KR20160023216A - Mgps anode current control system and method by change of sea flow rate of vessel, and vessel including the same - Google Patents

Abstract

A system for controlling a current of a marine growth prevention system (MGPS) anode in accordance with changes in a seawater flow rate of a ship, method therefor, and a ship having the same are disclosed. According to one embodiment of the present invention, the system for controlling the current of a MGPS anode in accordance with changes in a seawater flow rate of a ship comprises: a pump control unit controlling an operation rate of a seawater pump supplying seawater to a hull in accordance with a necessary amount of consumption; an MGPS unit generating an ion by a current to sterilize seawater introduced into the hull by the seawater pump and comprising a consumed anode; and an MGPS controller connected to the pump control unit to receive information on an introduction amount of the seawater inside the hull in accordance with the operation rate of the seawater pump from the pump control unit and controlling a current supply with respect to the anode in accordance with the introduction rate of the seawater in accordance with the information with respect to the introduction amount of the seawater.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an MGPS anode current control system and method, and a ship including the MGPS anode current control system,

[0001] The present invention relates to a system and method for controlling current of an MGPS anode according to a change in sea water flow rate of a ship due to a change in sea water flow rate of a ship, and to a ship including the same, and more particularly to a system for sterilizing seawater The present invention relates to an MGPS anode current control system and method, and a vessel including the MGPS anode current control system, and a method of controlling the MGPS anode current control system in accordance with a change in sea water flow rate of a ship, which can reduce consumption of an anode used in an MGPS.

Generally, a large number of equipment, such as a main engine, a generator engine, a boiler, a pump, an air conditioner, etc., are operated to operate a ship.

Each of these devices generates a lot of heat while operating. Cooling water is supplied to each unit to dissipate the generated heat. Some equipment may be air-cooled to cool through the air, but many units are water-cooled with a higher cooling efficiency.

Fresh water (FW) is used as a cooling water medium for directly absorbing heat in each equipment. This water for absorbing heat from each equipment exchanges heat with seawater through a heat exchanger and transfers heat to the seawater. As the seawater exits to the sea, it continuously dissipates heat generated from the ship.

Marine Growth Prevention System (MGPS) is a facility that can sterilize marine organisms (shellfish, seaweeds, marine microorganisms, etc.) in seawater supplied to ships. MGPS prevents seawater pipeline clogging by disinfecting marine life, thereby enabling smooth sea water inflow.

The operating principle of this MGPS is to supply a current to an anode provided with Cu (copper) and Al (aluminum), dissolve the anode with current, It is a way to sterilize.

In the past, the MGPS anode current dissipation method was used to set the current value recommended by the MGPS company, and a certain amount of anode is consumed by the constant current regardless of the flow rate of the sea water.

In the case of ships with ESS (Energy Saving System), since the sea water flow is changing in real time according to the heat load of ship (less flow than the design flow is always supplied), the following unwanted waste of the anode occurs .

In other words, as the ESS is driven, the flow rate of the seawater actually supplied to the ship may be 50% of the design flow rate. The MGPS will flow the current set in the 100% flow rate standard to the anode, .

As a result, excessive excess of Cu / Al in the seawater flows through the heat exchanger after being melted, resulting in waste of the anode.

In other words, the ESS performs the energy saving by supplying the required amount of the sea water to the ship, but the MGPS is always wasted at the anode by flowing the fixed current to the anode side.

Korean Patent Application No. 10-2014-0014913

According to one embodiment of the present invention, when the flow rate of the cooling seawater is adjusted in the ESS (Energy Saving System) according to the ship's operating conditions (required cooling water load in the ship), the MGPS anode The MGPS anode current control system and the MGPS anode current control system according to the change of the sea water flow of the ship which can reduce the operation cost of the ship due to the unnecessary consumption of the anode and the extension of the life of the anode (extension of maintenance and replacement cycle) Methods, and vessels containing them.

According to an aspect of the present invention, there is provided a pump control unit for controlling an operation rate of a seawater pump for supplying seawater to a hull according to a required consumption amount; A Marine Growth Prevention System (MGPS) unit having an anode consumed while generating ions by an electric current so as to sterilize seawater flowing into the hull by the seawater pump; And a pump control unit connected to the pump control unit to receive inflow amount information of the in-vessel water based on the operating rate of the seawater pump from the pump control unit, wherein the controller controls the current to the anode according to the inflow amount of the seawater based on the inflow amount information An MGPS anode current control system according to a change in seawater flow rate of a ship including an MGPS controller for controlling supply can be provided.

Wherein the pump control unit comprises: a pump drive for generating a signal for driving the seawater pump; And an Energy Saving System (ESS) for controlling the pump drive according to the required amount of seawater in the hull.

The MGPS unit includes an MGPS module having a CU (copper) anode and an AL (aluminum) anode, and disposed on an inflow line of the seawater, and the MGPS controller can be connected to the ESS.

Wherein the plurality of seawater pumps are disposed on the inflow line of the seawater and the ESS controls the driving speed or the operation ratio of at least one of the plurality of seawater pumps by the pump drive in accordance with the required seawater flow rate in the hull can do.

According to another aspect of the present invention, there is provided a method of recovering seawater, comprising: introducing seawater into a required place in a ship by a seawater pump; Adjusting the operation rate of the seawater pump by the pump control unit according to the required consumption amount of seawater; Sterilizing the seawater introduced by the seawater pump by an MGPS unit provided with an anode that generates ions while being consumed by the electric current and performs sterilizing action; Providing inflow amount information of the in-vessel seawater based on the operating rate of the seawater pump from the pump control unit to an MGPS controller for controlling supply of current to the anode; And controlling the current supply to the anode by the MGPS controller according to the inflow amount of the seawater according to the inflow amount information of the seawater. have.

In the MGPS anode current control method according to the present invention, the pump control unit includes: a pump drive for generating a signal for driving the seawater pump; And an ESS for controlling the pump drive according to the required amount of seawater in the hull, wherein the MGPS unit comprises an MGPS module having a CU (copper) anode and an AL (aluminum) And the MGPS controller may be connected to the ESS so that the MGPS controller may provide inflow information of the seawater.

In the MGPS anode current control method according to the present invention, the seawater pumps are disposed on the inflow line of the seawater, and the ESS controls the pump drive according to the required seawater flow rate in the hull, The driving speed or the operation ratio of at least one of the plurality of seawater pumps can be controlled by the control unit.

According to another aspect of the present invention, there is provided a sea chest unit disposed on an inlet side of a hull; A strainer unit connected to the body strut to filter the seawater; A seawater pump for flowing the seawater to a heat exchange site; A heat exchange unit for exchanging the seawater with equipment in the ship; And a sea water cooling system of the ship including the MGPS anode current control system in accordance with the change of the sea water flow rate of the ship described above.

According to another aspect of the present invention, a vessel including the seawater cooling system of the ship described above can be provided.

According to one embodiment of the present invention, when the flow rate of the cooling seawater is adjusted in the ESS (Energy Saving System) according to the operating condition of the ship (the required cooling water load in the ship), the MGPS anode is also required for the flow rate The MGPS anode current control system according to the change of the sea water flow of the ship which can reduce the operation cost of the ship due to the unnecessary consumption of the anode and the extension of the life of the anode (maintenance / replacement cycle extension) And a method, and a ship including the same.

FIG. 1 is a flow diagram of a MGPS anode current control system according to an embodiment of the present invention, in which a sea water flow rate is changed.

Various embodiments of the present invention will now be described by way of specific embodiments shown in the accompanying drawings. The differences between the embodiments of the present invention described below are to be understood as mutually exclusive. That is, the specific shapes, structures, and characteristics described may be embodied in other embodiments in accordance with one embodiment without departing from the spirit and scope of the present invention, It is to be understood that the arrangements may be altered, where like reference numerals refer to like or similar features throughout the several views, and length and area, thickness, and the like may be exaggerated for convenience.

1, according to an embodiment of the present invention, the MGPS anode current control system according to the present invention changes the operation rate of the sea water pump 106, which supplies seawater to the hull, according to the required consumption amount A Marine Growth Prevention System (MGPS) having an anode (111) consumed while generating ions by an electric current so as to sterilize seawater flowing into a ship by a seawater pump (106); And a pump control unit 100 connected to the pump control unit 100 to receive inflow volume information of the in-vessel water due to the operation ratio of the seawater pump 106, And an MGPS controller 120 for controlling the supply of current to the anode 111 according to the inflow amount of the anode 111.

According to this embodiment, the MGPS controller 120 receives the inflow amount information of the in-vessel sea water by the sea water pump 106 from the pump control unit 100, and calculates the consumption amount of the anode 111 The current to the anode 111 is controlled. Accordingly, the anode 111 generates ions corresponding to the inflow amount of the seawater, and unnecessary consumption of the anode 111 is prevented, so that consumption of the anode 111 can be saved.

That is, according to the present embodiment, the MGPS anode current control system according to the change of the seawater flow rate of the ship is controlled by the ESS (105, Energy Saving System) described below according to the operating conditions of the ship When the flow rate is adjusted, the system is configured so that the MGPS anode is also consumed as much as necessary for the corresponding flow rate, thereby preventing the unnecessary consumption of the anode and reducing the operating cost of the vessel due to the extension of the life of the anode (maintenance and replacement cycle extension) .

Hereinafter, the components of the MGPS anode current control system according to an embodiment of the present invention will be described in detail.

The pump control unit 100 according to the present embodiment includes a pump drive 102 for generating a signal for driving the seawater pump 106 and an ESS control unit 102 for controlling the pump drive 102 according to the required amount of seawater in the hull 105, Energy Saving System).

The pump drive 102 typically has a circuit that generates a drive signal that can control the drive speed of the motor and generates a drive signal while saving energy by the ESS 105.

In addition, the MGPS unit according to the present embodiment includes an MGPS module 115 provided with a CU (copper) anode 112 and an AL (aluminum) anode 113 and arranged on an inflow line of seawater. The MGPS controller 120 may be connected to the MGPS controller 120.

The MGPS module 115 allows the seawater introduced by the seawater pump 106 to pass through by the ions generated in the CU (copper) anode 112 and the AL (aluminum) anode 113 Sterilizing equipment.

The MGPS module 115 is connected to an MGPS controller 120 capable of controlling current supply to the CU (copper) anode 112 and the AL (aluminum) The MGPS controller 120 receives the inflow amount information of the seawater collected in the ESS 105 and controls the current to the CU (copper) anode 112 and the AL (aluminum) do.

A plurality of seawater pumps 106 according to the present embodiment are arranged on the inflow line of seawater and the ESS 105 is connected to the plurality of seawater pumps 106 by the pump drive 102 in accordance with the required seawater flow rate in the hull. The driving speed or the driving ratio of at least one of the driving speed and the driving ratio can be controlled.

That is, the ESS 105 can selectively operate a plurality of seawater pumps 106 so that seawater can be appropriately introduced corresponding to the required flow rate of heat exchange in the ship. In one example, the ESS 105 will drive all seawater pumps 106 at full speed when seawater is required at a maximum, and will operate one pump at a minimum speed if seawater is required at a minimum.

Hereinafter, a method for adjusting the MGPS anode current according to the change of the sea water flow of a ship applied to the MGPS anode current control system according to the above-described sea water flow rate change will be described.

Referring to FIG. 1, a method for adjusting an MGPS anode current according to an embodiment of the present invention includes a step of introducing seawater into a required place in a ship by a seawater pump 106, (100) that controls the operation rate of the seawater pump (106) by the pump control unit (100) in accordance with the necessary consumption amount of seawater; and an MGPS unit having an anode (111) (101) for controlling the supply of current to the anode (111) from the pump control unit (100); and a control unit To the controller 120 and controlling the supply of current to the anode 111 by the MGPS controller 120 according to the inflow amount of the seawater according to the inflow amount information of the seawater.

According to the present embodiment, the MGPS controller 120 receives the inflow amount information of the in-ship seawater by the seawater pump 106 from the pump control unit 100, and determines that the disinfection operation is performed according to the amount of the incoming seawater. The consumption of the anode 111 can be economically controlled by controlling the current to the anode 111. That is, the anode 111 generates ions corresponding to the inflow amount of the seawater, and unnecessary consuming of the anode 111 is prevented, so that consumption of the anode 111 can be saved.

According to the present embodiment, the pump control unit 100 includes a pump drive 102 for generating a signal for driving the seawater pump 106, an ESS The MGPS unit includes an MGPS module 115 provided with a CU (copper) anode 112 and an AL (aluminum) anode 113 and disposed on an inflow line of seawater, 120 may be connected to the ESS 105 so that the inflow volume information of the seawater is provided to the MGPS controller 120. A duplicate description of the operation of these components is omitted.

The MGPS controller 120 receives the inflow amount information of the seawater passing through the seawater pump 106 from the ESS 105 and transmits the inflow amount information of the CU (copper) in the MGPS module 115, And the ions generated in the CU (copper) anode 112 and the AL (aluminum) anode 113 are connected to the sea water for heat exchange To disinfect marine life in seawater.

A plurality of seawater pumps 106 are disposed on the inflow line of the seawater and the ESS 105 is connected to the at least one of the plurality of seawater pumps 106 by the pump drive 102 according to the required seawater flow rate in the hull. It is possible to control the driving speed or the operating ratio of the motor. At this time, the ESS 105 selectively drives the plurality of seawater pumps 106 or adjusts the driving speed so that the amount of seawater required for heat exchange is economically introduced.

According to an embodiment of the present invention, a sea chest unit (130) disposed at the inlet side of the hull, a strainer unit (140) connected to the sea cruise unit (130) A seawater pump 106 for circulating the seawater to the heat exchange place, a heat exchange unit 150 for exchanging seawater with the equipment in the ship, and a ship including the MGPS anode current control system according to the above- A seawater cooling system may be provided.

Accordingly, the sea water cooling system of the ship can draw seawater in accordance with the amount of seawater that can be used for heat exchange, consumes the anode 111 that generates ions for sterilization in accordance with the amount of seawater to be introduced, It is possible to save the node 111 and save energy for the anode 111 as well as reduce the number of operations for exchanging the anode 111. [

Meanwhile, according to an embodiment of the present invention, a vessel including the seawater cooling system of the above-described vessel can be provided. Since the sea water is properly introduced by the above-described sea water cooling system and the anode 111 is consumed and the electric current is used economically, it is advantageous in terms of saving energy.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Deletion, addition or the like of the present invention may be variously modified and changed within the scope of the present invention.

100: pump control unit 102: pump drive
105: ESS 106: Seawater pump
110: Marine Growth Prevention System (MGPS) unit
111: anode 112: CU (copper) anode
113: AL (aluminum) anode 115: MGPS module
120: MGPS controller 130:
140: Strainer unit 150: Heat exchange unit

Claims (9)

A pump control unit for controlling the operation rate of a seawater pump supplying seawater to the hull according to a required consumption amount;
A Marine Growth Prevention System (MGPS) unit having an anode consumed while generating ions by an electric current so as to sterilize seawater flowing into the hull by the seawater pump; And
The pump control unit is connected to the pump control unit so as to receive inflow amount information of the in-vessel seawater based on the operation rate of the seawater pump from the pump control unit, and controls the flow rate of the current supplied to the anode according to the inflow amount of the seawater based on the inflow amount information The MGPS anode current control system according to the change of the sea water flow of the ship including the MGPS controller that controls the MGPS. The method according to claim 1,
The pump control unit includes:
A pump drive for generating a signal for driving the seawater pump; And
And an ESS (Energy Saving System) for controlling the pump drive according to a required amount of seawater in the hull. 3. The method of claim 2,
The MGPS unit includes an MGPS module provided with a CU (copper) anode and an AL (aluminum) anode and disposed on an inflow line of the seawater,
Wherein the MGPS controller is connected to the ESS. The method of claim 3,
Wherein the seawater pumps are arranged in plural on the inflow line of the seawater,
Wherein the ESS controls the driving speed or the operation ratio of at least one of the plurality of seawater pumps by the pump drive according to a required seawater flow rate in the hull. Introducing seawater into a required area in the hull by means of a seawater pump;
Adjusting the operation rate of the seawater pump by the pump control unit according to the required consumption amount of seawater;
Sterilizing the seawater introduced by the seawater pump by an MGPS unit provided with an anode that generates ions while being consumed by the electric current and performs sterilizing action;
Providing inflow amount information of the in-vessel seawater based on the operating rate of the seawater pump from the pump control unit to an MGPS controller for controlling supply of current to the anode; And
And controlling the current supply to the anode by the MGPS controller according to the inflow amount of the seawater according to the inflow amount information of the seawater. 6. The method of claim 5,
The pump control unit includes:
A pump drive for generating a signal for driving the seawater pump; And
And an ESS for controlling the pump drive in accordance with the required amount of seawater in the hull,
The MGPS unit includes an MGPS module having a CU (copper) anode and an AL (aluminum) anode, and disposed on an inflow line of the seawater, A method for regulating MGPS anode current according to seawater flow rate of a ship connecting MGPS controller. The method according to claim 6,
Wherein the seawater pumps are arranged in plural on the inflow line of the seawater,
Wherein the ESS controls the driving speed or the operation ratio of at least one of the plurality of seawater pumps by the pump drive according to a required seawater flow rate in the hull. A sea chest unit disposed on the inlet side of the hull;
A strainer unit connected to the body strut to filter the seawater;
A seawater pump for flowing the seawater to a heat exchange site;
A heat exchange unit for exchanging the seawater with equipment in the ship; And
A marine water cooling system of a ship comprising a MGPS anode current regulation system according to any one of claims 1 to 4 as the seawater flow rate is changed. A ship comprising the sea water cooling system of the ship according to claim 8.

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