation is conducted to assess the operation performance of the terminal. It
evaluates productivity while considering the variables that may arise during
the operation and aims to predict and improve potential problems and
bottlenecks in advance. This simulation includes productivity verification
support and optimizes productivity by considering workflow in the terminal,
equipment utilization rate, working time, and other factors.
Test-Purpose
Simulation
Utilized
Equipment Emulator in an automated terminal, the emulator-utilized simulation
is carried out under the condition that the equipment, yard layout, and
operation system have already been confirmed. It is utilized to verify the
stability of automated equipment and terminal operation system and its
performance through various operation scenario tests in a virtual environment.
Simulations have
mainly been carried out in the greenfield during the design and operation
stages. However, due to recent demand, verifying full automation by applying
autonomous vehicles in non-fully automated and semi-automated terminals is
necessary. Additionally, it requires converting to automation by remodeling
using manual equipment and verifying stable operation during terminal
integration and expansion. The terminal must be flexible in responding to
volume increases by introducing automated equipment, which is why the
verification of new equipment introduction is being done in operating
terminals.
As the various
requirements grow, the demand for operation simulation is increasing. An
automated Equipment Control System (ECS) must be selected in the automated
terminal, along with the equipment. The simulation's complexity rises to meet
the synergy with the appropriate equipment control system and operation system.
The diagram
below shows the Equipment-Controller-Operation System in Korea’s 1st fully automated
terminal.
The automated
terminal’s selected equipment type and operation strategy affect the yard
layout structure. Depending on the provided ECS from the vendor, the Auto
Guided Vehicle (AGV) also differs in driving lane strategy in the yard layout
and Transponder's physical location. An integrated simulation for the design
and operation stage is necessary. The integrated simulation can dynamically
respond to changing conditions and provide simulation results for the
circumstances of currently operating terminals. It may need to adapt and modify
the system to comply with changing operational requirements.
Continuous
simulation is an important tool used during both the design and operation
stages. However, traditional simulations have limitations as they can only be
used once, which makes it difficult to reflect the persistent changes that
happen during actual operations. There are now more options for terminal
operations, which can make it increasingly complex to choose the best one.
For instance,
when it comes to automatic transfer equipment like AGV, there are various
options available such as Lift AGV, IGV with changed Transponder reclamation
method, and AMR with autonomous driving function. The total gross productivity
and TGS of the yard crane depends on whether the Cantilever uses equipment on
both sides or one side only.
With more
options to choose from, the interaction and dependency also increase, making it
even more important to find the optimal decision through simulation. By
estimating the impact of each option, the simulation can help establish an
effective strategy. It is necessary to evaluate and improve the stability and
efficiency of the process, considering the increased interaction and
dependency. Simulation can be applied at any stage, from the design phase to
after the go-live stage.
The Simulation,
which can be applied before the design stage, even after the go-live stage, is
needed.
- Terminal
layout, Equipment types, Simulation, which is configurable equipment quantity
- Possible to
apply the actual operating volume and operation patterns
- Need future
predictions about the current operation condition
- The Simulation
includes an equipment emulator
- Likely to use
a gate Import/Export volume pattern
- Possible to
process at least 200 times speed simulation (1month operation base, the
simulation result for 720 hours non-stop operation simulation needs to be
extracted within 4 hours max)
- Draw the
results that could confirm bottlenecks
- Includes
standard API for the equipment emulator – Compliance of TIC(Terminal Industry
Committee) 4.0 equipment layer (level 1) data standardization
The result below
is for applying a hybrid layout to terminals in the construction stage,
adjusting the transshipment ratio, and the scenario created in which the type
of equipment used and the number of equipment are changed.
- Apply yard layout “Vertical Layout / End
Loading” and “Horizontal Layout / Side Loading”
- Modify transshipment ratio (T/S ratio)
- Change the equipment type and quantity
Scenario definition for the simulation
|
Comparison |
Scenario |
Quay |
Mover |
Yard |
T/S | ||||
|
STS Q’ty |
BackReach Lane Q’ty |
Mover Type |
Mover Q’ty |
Block Q’ty |
YC Q’ty |
End Loading Block |
T/S Rate |
||
|
AGV Operation |
1a |
8 |
4 |
AGV |
36 |
16 |
32 |
50% |
50% |
|
1b |
8 |
|
|
|
|
|
50% |
50% |
|
|
1c |
8 |
|
|
|
|
|
50% |
50% |
|
|
1d |
8 |
|
|
|
|
|
50% |
50% |
|
|
Lift-AGV Operation |
2a |
8 |
|
|
|
|
|
50% |
50% |
|
2b |
8 |
The data has been treated as confidential. Please contact CyberLogitec for more information. |
50% |
50% |
|||||
|
2c |
8 |
50% |
50% |
||||||
|
2d |
8 |
50% |
50% |
||||||
|
End Load
Ratio |
3a |
8 |
|
|
|
|
|
100% |
50% |
|
T/S Ratio |
4a |
8 |
|
|
|
|
|
50% |
70% |
|
4b |
8 |
|
|
|
|
|
50% |
60% |
|
|
4c |
8 |
|
|
|
|
|
50% |
40% |
|
|
4d |
8 |
|
|
|
|
|
50% |
30% |
|
|
Block Q’ty |
5a |
8 |
|
|
|
|
|
50% |
50% |
|
B/R Qty |
6a |
8 |
|
|
|
|
|
50% |
50% |
Please find
below a breakdown of the analysis results from 15 different operation scenarios
regarding average gang productivity, peak time productivity decline ratio, and
operation time increase ratio compared to total gross operating time. The
impact of peak time productivity decline is more critical for terminal
operations than the off-peak period productivity decline of yard capacity and
equipment.
• Gang Productivity = Total Container Moves
(VAN) / Gross Gang Operation Time (Total gross working time from all of applied
STS)
• GI (Gang Intensity) = Gross Gang
Operation time / Gross working time (The operation time of STS which has the
longest working time)
The average GI
is 2.43 in scenario “1c” Derive Peak time Productivity of the vessel experiencing
bottlenecks based on GI value
• High GI Productivity (Peak time
Productivity) = Gang Productivity of the vessel which has more than GI value
3.0
When Peak time productivity
decreases by more than 10%
100% end
loading only operation (Scenario 3a) experienced the most decline in Peak time
productivity (15.65%)
When
quantity of assigned mover is less (Scenario 1a – AGV x 36, Scenario 2a – LAGV x 32)
When
transshipment ratio is below 50% (Scenario 4c – T/S 40%, Scenario 4d – T/S 30%)
Scenario-wise AGV Productivity and Waiting time
|
Comparison |
Scenario |
Agv
total waiting
time (m:s) |
Agv Productivity |
Agv waiting
rate |
Agv
total traveling
distance (m) |
Agv un-laden
Rate |
|
AGV Q'ty |
1a |
8:55 |
4.9 |
67.5% |
916 |
49.5% |
|
1b |
|
|
|
|
|
|
|
1c |
|
|
|
|
|
|
|
1d |
|
|
|
|
|
|
|
LAGV Q'ty |
2a |
|
|
|
|
|
|
2b |
The data has been treated as confidential. Please contact CyberLogitec for more information. |
|||||
|
2c |
||||||
|
2d |
||||||
|
End Loading |
3a |
|
|
|
|
|
|
T/S Ratio |
4a |
|
|
|
|
|
|
4b |
|
|
|
|
|
|
|
4c |
|
|
|
|
|
|
|
4d |
|
|
|
|
|
|
|
Block Q'ty |
5a |
|
|
|
|
|
|
B/R Q'ty |
6a |
|
|
|
|
|
Productivity comparison by AGV quantity
|
Category |
KPI |
AGV |
|||
|
36 (1a) |
40 (1b) |
44 (1c) |
48 (1d) |
||
|
Productivity |
Gross Gang Productivity |
31.84 |
|
|
|
|
(High GI) Gross Gang Productivity |
28.28 |
|
|
|
|
|
(High GI) Productivity decline ratio |
11.19% |
|
|
|
|
|
STS |
Average Gang Intensity |
2.45 |
The data has been treated as confidential. Please contact CyberLogitec for more information. |
||
|
Average Gang Operation time (h:m) |
10:42 |
||||
|
(High GI) Average Gang Operation Time |
19:29 |
||||
|
STS utilization rate |
42.7% |
|
|
|
|
|
YC |
YC Productivity |
|
|
22.15 |
|
|
Average Moving Bay (bay) |
|
|
7.15 |
| |
|
YC utilization rate |
|
|
38.6% |
| |
|
Mover |
Mover Productivity |
|
|
4.60 |
|
|
Mover utilization rate |
|
|
42.3% |
| |
|
(Discharge) STS waiting time |
|
|
5:24 |
| |
|
(Discharge) YC waiting time |
|
|
2:52 |
| |
|
(Loading) STS waiting time |
|
|
|
6:14 | |
|
(Loading) YC waiting time |
|
|
|
5:23 | |
|
Average mileage |
|
|
|
944 | |
|
Average empty mover rate |
|
|
|
48.4% | |
|
Yard |
Average Yard occupancy rate |
|
|
|
52.9% |
|
Gate |
Average OTR Turn Time |
|
|
|
10:41 |
Integrated
operation simulation is a type of simulation that is useful throughout the
whole process of a project, from its initial design stage to its post-go-live
operation stage. This simulation allows you to test various scenarios, with
free configuration options for terminal layout, equipment type, and quantity.
By processing the simulation and applying the operation strategy provided as an
outcome from the previous simulation, you can contribute to continuous
operation improvement.
CyberLogitec
offers a simulation solution that supports all stages of terminal yard design,
equipment selection, and operation optimization. OPUS Solutions can help
improve productivity and system integration through simulation before the
terminal's opening and continuous simulation tailored to the changing operating
environment.
