한국해양대학교

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전기식 추진체계 함정의 프로세서 레버 제어기 적용에 관한 연구

Title
전기식 추진체계 함정의 프로세서 레버 제어기 적용에 관한 연구
Alternative Title
A Study of Processor Lever Controller for Warship Electric Propulsion System
Author(s)
심재순
Keyword
Electric propulsion systemProcessor leverNaval vessel
Issued Date
2020
Publisher
한국해양대학교 대학원
URI
http://repository.kmou.ac.kr/handle/2014.oak/12537
http://kmou.dcollection.net/common/orgView/200000340256
Abstract
With the advent of a high-power weapon system, the propulsion system of
the naval ship is shifting from a mechanical propulsion system to an electric
propulsion system with the aim of strengthening anti-submarine capabilities and
reducing the operating cost of the ship.
An efficient control logic design that can satisfy the operational requirements
of the ship while preventing over-torque and overload of the shaft and
propulsion engine is essential for the propulsion control system of the ship. It
is common to optimize the propulsion control system through a so-called
tuning process that modifies the parameter values of the propulsion control
software during a test run. As with the ship control system, PI controllers are
generally widely used in the propulsion control system of the ship to control
shaft rotational speed, and by adjusting the P and I setting values during a test
run, the transient state is improved and the stable propulsion control state is
set. However, during this process, if the error of the initial setting value is
large, the tuning time may take too long, or the propulsion equipment can be
seriously damaged due to over-torque, over-speed and over-power. Especially,
since the electric propulsion system has a higher power increase/decrease
speed than the mechanical propulsion system, there is a high possibility of
mechanical damage. In addition, the problem caused by the occurrence of
regenerative power must be taken into account. Therefore, in this study, we
conducted research on the design of a propulsion controller that applied a
Processor lever even for inexperienced people with relatively little experience
in tuning propulsion control software to be able to reduce the tuning time while
protecting the propulsion system.
To this end, we performed ship form and propulsion system modeling that
could calculate the power, torque and revolutions of the propulsion system,
thrust of propeller, and speed according to the change in thrust. We also
verified the stability and reliability of the Processor lever controller by
developing a propulsion controller model applying a Processor lever controller.
In simulations, the propulsion controller model performs the propulsion motor,
controllable pitch propeller, and rudder control. The propulsion motor model that
receives control commands generates torque, and the propulsion shaft model
determines the number of shaft revolutions by rotating the propulsion shaft
through the calculation of the torque generated from the propulsion motor, the
speed of the ship, the pitch of the controllable pitch propeller, the difference
between the torque according to the rotation speed. Based on the advance ratio
according to the rotation speed and pitch angle, the ship model finally
calculates the thrust, and determines the speed according to the thrust and the
current speed of the ship.
Through this dynamic simulation, by comparing the execution result of
propulsion control lever commands through the PI controller without applying
the Processor lever controller with that of propulsion control lever commands
through the PI controller applying the Processor lever controller, we analyzed
the improvement of the Overshoot and propulsion performance.
The simulation results showed that the safety of the propulsion system
increased because Overshoot of approximately 9.74%, which occurred when the
Processor lever function was not applied, did not occur. However, the
propulsion performance (acceleration) of the ship decreased as the system
responded slowly. We confirmed that the reduction in propulsion performance
could be addressed stably by adjusting the parameter values of the Processor
lever.
In order to secure the maneuverability required for combat performance, the
electric propulsion system of the ship should adopt a high-power propulsion
motor relative to the propulsion shaft load, and secure high acceleration and
deceleration performance. In order to solve equipment safety problems that
could occur during the tuning process of the propulsion control system and to
reduce the tuning period, which are attributed to these characteristics, we suggested a Processor lever controller application method.
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기관공학과 > Thesis
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