KR20170009336A - System and Method for Ship Energy Efficiency Optimization - Google Patents

Abstract

According to an aspect of the present invention, a system for optimizing energy efficiency of a main engine (ME) and an auxiliary engine (GE) of a vessel includes: a generation unit generating power using the main engine (ME), the auxiliary engine (GE), and a waste heat collector (10); a detecting unit detecting a power generation amount generated in the vessel and a propulsion generated by the main engine (ME); and a control unit inputting a signal of the generation unit and the detecting unit and integrally controlling SFOC of the main engine (ME) and the auxiliary engine (GE). Therefore, the system for optimizing energy efficiency of a vessel can reduce discharge of pollutants and can save fuel by optimally distributing a load of a generation engine, a shaft generator/a motor, a WHRS, and the main engine for FOC and generating the power of the same output using the minimum fuel.

Description

System and Method for Ship Energy Efficiency Optimization

More particularly, the present invention relates to a ship energy efficiency optimization system for optimally distributing and operating a load of a main engine, a WHRS, a shaft generator / motor, and a power generation engine so as to apply a minimum FOC ≪ / RTI >

To improve the fuel consumption of the engine room, WHRS (Waste Heat Recovery System) using waste heat of the engine is applied. It drives the main engine that generates the required propulsive force, turbine power to the exhaust gas, shafts to generate additional power, and power generation engine to produce additional power if necessary. Surplus power is used again for propulsion using shaft motor .

Traditionally, propulsion systems and power generation systems are separated on ships. Recently, in order to increase energy efficiency, the propulsion system uses waste heat to generate electricity and the remaining electricity is being used for propulsion.

Thus, the propulsion system of the ship and the method of driving the power generation system operate according to a predetermined sequence to generate the required propulsion and power generation. For example, the ME load is determined according to the required thrust, and WHRS is generated by the steam that can be generated at that time.

However, according to this method, the required driving force and power can be met, but since the optimal fuel consumption is not considered, there is a great opportunity for improvement in terms of meeting the driving force and electric power required for the minimum fuel. For example, by increasing the load on the main engine to produce more power and lowering the load on the GE, or conversely, lowering the load on the main engine and increasing the load on the GE can be more effective for fuel use. Therefore, the conventional method driven only in a predetermined order is inefficient.

The following prior art document 1 includes a step of generating a computer simulation model of a ship optimized for fuel efficiency, in which the equations are selected from a pool of equations depicting the ship's core components and structural characteristics, Lt; RTI ID = 0.0 > of the core data < / RTI >

According to the preceding Prior Art 2 described below, there is provided a power supply system including at least two generator sets each including a prime mover and a generator, an electric propulsion unit, an energy storage unit, and a main switchboard, , The electric propulsion unit, and the energy storage unit are connected to each other.

However, according to the above-mentioned prior art document 1, since the energy optimization simulation is performed in the drying process of the ship, it is limited to apply to the navigation process. According to the preceding document 2, the generator is over- The FOC reduction effect is insufficient.

1. Korean Patent Publication No. 2008-0063273 "Optimization of Energy Sources in Ships" (Published on July 23, 2008). 2. Korean Registered Patent Publication No. 2014-0046441 "Improvement in Fuel Efficiency of Ship Propulsion Engine" (Published Date: April 4, 2014).

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-mentioned problems of the prior art by implementing an engine room in which a load of a main engine, a WHRS, a shaft generator / And to provide a system and method for optimizing ship energy efficiency.

To achieve the above object, according to one aspect of the present invention, there is provided a system for optimizing energy efficiency of a cycle engine and a view engine of a ship, comprising: a cycle engine, a view engine, Detecting means for detecting an impulse by the periodic engine and an amount of power generated in the ship; And control means for inputting signals of the power generation means and the detection means and integrally controlling the SFOC of the cycle engine and the view engine.

In the detailed configuration of the present invention, the control means stores SFOC data for each output load for the cycle engine and the view engine, and updates the SFOC data for each set load period.

In the detailed configuration of the present invention, the control means is further connected to the power generation means to further include a storage battery for storing and drawing electric power, thereby reducing the SFOC.

According to another aspect of the present invention, there is provided a method of optimizing energy efficiency using the system of claim 1, comprising the steps of: (S10) collecting SFOC reference values by output load of each component; Inputting a required thrust and an amount of power generation (S20); Deriving a combination of the output load and SFOC of each component (S30); Selecting an optimum value among the output load-SFOC combinations (S40); And operating each component at an optimum value (S50).

In a detailed configuration of the present invention, the components include a cycle engine, a shaft generator motor of the cycle engine, a view engine, a generator of a view engine, and a generator of a waste heat recoverer.

In the detailed configuration of the present invention, the step S20 calculates the thrust by at least one of the wire speed, the number of revolutions of the periodic engine, and the load sensor, and the power generation amount is calculated by the power generation sensor installed in the constituent element.

As a detailed configuration of the present invention, the steps S30 to S50 are performed based on an algorithm set to drive with a minimum SFOC while satisfying the required thrust and power generation.

As described above, according to the present invention, since the main engine, the WHRS, the shaft generator / motor, and the power of the power generation engine are optimally distributed in the FOC aspect, the same power of the same output is produced with a minimum amount of fuel. There is a reduction effect.

1 is a block diagram schematically illustrating an optimization system according to the present invention;
2 is a flowchart showing the main steps of the optimization method according to the present invention;
3 is a graph showing the operating concept of the optimization method according to the present invention

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

According to one aspect of the present invention, a system for optimizing the energy efficiency of a cycle engine (ME) and a view engine (GE) of a ship is proposed. The cycle engine (ME) has a shaft generator motor (SG / SM) coupled to the propeller. The view engine GE is installed in a plurality of units and has a respective generator (G).

According to the present invention, the power generation means is a structure in which power is generated to the cycle engine (ME), the view engine (GE), and the waste heat collector (10). 1 shows a state in which the periodic engine ME develops into a shaft generator motor SG / SM, the view engine GE develops into a generator G and the waste heat recoverer 10 develops into a generator G For example. The electricity generated by each of these components is utilized as the power load (LE) of the ship. The exhaust gas of the periodic engine ME is sent to the waste heat recoverer 10 to generate steam, drive the steam turbine, and send it to the economizer 12 to be used as a steam load LS of the ship.

Further, according to the present invention, the detection means detects the propulsive force by the periodic engine (ME) and the generation amount generated in the ship. In Fig. 1, the detection means is exemplified by the rpm sensor 22, the load detection sensor 24, and the generation detection sensor 26. the rpm sensor 22 detects the shaft rotation number of the periodic engine ME and the load detection sensor 24 detects the power load LE and the generation detection sensor 26 detects the power amount of each generator G .

According to the present invention, the control means inputs the signals of the power generation means and the detection means to integrally control the SFOC (Specific Fuel Oil Consumption) of the cycle engine (ME) and the view engine (GE). The control means includes a microprocessor, a memory, and a controller 32 of a microcomputer circuit having an I / O interface. The control unit 32 may include a communication unit 34 and a DB server 36 as control means. The algorithm for integrally controlling the SFOC of the cycle engine (ME) and the view engine (GE) is mounted in a memory and can be clearly understood with reference to Figs. 2 and 3 which will be described later.

At this time, if the complexity of the system becomes high, the controller 32 can fetch and store a considerable amount of data from the DB server 36 through the communication unit 34. [

In the detailed configuration of the present invention, the control means stores SFOC data for each output load for the period engine (ME) and the view engine (GE), and updates the SFOC data for each set load period. Specific fuel rate (SFOC) data for the output load of the cycle engine (ME) and the view engine (GE) correspond to the graph illustrated in FIG. The cycle engine (ME) and the view engine (GE) decrease in SFOC from point A to point B. However, it is desirable to update the SFOC data due to aging of the cycle engine (ME) and the view engine (GE).

As a detailed configuration of the present invention, the control means further includes a battery (15) connected to the power generation means for storing and drawing electric power, thereby reducing the SFOC. The battery 15 generates and stores idle power in the process of attempting to reduce the SFOC of the engine and suppresses an increase in the SFOC of the engine by providing power at the time of a sudden increase in the driving force or the power load LE.

According to another aspect of the present invention, a method for optimizing energy efficiency using the system of claim 1 is proposed. The same holds for the detection means and the control means in addition to the cycle engine ME, the shaft generator motor SG / SM, the view engine GE, the waste heat recoverer 10, the generator G and the like.

Step S10 of the present invention proceeds to a step of collecting the SFOC reference value for each output load of each component. The reference value data such as the graph illustrated in FIG. 3 is stored in the memory of the controller 32 and is periodically updated. In many view engines (GE), the SFOC reference values for the output loads are set to be different from each other.

As a detailed configuration of the present invention, the components include a generator of a cycle engine ME, a shaft generator motor of a cycle engine ME, a generator of a view engine GE, a generator of a view engine GE, and a generator of a waste heat collector 10 . SFOC data is basically directly related to the cycle engine (ME) and the view engine (GE), but it is better to consider the indirect effects of the shaft generator motor and multiple generators.

Step S20 of the present invention proceeds to input of required thrust and power generation amount. The required thrust and power generation are stored and updated in the memory of the controller 32 at the set intervals. The demand propulsive force is basically handled by the cycle engine (ME), but the shaft generator motor (SG / SM) and the generators are used together. The required power generation amount is basically achieved by the generators, but the shaft generator motor (SG / SM) of the cycle engine (ME) and the battery 15 are used in combination.

In the detailed configuration of the present invention, the step S20 calculates the thrust by at least one of the speed of rotation, the number of revolutions of the periodic engine ME, and the load sensor 24, . The propulsive force can be calculated using the line speed required by the operator or the signal of the rpm sensor 22. [ The power generation amount can be integrally calculated by individually inputting the signals of the power generation detection sensors 26 provided in the plurality of generators. In addition, the signal of the load detection sensor 24 may be alternatively / concurrently used for calculating the power generation amount.

Step S30 of the present invention proceeds to derive the combination of the output load and SFOC of each component. In the case of the system of the present invention, propulsion / power generation can be performed in the cycle engine (ME), and propulsion / power generation can be performed through a generator such as a view engine (GE). Accordingly, there may be a plurality of combinations of methods for satisfying the necessary thrust and generation power (generation amount). The combination of the load sharing between the waste heat recovery unit 10 and the view engine (GE) in each of the conditions that maintain the load of the cycle engine (ME) at 60%, 70%, 80%, and 90% (ME) and the waste heat recoverer 10 are shared by the conditions that maintain the load imposed by the view engine (GE) at 60%, 70%, 80%, and 90%, respectively, A plurality of combinations may be set. Of course, since the waste heat recoverer 10 is dependent on the cycle engine ME and maintains the proportional relationship, the number of combinations can be limited to a certain extent.

Step S40 of the present invention proceeds to a process of selecting an optimum value among the output load-SFOC combinations. As mentioned above, each component has different SFOC efficiency by load. Therefore, the optimal combination of driving with minimum FOC must be selected to produce the required thrust and power. The optimal value is changed in conjunction with the fluctuation of the propulsive force and the power generation force required during the operation of the ship. In this manner, the data accumulated during the operation can be limited in the calculation time by gradually limiting the number of the output load-SFOC combinations.

Step S50 of the present invention proceeds to a process of operating each component at an optimum value. The controller 32 adjusts the load of each component under the condition of the selected combination, and this is interlocked in correspondence with the demand thrust and the power generation amount inputted in step S20.

As a detailed configuration of the present invention, the steps S30 to S50 are performed based on an algorithm set to drive with a minimum SFOC while satisfying the required thrust and power generation. These algorithms identify the fuel consumption by the output of the system components, create a system load combination that can produce the required thrust and power, identify the fuel consumption for each combination, It is a series of subroutine programs to select and operate.

As shown in FIG. 3, the load of the cycle engine ME can be reduced and the load of the view engine GE can be increased to cover the same thrust and generation power. That is, the changed operating condition B has a higher LOAD-FOC efficiency than the operating condition A before the change.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

ME: Cycle Engine GE: View Engine
G: generator LS; Steam load
LE: Power load 10: Waste heat recovery (WHRS)
12: Economizer 15: Battery
22: rpm sensor 24: load detection sensor
26: power generation detection sensor 32: controller
34: communication unit 36: DB server

Claims (7)

A system for optimizing the energy efficiency of a cycle engine (ME) and a view engine (GE) of a ship, comprising:
Power generation means for generating power to the cycle engine (ME), the view engine (GE), and the waste heat recoverer (10);
Detection means for detecting thrust generated by the periodic engine (ME) and generation amount generated in the ship; And
And control means for inputting signals of the power generation means and the detection means and integrally controlling the SFOC of the cycle engine (ME) and the view engine (GE). The method according to claim 1,
Wherein the control means stores the SFOC data for each output load for the periodic engine (ME) and the view engine (GE) and updates the stored SFOC data at a set period. The method according to claim 1,
Wherein the control means further comprises a battery (15) connected to the power generation means for storing and drawing electric power, thereby reducing the SFOC. A method for optimizing energy efficiency using the system of claim 1,
Collecting an SFOC reference value by output load of each component (S10);
Inputting a required thrust and an amount of power generation (S20);
Deriving a combination of the output load and SFOC of each component (S30);
Selecting an optimum value among the output load-SFOC combinations (S40); And
And a step (S50) of operating each component at an optimum value. The method of claim 4,
Characterized in that said component comprises a generator of a cycle engine (ME), a shaft generator motor of a cycle engine (ME), a view engine (GE), a generator of a view engine (GE), a waste heat recoverer (10) Efficiency optimization method. The method of claim 4,
Wherein the step S20 calculates the thrust with at least one of the speed of rotation, the number of revolutions of the periodic engine ME, and the load sensor 24, and calculates the power generation amount with the power generation sensor 26 installed in the component. Energy efficiency optimization method. The method of claim 4,
Wherein the steps S30 to S50 are performed based on an algorithm set to drive with a minimum SFOC while satisfying the required thrust and power generation.

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