KR20130050457A - Marine growth preventing system and sea water supplying system and ship having the same - Google Patents

Abstract

PURPOSE: A seawater processing device, a seawater supply system, and a ship with the same are provided to reduce marine pollution by reducing the consumption of copper and aluminum electrode bars. CONSTITUTION: A ship comprises a seawater supply system(20) which has a seawater processing device. The seawater processing device processes seawater which is supplied to the ship and comprises electrode bars and a control part. The control part supplies a current to the electrode bars and controls the current strength according to a seawater flow rate which is supplied to the ship.

Description

Marine treatment apparatus and seawater supply system and vessel having same {MARINE GROWTH PREVENTING SYSTEM AND SEA WATER SUPPLYING SYSTEM AND SHIP HAVING THE SAME}

The present invention relates to a seawater treatment apparatus and a seawater supply system and a vessel having the same, and to a vessel for sterilizing marine life by introducing seawater, and using the sterilized seawater in a vessel and then outflowing into the sea.

In ships, sea water supply is essential for engine cooling and BALLAST. However, there is a problem that the seawater supply site is not effective in the outflow of seawater due to breeding of marine organisms, the consumption of fuel is increased, and the corrosion is increased. In other words, the effective consumption of seawater is prevented, and the engine cooling efficiency is lowered, and fuel consumption is increased. In addition, the cost of repair and repair is increasing due to the increase of corrosion caused by marine organisms.

Therefore, the ship needs to reduce the operation cost of the ship by using the seawater treatment device to sterilize the marine life of the seawater and prevent corrosion of the pipe. In general, seawater treatment devices generate current in copper and aluminum (or iron) electrodes to allow copper ions to be released from the copper electrodes, and aluminum hydroxide to be emitted from the aluminum electrodes. Copper ions sterilize marine life, and aluminum hydroxide forms a thin film on the pipe to prevent corrosion. A constant current flows in the copper and aluminum electrodes according to a preset current value, and thus the electrodes are consumed.

However, even if the vessel does not require much seawater, the seawater treatment device supplies a constant current to generate copper ions and aluminum hydroxide from the electrode. This sterilized seawater is dumped into the sea without being supplied to ships, which can cause marine pollution.

Accordingly, as described below, a system for treating seawater by directly electrolyzing seawater without using a seawater treatment device having an electrode electrode has been developed. However, in order to apply the new system to a ship, the structure of a conventional vessel is changed. There are various problems such as the need to do.

Patent Document 1: Korean Patent Publication No. 2008-0057469 (Published June 25, 2008) Patent Document 2: Republic of Korea Patent Publication No. 2010-0057644 (published May 31, 2010)

SUMMARY OF THE INVENTION An object of the present invention is to provide a seawater treatment apparatus capable of adjusting the throughput of seawater according to the amount of seawater supplied using the existing seawater treatment apparatus, and a seawater supply system and a vessel having the same.

According to one aspect of the present invention, a ship has a seawater supply system for supplying seawater to a ship, wherein the seawater supply system includes a seawater treatment device for treating seawater supplied to the ship, and the seawater treatment device includes: And an electrode; and a controller for supplying current to the electrode, wherein the controller can control the current intensity supplied to the electrode according to the flow rate of seawater supplied to the vessel.

The seawater supply system may further include a seawater pump for pumping seawater, and the controller of the seawater treatment device may control the current intensity supplied to the electrode according to the seawater flow rate pumped by the seawater pump.

The apparatus may further include a cooling system connected to the seawater supply system to exchange heat with seawater and fresh water. The control unit of the seawater treatment apparatus may control the current intensity supplied to the electrode according to the cooling demand of the cooling system. .

The cooling system may further include a valve configured to control an amount of heat exchange between seawater and fresh water, and the controller of the seawater treatment device may control the current intensity supplied to the electrode according to the opening / closing amount of the valve.

The cooling system may include a temperature sensor measuring a temperature of fresh water, and the controller of the seawater treatment device may control the current intensity supplied to the electrode according to the measured value of the temperature sensor.

In addition, the electrode may be formed of an aluminum (AL) electrode.

In addition, the electrode may be formed of a copper (Cu) electrode.

The apparatus may further include a ship balancing system connected to the seawater supply system to balance the vessel by receiving seawater, wherein the controller of the seawater treatment device is configured to supply current to the electrode according to the seawater demand of the ship balancing system. Can be controlled.

On the other hand, a seawater supply system according to another aspect of the present invention is a seawater supply system for supplying seawater to the ship, the seawater supply system, including a seawater treatment device for processing seawater supplied to the vessel; The apparatus includes an electrode; and a controller for supplying current to the electrode, wherein the controller can control the current intensity supplied to the electrode according to the flow rate of seawater supplied to the vessel.

On the other hand, the seawater treatment apparatus according to another technical idea in the seawater treatment apparatus for processing seawater supplied to the vessel, including an electrode; and a controller for supplying a current to the electrode rod, the control unit is supplied to the vessel The strength of the current supplied to the electrode can be controlled according to the flow rate of the seawater.

On the other hand, a vessel according to another technical concept includes a seawater treatment device for treating seawater supplied to the vessel in a ship having a plurality of operation modes, the seawater treatment device, the electrode rod; and the current to the electrode rod And a control unit for supplying the control unit. The control unit of the seawater treatment device may adjust the current intensity supplied to the electrode rod according to the plurality of operation modes.

Seawater treatment apparatus according to an embodiment can reduce the consumption of copper and aluminum electrode can reduce the marine pollution.

In addition, it is possible to prevent the formation of excess aluminum film in the pipe to prevent the seawater pipe from narrowing.

In addition, the oil can be effectively flowed in and out, thereby reducing fuel consumption.

1 is a view showing a cooling system and a sea water supply system included in a ship according to an embodiment.
2 is a view showing in more detail the seawater treatment apparatus according to an embodiment.
3 is a view showing a cooling system and a sea water supply system included in a ship according to another embodiment.
4 is a view showing a cooling system and a sea water supply system included in a ship according to another embodiment.
5 is a view showing a seawater treatment apparatus and a vessel having a plurality of operating modes according to another embodiment.

Hereinafter, a seawater treatment apparatus and a seawater supply system and a vessel having the same according to an embodiment will be described in detail with reference to the accompanying drawings.

1 is a view showing a cooling system and a seawater supply system included in a ship according to an embodiment, Figure 2 is a view showing a seawater treatment apparatus according to an embodiment.

As shown in Figures 1 and 2, the vessel may comprise a cooling system 10 for cooling the engine, and a seawater supply system 20 for supplying seawater to the vessel.

The cooling system 10 includes a heat exchanger 11 for exchanging fresh water with seawater and a fresh water pump 12 for pumping the exchanged fresh water.

The heat exchanger 11 exchanges fresh water with cold seawater. The fresh water pump 12 pumps cold fresh water to be sent to various places of the ship. Accordingly, the fresh water moves to the generator engine 13, the main engine 14, and the place 15 where cooling is required, to cool the generator engine 13, the main engine 14, and the like, and then to the main engine jacket 16. Move to cool the main engine jacket 16. After the portion of the fresh water that is heated again goes to the valve 17 without passing through the heat exchanger 11, and the rest moves to the valve 17 after heat exchange with cold sea water while passing through the heat exchanger (11).

The cooling system 10 also includes a valve 17 provided in front of the fresh water pump 12 and a temperature sensor 18 provided behind the fresh water pump 12.

The temperature sensor 18 measures the temperature of the fresh water pumped by the fresh water pump 12. The valve 17 is formed as a three-way valve and receives a signal from the temperature sensor 18 to adjust the heat exchange amount between the fresh water and the sea water. For example, when the temperature of the fresh water measured by the temperature sensor 18 is higher than the reference value, the valve 17 increases the inflow rate of the fresh water heat-exchanged with the sea water. On the contrary, when the temperature of the fresh water measured by the temperature sensor 18 is lower than the reference value, the valve 17 reduces the inflow amount of the fresh water heat-exchanged with the sea water.

The seawater supply system 20 includes a seawater tank 21 in which seawater is stored, a seawater pump 22 for pumping seawater stored in the seawater tank 21, and a seawater tank 21 and a seawater pump 22. It is comprised including the seawater treatment apparatus 30 provided in the.

The seawater pump 22 supplies seawater to the heat exchanger 11 of the cooling system 10. In the heat exchanger 11, the cold sea water supplied by the sea water pump 22 and the fresh water circulating in the cooling system 10 are heat exchanged. The heat exchanged seawater is then dumped into the sea.

The seawater treatment device 30 sterilizes seawater organisms while the seawater moves from the seawater tank 21 to the seawater pump 22, and coats the pipe 23 through which the seawater moves to prevent corrosion. The seawater treatment apparatus 30 includes the electrode rods 31 and 32 and a control unit 33 for supplying current to the electrode rods 31 and 32.

The electrode rod 31 includes a copper (Cu) electrode rod 31 and an aluminum (AL) electrode rod 32. When current is supplied to the copper electrode 31, copper ions are released to sterilize marine organisms, and when current is supplied to the aluminum electrode 32, aluminum hydroxide is released to form a thin film on the pipe to prevent corrosion.

The controller 33 controls the current strength supplied to the electrodes 31 and 32. The controller 33 controls the current strength based on the flow rate of the seawater pumped by the seawater pump 22. That is, when the flow rate of the seawater pumped from the seawater pump 22 increases, the controller 33 increases the current intensity supplied to the electrodes 31 and 32. On the contrary, when the flow rate of the seawater pumped from the seawater pump 22 decreases, the controller 33 reduces the current intensity supplied to the electrodes 31 and 32. Accordingly, it is possible to prevent unnecessary consumption of the electrode rods 31 and 32 and to prevent excessive film formation on the pipe 23.

Hereinafter, operations of a seawater treatment apparatus, a seawater supply apparatus having the same, and a vessel according to an embodiment will be described.

In some cases, it may be necessary to increase the flow rate of seawater supplied to the ship during the ship's operation. For example, there may occur a case where the engine of the ship is overheated to increase the cooling efficiency of the cooling system 10. At this time, the temperature of the fresh water measured by the temperature sensor 18 of the cooling system 10 is higher than the reference value, and the signal of the temperature sensor 18 is transmitted to the valve 17. The valve 17 increases the inflow of fresh water heat-exchanged with the seawater, and the signal from the valve 17 is transmitted to the seawater pump 22. The seawater pump 22 increases the flow rate of pumping seawater stored in the seawater tank 21 in order to increase the heat exchange amount between seawater and fresh water, and the signal of the seawater pump 22 is a control unit 33 of the seawater treatment device 30. Is delivered. The control unit 33 of the seawater treatment device 30 increases the current intensity supplied to the electrode rods 31 and 32.

On the other hand, it may be necessary to reduce the flow rate of seawater supplied to the vessel during the operation of the vessel. For example, a case may occur where the engine of a ship is sufficiently cooled (or when the engine is in a stopped state) to lower the cooling efficiency of the cooling system 10. At this time, the temperature of the fresh water measured by the temperature sensor 18 of the cooling system 10 is lower than the reference value, the signal of the temperature sensor 18 is transmitted to the valve 17. The valve 17 reduces the inflow of fresh water heat-exchanged with the seawater, and the signal from the valve 17 is transmitted to the seawater pump 22. The seawater pump 22 reduces the flow rate of pumping seawater in order to reduce the heat exchange amount between seawater and fresh water, and the signal of the seawater pump 22 is transmitted to the controller 33 of the seawater treatment device 30. The control unit 33 of the seawater treatment device 30 reduces the current intensity supplied to the electrodes 31 and 32.

3 is a view showing a cooling system and a sea water supply system included in a ship according to another embodiment.

As shown in FIG. 3, the vessel may include a cooling system 10 for cooling the engine and a seawater supply system 20 for supplying seawater to the vessel. As such, the cooling system 10 and seawater supply system 20 of FIG. 3 have substantially the same components as the cooling system 10 and seawater supply system 20 of FIG. 1.

However, in FIG. 1, the controller 33 of the seawater treatment device 30 adjusts the current intensity supplied to the electrodes 31 and 32 according to the pumping flow rate of the seawater pump 22, but in FIG. 3, the seawater treatment device ( The controller 33 of 30 adjusts the current strength according to the opening and closing amount of the valve 17.

Accordingly, the cooling system 10 and the seawater supply system 20 of FIG. 3 operate as follows.

First, when the temperature of the fresh water measured by the temperature sensor 18 of the cooling system 10 is higher than the reference value, this signal is transmitted to the valve 17. The valve 17 increases the inflow rate of fresh water heat-exchanged with the seawater, and the signal of the valve 17 is transmitted to the seawater pump 22 and the controller 33 of the seawater treatment device 30. The seawater pump 22 increases the flow rate for pumping seawater stored in the seawater tank 21 in order to increase the heat exchange amount between seawater and fresh water, and the control unit 33 of the seawater treatment device 30 includes the electrode rods 31 and 32. Increase the current strength supplied to

On the other hand, if the temperature of the fresh water measured by the temperature sensor 18 of the cooling system 10 is lower than the reference value, this signal is transmitted to the valve 17. The valve 17 reduces the inflow rate of fresh water heat-exchanged with the seawater, and the signal of the valve 17 is transmitted to the seawater pump 22 and the control unit 33 of the seawater treatment device 30. The seawater pump 22 reduces the flow rate of pumping seawater in order to reduce the heat exchange amount between seawater and fresh water, and the control unit 33 of the seawater treatment device 30 reduces the current intensity supplied to the electrodes 31 and 32. Let's do it.

4 is a view showing a cooling system and a sea water supply system included in a ship according to another embodiment.

As shown in FIG. 4, the vessel may include a cooling system 10 for cooling the engine and a seawater supply system 20 for supplying seawater to the vessel. As such, the cooling system 10 and seawater supply system 20 of FIG. 4 have substantially the same components as the cooling system 10 and seawater supply system 20 of FIG. 1.

However, in FIG. 1, the controller 33 of the seawater treatment device 30 adjusts the current intensity supplied to the electrodes 31 and 32 according to the pumping flow rate of the seawater pump 22, but in FIG. 4, the seawater treatment device ( The control unit 33 of 30 adjusts the current intensity according to the temperature measurement value measured by the temperature sensor 18.

Accordingly, the cooling system 10 and the seawater supply system 20 of FIG. 4 operate as follows.

First, when the temperature of the fresh water measured by the temperature sensor 18 of the cooling system 10 is higher than the reference value, the signal is transmitted to the valve 17 and the control unit 33 of the seawater treatment device 30. The valve 17 increases the inflow of fresh water heat-exchanged with the seawater, and the signal from the valve 17 is transmitted to the seawater pump 22. The seawater pump 22 increases the flow rate of pumping seawater in order to increase the heat exchange amount between seawater and fresh water. The control unit 33 of the seawater treatment device 30 receives a signal from the temperature sensor 18 and increases the current intensity supplied to the electrodes 31 and 32.

On the other hand, if the temperature of the fresh water measured by the temperature sensor 18 of the cooling system 10 is lower than the reference value, the signal is transmitted to the valve 17 and the seawater treatment device 30. The valve 17 reduces the inflow of fresh water heat-exchanged with the seawater, and the signal from the valve 17 is transmitted to the seawater pump 22. The seawater pump 22 reduces the flow rate of pumping seawater in order to reduce the heat exchange amount of seawater and fresh water. And the control unit 33 of the seawater treatment device 30 receives a signal from the temperature sensor 18 to reduce the current strength supplied to the electrode (31, 32).

5 is a view showing a seawater treatment apparatus and a vessel having a plurality of operating modes according to another embodiment.

As shown in FIG. 5, the vessel has a plurality of modes of operation. The vessel may have a sea going mode 1 and a floating mode 2. When the vessel is in the rapid operation mode (1), the vessel requires a large amount of seawater, and in the berth operation mode (2), it is common that the vessel does not require a large amount of seawater.

Accordingly, the control unit 33 of the seawater treatment device 30 may adjust the current strength supplied to the electrode rods 31 and 32 according to the operation mode of the ship. When the vessel is in the rapid operation mode (1), since the amount of seawater is increased, the control unit 33 of the seawater treatment device 30 increases the current strength supplied to the electrodes (31, 32). On the other hand, when the vessel is in the berth operation mode (2), since the amount of seawater is reduced, the control unit 33 of the seawater treatment device 30 reduces the current intensity supplied to the electrodes (31, 32).

6 is a view showing a vessel having a vessel balancing system according to another embodiment.

As shown in FIG. 6, the vessel may include a vessel balancing system 40 for vessel balance (BALLAST). At this time, the seawater supply system 20 supplies seawater to the ship balance system 40 for the ship balance. In this case, the seawater treatment device 30 may adjust the current strength according to the seawater flow rate supplied to the vessel. That is, when a large amount of seawater flow rate is required to balance the vessel, the control unit 33 of the seawater treatment device 30 increases the current intensity supplied to the electrodes 31 and 32, and when the seawater flow rate is required, the seawater treatment device 30 The control unit 33 reduces the current intensity supplied to the electrode (31, 32).

1: rapid flight mode 2: anchored mode
10: cooling system 20: seawater supply system
30: seawater supply device 40: ship balancing system

Claims (11)

In a ship having a seawater supply system for supplying seawater to the ship,
The sea water supply system,
Includes; seawater treatment device for processing seawater supplied to the vessel,
The seawater treatment device,
Electrodes; and
And a controller for supplying current to the electrode.
The control unit is a vessel for controlling the current strength supplied to the electrode in accordance with the flow rate of the sea water supplied to the vessel. The method of claim 1,
The sea water supply system,
Further comprising: a sea water pump for pumping sea water,
The control unit of the seawater treatment device to control the current intensity supplied to the electrode rod in accordance with the seawater flow rate pumped by the seawater pump. The method of claim 1,
And a cooling system connected to the seawater supply system to heat-exchange seawater and fresh water.
The control unit of the seawater treatment device to control the current strength supplied to the electrode rod in accordance with the cooling amount of the cooling system. The method of claim 3,
The cooling system,
It includes; and a valve for controlling the heat exchange amount of seawater and fresh water,
The control unit of the seawater treatment device to control the current strength supplied to the electrode rod in accordance with the opening and closing amount of the valve. The method of claim 3,
The cooling system,
It includes; a temperature sensor for measuring the temperature of the fresh water,
The control unit of the seawater treatment device to control the current strength supplied to the electrode in accordance with the measured value of the temperature sensor. The method of claim 1,
The electrode rod is formed of aluminum (AL) electrode. The method of claim 1,
The electrode rod is formed of a copper (Cu) electrode. The method of claim 1,
And a ship balance system connected to the sea water supply system to balance the vessel by receiving sea water.
The control unit of the seawater treatment device is a vessel for controlling the current strength supplied to the electrode according to the seawater demand amount of the vessel balancing system. In the seawater supply system for supplying seawater to the ship,
The sea water supply system,
Includes; seawater treatment device for processing seawater supplied to the vessel,
The seawater treatment device,
Electrodes; and
And a controller for supplying current to the electrode.
The control unit is a seawater supply system for controlling the current intensity supplied to the electrode in accordance with the flow rate of the seawater supplied to the vessel. In the seawater treatment apparatus for treating seawater supplied to the vessel,
Electrodes; and
And a controller for supplying current to the electrode.
The control unit is a seawater treatment apparatus for controlling the current intensity supplied to the electrode in accordance with the flow rate of the seawater supplied to the vessel. In a ship having a plurality of modes of operation,
Includes; seawater treatment device for processing seawater supplied to the vessel,
The seawater treatment device,
Electrodes; and
And a controller for supplying current to the electrode.
The control unit of the seawater treatment apparatus for controlling the current intensity supplied to the electrode in accordance with the plurality of operation modes.

Images