KR101010989B1 - Monitoring and controlling method of sloshing to liquid cargo in ship - Google Patents

Abstract

The present invention relates to a method for monitoring and controlling the sloshing of a liquid cargo of a ship, and more particularly, to a method of monitoring the sloshing of a liquid cargo stored in a liquid cargo tank of a ship, wherein the liquid level sensor is used in the liquid cargo tank. A liquid level measuring step of measuring the liquid level of the stored liquid cargo in real time; A signal processing step of amplifying the signal measured in the liquid level measurement in real time, converting the signal into a digital signal, and storing the converted signal; A display step of displaying the signal stored in the signal processing step in real time; And controlling the operating state of the ship to reduce sloshing when the signal displayed in the display step exceeds a set value, thereby changing the liquid level of the liquid cargo stored in the cargo tank of the ship. Can be observed in real time from the outside, so it is possible to reduce the sloshing by controlling the ship's operating speed, direction etc. Shock can be alleviated.

Vessel, tanker, LNG, sloshing, monitoring, liquid level, liquid, cargo, tank, sensor, vibration, alarm, laser

Description

Monitoring and controlling method of sloshing to liquid cargo in ship}

The present invention relates to a method for monitoring and controlling the sloshing of a liquid cargo of a ship, and more particularly, to monitor the sloshing occurring inside the tank for storing the liquid cargo of the ship from the outside and to mitigate excessive sloshing. The present invention relates to a sloshing monitoring and control method of a liquid cargo of a ship for controlling the operating state.

Oil tankers or LNG carriers carry cargoes in liquid form, such as crude oil or LNG, in cargo tanks.

Liquid cargo (hereinafter referred to as 'liquid cargo') is leveled to a certain level when the ship is stationary, but is pitched or rolled even if it is stopped in an environment where waves or sea breezes are severe. This causes sloshing in the tank. In particular, when sailing, this sloshing phenomenon becomes more severe.

Sloshing is a liquid flow phenomenon in which liquid flows as it swings inside a tank, causing various problems.

The biggest problem is that the liquid cargo hits the inner wall of the tank due to sloshing, causing damage inside the tank, and if this sloshing impact is repeated repeatedly, cracks due to fatigue may occur in the tank and be destroyed. .

In addition, the natural frequency of the tank and the natural frequency of the liquid cargo itself stored in the tank is similar at any moment, when the resonance occurs, the vibration of the tank is severe and there is a risk of severe noise, tremor, or even breakage.

The destruction of the tank by this sloshing phenomenon is more problematic in the case of cryogenic LNG carriers because the metal is generally changed to brittle state, which is fragile even in a weak impact when cooled to low temperature. The LNG tank made of such a metal material is in a very vulnerable state because it contains the cryogenic LNG inside the tank, when the sloshing phenomenon as described above is caused by the hull fluctuations such as rolling or pitching during the operation of the vessel, the tank is The risk of destruction is further increased.

In addition, since sloshing ships are becoming more and more large, these sloshing problems are becoming more and more important issues and become important design factors to be considered in design.

Looking at known techniques for reducing such sloshing, it is most likely to reduce the sloshing by changing the structure of the tank.

However, since there is no system for measuring the fluctuations of the oil or liquefied natural gas that is rocking and shaking in the tank of the ship, some sloshing occurs in the tank during the actual ship's voyage, There was no observational method for

Therefore, there is a need for a method for externally monitoring the flow of liquid cargo stored in a cargo tank of a sailing vessel.

The present invention has been made to solve the above problems, an object of the present invention is to monitor the flow of liquid cargo, especially liquid level, such as oil or liquefied natural gas stored in the cargo tank of the ship in real time from the outside at the same time to operate the vessel It is to provide a method of monitoring and controlling the sloshing of the liquid cargo of the ship that can control the state.

In order to achieve the above object, the present invention provides a method for monitoring the sloshing of liquid cargo stored in a liquid cargo tank of a ship, the liquid level of the liquid cargo stored in the liquid cargo tank by a liquid level sensor to measure in real time Level measurement step; A signal processing step of amplifying the signal measured in the liquid level measurement in real time, converting the signal into a digital signal, and storing the converted signal; A display step of displaying the signal stored in the signal processing step in real time; And controlling the operating state of the ship to reduce sloshing when the signal displayed in the display step exceeds a set value.

Preferably, the liquid level measuring step further comprises a vibration measuring step of measuring the vibration of the liquid cargo tank in real time by an acceleration sensor.

Preferably, the display step is characterized in that it further comprises an alarm step for transmitting an alarm when the liquid level of the liquid cargo exceeds a set value.

Preferably, the liquid level sensor is a laser range finder for measuring the distance to the liquid level of the liquid using a laser.

Preferably, the liquid level sensor is characterized in that the plurality of horizontally arranged inside the liquid cargo tank to measure the liquid level of a plurality of points.

The effect of the present invention by the configuration as described above can be observed in real time from the outside of the liquid level change of the liquid cargo stored in the cargo tank of the vessel as a basis for determining the operating state of the vessel in the bridge based on the liquid level measurement signal Can do it. In other words, when the sloshing is severe, sloshing can be alleviated by adjusting the ship's speed and bow angle, which can reduce the damage of the tank due to sloshing.

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

1 is a flow chart illustrating a sloshing monitoring and control method for a liquid cargo of a ship according to an embodiment of the present invention.

The present invention is largely composed of the liquid level measurement step 100, the signal processing step 200, the display step 300, the control step 400.

First, the liquid level measurement step 100 will be described with reference to FIGS. 1 and 2.

2 is a block diagram showing an apparatus for monitoring and controlling sloshing of liquid cargo of a vessel.

Hereinafter, the term liquid level is used to mean the depth of the liquid, that is, the liquid level.

The level measurement step 100 measures the liquid level of the liquid cargo stored in the liquid cargo tank 10 of the ship in real time, and uses the liquid level measurement sensor 20. The liquid level sensor 20 is a sensor for measuring the liquid level, as shown in Figure 2 is installed in the liquid cargo tank (10).

The liquid level measurement sensor 20 may be used in various ways, such as a float sensor, a pressure sensor, an ultrasonic sensor, a liquid level sensor using a current.

The floating sensor is to recognize the buoy floating in the liquid from the outside by mechanical coupling, the pressure sensor is installed in the liquid to detect the change of pressure caused by the change of the liquid level, and the ultrasonic sensor emits the ultrasonic wave. By measuring the time of the carrier wave reflected by reaching the upper surface of the liquid to measure the amount of change in the liquid level, and the liquid level sensor is a sensor for measuring the change in the liquid level by the change of the current by depositing the conductor in the liquid.

Preferably, in the present invention, it is preferable to accurately measure the liquid level in real time using the laser range finder 22, the laser range finder 22 is a waveguide 22a, a floating body 22b and a laser beam generator 22c. ) And will be described with reference to FIG. 3.

3 is a block diagram showing a laser range finder of the present invention shown in FIG.

The waveguide 22a is a hollow tube-shaped pipe through which a laser beam passes. The waveguide 22a is vertically installed in the liquid cargo tank 10, and the lower part is always immersed in the liquid cargo, and the liquid cargo flows into the waveguide. 22a) The lower end of the waveguide 22a is installed to be spaced apart from the bottom of the liquid cargo tank 10 so that the liquid level inside and outside remains the same. In addition, the waveguide 22a may be a synthetic resin, a metal, or the like, but when the liquid cargo is a liquefied natural gas, it is preferable to use a metal because it is cryogenic.

In addition, the floating body 22b is disposed in the waveguide 22a and floats on the liquid surface. The floating body 22b is made of various materials and shapes. In particular, in order to reduce measurement errors, the floating body 22b has a flat top surface and is horizontal in the waveguide 22a. It is preferable to have a cylindrical shape so that it can hold | maintain. The floating body 22b moves up and down according to the change of the liquid level.

In addition, since the laser beam generator 22c is a well-known technique as a means for receiving a reflected beam that irradiates a laser and reflects it, detailed description thereof will be omitted.

Next, the signal processing step 200 will be described.

The signal processing step 200 is a step of amplifying the electrical micro-signals measured by the liquid level sensor 20 of the liquid level measuring step 100 in real time and converting the amplified analog signals into digital signals and storing them.

The signal processing step 200 may be implemented by a signal processor consisting of an amplifier, an A / D converter, and a memory.

Usually, the electrical signal measured by the liquid level sensor 20 is a weak signal in general, so it must be amplified through an amplifier, and the amplified signal is a continuous analog signal, which is demonstrated in the display step 300 to be described later. To be used in the control step 400, the A / D converter must be converted to digital and stored in memory.

For reference, the digitally stored signals in the signal processing step may be provided as a display step to be described later, and may be used as data for analyzing the sloshing state of the liquid cargo during ship operation.

Next, the display step 300 may be implemented by a display unit including a monitor and a display program to receive the data stored in the signal processing step 200 so that the monitor of the cabin can see it. The display program may display a real-time change of the liquid level in a graph having an amplitude on the time axis, the display method is not limited to this, it is natural that it can be displayed in various forms.

Next, the control step 400 compares the liquid level measurement value displayed in the display step 300 with a previously set liquid level setting value, and then, if the liquid level measurement value is exceeded, the operation step such as an engine, a rudder or a ballast of a ship is performed. It is the stage that can control the related device to reduce the speed or adjust the bow angle to alleviate sloshing.

The control step 400 may be performed by a control unit made of a computer, and is programmed and built in the computer to transmit a command to a ship engine or a rudder when the liquid level measurement value and a set value are compared in real time.

In the present invention, the liquid level measuring step 100 may further include a vibration measuring step of measuring the vibration of the liquid cargo tank 10.

The vibration measuring step 110 measures in real time that the liquid cargo tank 10 vibrates by sloshing of the liquid cargo, and uses an acceleration sensor 30.

The acceleration sensor 30 is attached to the outside of the liquid cargo tank 10, it is preferable that the three-axis acceleration sensor that can measure the acceleration in the three-axis direction.

Since the vibration signal of the liquid cargo tank 10 measured by the acceleration sensor 30 is also an electrical signal, it is amplified, converted, stored, and transmitted to the display unit through the signal processor in the signal processing step 200.

In addition, in the present invention, the display step 300 may further include an alarm step 310 to issue an alarm to allow the monitor to recognize when the liquid level of the liquid cargo exceeds a set value.

In addition, the method of installing the liquid level measurement sensor 20 will be briefly described in the present invention.

4 is a layout view showing an installation example of the liquid level measurement sensor of the present invention.

In the present invention, the liquid level measurement sensor 20 is installed in the liquid cargo tank 10, in the case of the laser range finder 22, the long waveguide 22a is installed to be submerged in liquid, in which case the waveguide Only the liquid level at the point where 22a is located can be measured.

Therefore, the other point in the liquid cargo tank 10 can not know the liquid level change. Thus, preferably, a plurality of liquid level measurement sensor 20 is installed, horizontally installed to accurately measure the liquid level of a plurality of points inside the liquid cargo tank 10, and as shown in the form of a mesh with a predetermined interval to each other Would be nice to arrange.

Below is a brief look at the operational sequence of the present invention.

When a ship operates, a sloshing phenomenon occurs in which oil or liquefied natural gas flows in the liquid cargo tank 10, and the liquid level is measured by the liquid level sensor 20 in real time to generate an electrical signal.

When the liquid level measuring sensor 20 is the laser range finder 22, the laser beam generator 22c irradiates a laser beam and the irradiated laser beam reaches the floating body 22b and is then reflected again. It is received by the laser beam generator 22c. At this time, if the distance to the floating body 22b is measured by measuring the round trip time of the laser beam, the distance from the bottom surface of the liquid cargo tank 10 to the laser beam generator 22c is determined. The cargo level is calculated.

The liquid level measurement signal thus calculated is amplified in the signal processing step 200, digitally converted and stored, and then sent to the display step 300.

In the display step 300, the monitor can be easily displayed through the monitor, and the monitor can recognize the sloshing state (liquid level change state) of the liquid cargo in real time.

If the measured liquid level exceeds the set value, that is, if the liquid level is changed to a certain amplitude or more, the monitor can reduce the ship's ship speed or change the bow angle to mitigate sloshing. In step 400, the control of the ship's speed or bow angle is possible automatically.

In addition, even if the monitor does not recognize the alarm by the alarm step 310 may be informed to the monitor.

As described above, the present invention has a main technical idea of a method for monitoring the sloshing of liquid cargo in real time and controlling the operation of the ship. Since the embodiments described above with reference to the drawings are only one embodiment, The true scope of the invention should be determined by the claims.

1 is a flow chart illustrating a sloshing monitoring and control method of a liquid cargo of a ship according to an embodiment of the present invention.

2 is a block diagram showing an apparatus for monitoring and controlling sloshing of liquid cargo of a vessel.

3 is a block diagram showing a laser range finder of the present invention shown in FIG.

4 is a layout view showing an installation example of the liquid level measurement sensor of the present invention.

<< Explanation of main parts of drawing >>

10: liquid cargo tank 20: liquid level measurement sensor

22 laser rangefinder 22a waveguide

22b: floating body 22c: laser beam generator

30: acceleration sensor

100: level measurement step 110: vibration measurement step

200: signal processing step 300: display step

310: alarm step 400: control step

Claims (5)

A method for monitoring the sloshing of liquid cargo stored in a liquid cargo tank of a ship, A liquid level measuring step of measuring, in real time, the liquid level of the liquid cargo stored in the liquid cargo tank by a liquid level measuring sensor; A signal processing step of amplifying the signal measured in the liquid level measurement in real time, converting the signal into a digital signal, and storing the converted signal; A display step of displaying the signal stored in the signal processing step in real time; And controlling the operating state of the ship to reduce sloshing when the signal displayed in the display step exceeds a set value. The method of claim 1, In the level measurement step, And a vibration measuring step of measuring the vibration of the liquid cargo tank in real time by an acceleration sensor. The method of claim 1, In the display step, And a warning step of transmitting an alarm when the liquid level of the liquid cargo exceeds a set value. 4. The method according to any one of claims 1 to 3, The liquid level measurement sensor, A sloshing monitoring and control method for a liquid cargo of a ship, characterized in that the laser range finder measures the distance to the liquid level of the liquid cargo using a laser. 4. The method according to any one of claims 1 to 3, The liquid level measurement sensor, A sloshing monitoring and control method for a liquid cargo of a ship, characterized in that a plurality of horizontally arranged inside the liquid cargo tank to measure the liquid level of the plurality of points.

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