KR20180078090A - The cooling equipment and the cooling method for vessel's heating unit - Google Patents

Abstract

One embodiment of the present invention provides a cooling device of a heat radiating unit for a vessel, comprising: a heat radiating unit arranged in a vessel; a clean water circulating unit connected to the heat radiating unit, and including a clean water pump circulating the clean water cooling the heat radiating unit; a heat exchanging unit connected to the clean water circulating unit; a seawater supplying unit connected to the heat exchanging unit, and including a seawater pump supplying the seawater to the heat exchanging unit from the outside of the vessel; and a control portion for controlling operation of the seawater pump in accordance with a temperature difference between the clean water and the seawater.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cooling apparatus for a marine heating unit,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cooling apparatus and method for a marine heating unit, and more particularly, to a cooling apparatus and method for a marine heating unit for efficiently cooling a marine heating unit.

1 is a view showing a marine cooling device 10 according to the prior art.

1, a conventional marine cooling apparatus 10 includes a heating device 20, a fresh water pump 43, a seawater pump 55, and a control unit 70 for cooling the heat generator 20 . Other components can be found in the prior art (Korean Patent Laid-Open Publication No. 2013-0053352). The control unit 70 determines the temperature difference value between the inlet water temperature and the outlet water temperature of the cooler 60 and controls the fresh water pump 43 accordingly. Further, the control unit 70 controls the seawater pump 55 based on the fresh water temperature at the outlet of the cooler 60. That is, the marine cooling apparatus 10 according to the related art controls the seawater pump based on only the fresh water temperature.

On the other hand, the cooler 60 is manufactured to have a specific capacity. Certain capacities are manufactured to operate at maximum efficiency at specific temperature differences between seawater and fresh water. Therefore, the cooler 60 is operated at maximum efficiency by maintaining a specific temperature difference between the seawater and fresh water.

However, since the marine cooling apparatus 10 according to the related art controls the seawater pump 55 only with the fresh water temperature, there is a problem that the cooler 60 designed based on the temperature difference between fresh water and seawater is limited to operate at maximum efficiency .

It is an object of the present invention to provide a cooling apparatus and method for a marine heat generating unit for controlling a sea water pump according to the temperature difference between clear water and sea water.

In order to accomplish the above object, a cooling device of a ship heat generating unit according to an embodiment of the present invention includes a heat generating unit disposed in a ship, a water heater connected to the heat generating unit, A seawater supply unit including a fresh water circulation unit including a pump, a heat exchange unit connected to the fresh water circulation unit, a seawater pump connected to the heat exchange unit and supplying seawater from the outside of the ship to the heat exchange unit, And a controller for controlling the operation of the seawater pump according to the temperature difference between the fresh water and the seawater.

The heat exchange unit may further include a fresh water outlet port through which the fresh water flows, a fresh water outlet port through which the fresh water flows, a sea water inlet through which the seawater flows, and a sea water outlet through which the seawater flows out, A fresh water temperature sensor for measuring an outflow temperature of fresh water, and a seawater temperature sensor disposed at the seawater inlet for measuring an inflow temperature of the seawater.

The control unit may drive the seawater pump at a rated rotational speed when the temperature difference between the fresh water outflow temperature measured by the fresh water temperature sensor and the seawater inflow temperature measured by the seawater temperature sensor is substantially equal to a preset reference value, And when the temperature difference is larger than the reference value, the seawater pump is driven at a rotational speed greater than the rated rotational speed.

Also, the reference value is 4 캜, and the controller increases the number of rotations of the seawater pump as the temperature difference increases with reference to the reference value.

A cooling method for a ship heat generating unit according to an embodiment of the present invention includes a fresh water circulating unit connected to a heat generating unit disposed on a ship and circulating fresh water for cooling the heat generating unit, The present invention relates to a method of cooling a ship heat generating unit including a unit, a seawater supply unit including a seawater pump for supplying seawater for cooling the fresh water to the heat exchange unit, and a control unit, The method comprising the steps of: measuring a leachate outflow temperature to measure a leaking temperature; measuring a leachate inflow temperature of the seawater flowing into the heat exchange unit; And a seawater supply amount adjusting step of adjusting the number of revolutions of the pump.

When the temperature difference between the fresh water outflow temperature and the seawater inflow temperature is substantially equal to a preset reference value, the control unit drives the seawater pump at a rated rotation speed, and the temperature difference is less than the reference value The seawater pump is driven at a rotational speed greater than the rated rotational speed.

Also, the reference value is 4 캜, and the controller increases the number of rotations of the seawater pump as the temperature difference increases with reference to the reference value.

At the temperature difference between pre-set fresh water and sea water, the heat exchange unit can be operated at the maximum efficiency of production. The control unit can adjust the supply amount of seawater by adjusting the number of revolutions of the seawater pump based on the temperature difference between the fresh water outflow temperature and the seawater inflow temperature and the predetermined reference value. The control unit can drive the seawater pump so that the heat exchange unit is optimally operated in accordance with the refrigerating capacity by design. Therefore, unnecessary consumption of energy can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a marine cooling apparatus according to the prior art; FIG.
FIG. 2 is a view showing a cooling apparatus for a ship heat generating unit according to an embodiment of the present invention.
3 and 4 are views for explaining the operation of the control unit shown in FIG.
5 is a flowchart showing a cooling method of a ship heat generating unit according to an embodiment of the present invention.

Hereinafter, a cooling apparatus 1000 of a marine heat generating unit according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing a cooling apparatus 1000 of a marine heat generating unit according to an embodiment of the present invention.

2, a cooling apparatus 1000 of a heating unit for a ship according to an embodiment of the present invention includes a heating unit 100, a fresh water circulating unit 200, a heat exchanging unit 300, a seawater supplying unit 400, And a control unit 500. The cooling apparatus 1000 of the heating unit for a ship according to an embodiment of the present invention may further include a fresh water temperature sensor 600 and a seawater temperature sensor 700.

The heat generating unit 100 may be disposed on the ship. Here, the heat generating unit 100 may include a main engine (not shown), an auxiliary engine (not shown), a main generator (not shown), a secondary generator (not shown), and other electric devices have. Therefore, the heat generating unit 100 generates heat in accordance with its operation. That is, cooling is essential for the periodic and continuous operation of the heat generating unit 100.

The fresh water circulating unit 200 may be connected to the heat generating unit 100. The fresh water circulating unit 200 can circulate fresh water for cooling the heat generating unit 100. The fresh water circulation unit 200 may include at least a fresh water pump 210 and a fresh water pipe 230. The fresh water pipe 230 may be connected to the heat generating unit 100 and a heat exchange unit 300 described later. The fresh water pipe 230 can connect the heat generating unit 100 and the heat exchanging unit 300 to circulate fresh water.

The fresh water pump 210 may be disposed between the heat generating unit 100 and a heat exchange unit 300 described later. Further, the fresh water pump 210 may be connected to the fresh water pipe 230. The fresh water pump 210 can circulate fresh water through the fresh water pipe 230.

The heat exchange unit 300 may be connected to the fresh water circulation unit 200. Further, the heat exchange unit 300 may be connected to the seawater supply unit 400 described later. The heat exchange unit 300 includes a fresh water inlet 310 through which clear water flows, a fresh water outlet 330 through which clear water flows out, a sea water inlet 350 through which seawater flows, and a sea water outlet 370 through which seawater flows out. Lt; / RTI > The fresh water flows into the fresh water inlet 310 and flows out to the fresh water outlet 330. The seawater flows into the seawater inlet port 350 and flows out to the seawater outlet port 370. The seawater passing through the heat exchange unit 300 can cool the fresh water.

The heat exchange unit 300 may be separately manufactured and then disposed on the ship. The heat exchange unit 300 may have a specific cooling capacity Q. [ In one embodiment, the heat exchange unit 300 may have a cooling capacity Q determined according to the heat transfer coefficient U, the heat transfer area A, and the temperature difference T. [

That is, the cooling capacity Q of the heat exchange unit 300 can be calculated by the following equation.

[Mathematical Expression]

Q = U * A * T

Where Q is the cooling capacity (Kcal / hr), U is the heat transfer coefficient (Kcal / m ² * hr * ° C), A is the heat transfer area (m ² ), T is the temperature difference And the temperature of the inlet temperature of the seawater)

The coefficient of heat transfer (U) can be determined according to the combination of fluids performing heat exchange. That is, the heat transfer coefficient U according to an embodiment of the present invention can be determined by seawater and fresh water. On the other hand, the heat exchange unit 300 can be designed to have the maximum operating efficiency at a specific heat transfer area A and a specific temperature difference T. In the industry standard, the heat exchange unit 300 can be designed to have maximum operating efficiency at a temperature difference T of 4 ° C.

Therefore, even if the supply amount of the seawater for cooling the fresh water continuously increases, the heat exchange unit 300 has the cooling capacity when the temperature difference T between the fresh water and the sea water is 4 캜. That is, when the temperature difference (T) between fresh water and seawater is 4 ° C, continuous supply of seawater consumes unnecessary energy. In order to solve this problem, the control unit 500, which will be described later, can control the operation of the seawater pump 410.

The seawater supply unit 400 may be connected to the heat exchange unit 300. The seawater supply unit 400 may include a seawater pump 410 and a seawater pipe 430. The seawater pump 410 can supply seawater from the outside of the ship to the heat exchange unit 300. The seawater can cool the fresh water in the heat exchange unit 300 and be discharged to the outside of the ship. The seawater pump 410 may include a first seawater pump 411 and a second seawater pump 413. The first seawater pump 411 and the second seawater pump 413 may be arranged in parallel with each other.

The fresh water temperature sensor 600 may be disposed at the fresh water outlet 330. That is, the fresh water temperature sensor 600 may be disposed between the fresh water outlet 330 and the heat generating unit 100. The fresh water temperature sensor 600 can measure the outflow temperature of fresh water. The seawater temperature sensor 700 may be disposed at the seawater inlet 350. That is, the seawater temperature sensor 700 may be disposed between the seawater inlet 350 and the seawater pump 410. The seawater temperature sensor 700 can measure the inflow temperature of the seawater.

3 and 4 are views for explaining the operation of the control unit 500 shown in FIG.

Referring to FIGS. 2 and 3, the controller 500 may adjust the operation of the seawater pump 410 according to the temperature difference between clear water and sea water.

The controller 500 may calculate the temperature difference T between the fresh water discharge temperature measured by the fresh water temperature sensor 600 and the sea water inflow temperature measured by the sea water temperature sensor 700. [ If the temperature difference T is substantially equal to or less than a preset reference value, the control unit 500 may drive the seawater pump 410 at the rated speed R. [ If the temperature difference T is larger than the reference value, the controller 500 may drive the seawater pump 410 at a rotational speed greater than the rated rotational speed R. [ Here, the rated rotational speed R may be a predetermined value as the specific rotational speed.

On the other hand, the reference value may be 4 캜. This is because the heat exchange unit 300 is manufactured to have the cooling capacity Q according to the industry standard as described above.

3 and 4, the controller 500 can calculate the temperature difference T between the fresh water outflow temperature and the seawater inflow temperature through the fresh water temperature sensor 600 and the sea water temperature sensor 700. [ In one embodiment, the control unit 500 may increase the RPM of the seawater pump 410 as the temperature difference T increases with reference to the reference value (4 ° C). That is, the control unit 500 can control the seawater pump 410 to drive at the rated rotation speed R at the reference value (4 ° C). Thereby, the heat exchange unit 300 and the seawater pump 410 can be operated with optimum efficiency. Therefore, unnecessary consumption of energy can be eliminated.

5 is a flowchart showing a cooling method of a ship heat generating unit according to an embodiment of the present invention.

Referring to FIGS. 2 and 5, the method for cooling a ship heat generating unit according to an embodiment of the present invention includes a step of measuring a fresh water outflow temperature (S100), a step of measuring a seawater inflow temperature (S200), and a step of adjusting a supply amount of sea water (S300) .

The fresh water temperature sensor 600 can measure the outflow temperature of fresh water (S100). The seawater temperature sensor 700 can measure the inflow temperature of the seawater (S200). The control unit 500 can calculate the temperature difference (T) between the outflow temperature of fresh water and the inflow temperature of seawater. The control unit 500 can adjust the rotation speed of the seawater pump 410 according to the temperature difference T. Thereby, the supply amount of seawater can be adjusted.

The control unit 500 may control the operation of the seawater pump 410 at the rated rotation speed R when the temperature difference T between the fresh water outflow temperature and the seawater inflow temperature is substantially equal to or less than a predetermined reference value can do.

If the temperature difference T is larger than the reference value, the control unit 500 can drive the seawater pump 410 at a rotational speed greater than the rated rotational speed R. [ Here, the reference value may be 4 캜.

The control unit 500 can increase the number of rotations of the seawater pump 410 as the temperature difference T increases with reference to the reference value (4 ° C).

Meanwhile, the structure for cooling the ship heat generating unit according to the embodiment of the present invention can be referred to the description of the structure of the cooling apparatus 1000 of the ship heat generating unit according to the embodiment of the present invention described above.

Although the invention made by the present inventors has been described concretely with reference to the above embodiments, the present invention is not limited to the above embodiments, and it goes without saying that various changes can be made without departing from the gist of the present invention.

In addition, configurations not corresponding to the essential features of the present invention may not be mentioned in the above embodiments. However, to the extent necessary for the clarity of the above-described embodiment, the present invention can be understood by the technical characteristics disclosed in the prior art and the common sense level of the ordinary artisan.

1000: Cooling unit of the heating unit for ship
100: Heating unit
200: Fresh water circulation unit
300: Heat exchange unit
400: Seawater supply unit
500:
600: Fresh water temperature sensor
700: Sea water temperature sensor
R: Rated speed
T: temperature difference

Claims (7)

A heat generating unit disposed on the ship;
A fresh water circulating unit connected to the heat generating unit and including a fresh water pump for circulating fresh water for cooling the heat generating unit;
A heat exchange unit connected to the fresh water circulation unit;
A seawater supply unit connected to the heat exchange unit and including a seawater pump for supplying seawater from the outside of the ship to the heat exchange unit; And
And a control unit for controlling the operation of the seawater pump according to a temperature difference between the fresh water and the seawater. The method according to claim 1,
Wherein the heat exchange unit has a fresh water inlet through which fresh water flows, a fresh water outlet through which fresh water flows out, a sea water inlet through which the seawater flows, and a sea water outlet through which the seawater flows,
A fresh water temperature sensor disposed at the fresh water outlet to measure the outlet temperature of the fresh water; And
And a seawater temperature sensor disposed at the seawater inlet to measure an inflow temperature of the seawater. 3. The method of claim 2,
Wherein,
If the temperature difference between the fresh water discharge temperature measured by the fresh water temperature sensor and the sea water inflow temperature measured by the sea water temperature sensor is substantially equal to a preset reference value,
And when the temperature difference is larger than the reference value, drives the seawater pump at a rotational speed greater than the rated rotational speed. The method of claim 3,
The reference value is 4 DEG C,
Wherein the controller increases the number of revolutions of the seawater pump as the temperature difference increases with reference to the reference value. A fresh water circulating unit connected to the heat generating unit disposed on the ship for circulating fresh water for cooling the heat generating unit, a heat exchanging unit connected to the fresh water circulating unit, a seawater pump for supplying seawater for cooling the fresh water to the heat exchanging unit, And a control unit for controlling the cooling of the marine water supply unit.
A fresh water outflow temperature measurement step of measuring the outflow temperature of the fresh water flowing out of the heat exchange unit;
A seawater inflow temperature measurement step of measuring an inflow temperature of the seawater flowing into the heat exchange unit; And
And adjusting a rotational speed of the seawater pump according to a temperature difference between the outflow temperature of the fresh water and the inflow temperature of the seawater. 6. The method of claim 5,
In the seawater supply amount adjustment step,
Wherein the control unit drives the seawater pump at a rated rotational speed when the temperature difference between the fresh water outflow temperature and the seawater inflow temperature is substantially equal to a preset reference value,
And when the temperature difference is larger than the reference value, the seawater pump is driven at a rotational speed higher than the rated rotational speed. The method according to claim 6,
The reference value is 4 DEG C,
Wherein the control unit increases the number of rotations of the seawater pump as the temperature difference increases with reference to the reference value.

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