KR101430143B1 - Apparatus and Method for ballast water examination - Google Patents

Abstract

The present invention relates to a ballast water treatment apparatus including a chamber where ballast water to be inspected is accommodated; a means which is provided in a lower portion of the chamber to stir the ballast water accommodated in the chamber; a sensor unit which is disposed in an upper portion of the chamber to measure dissolved oxygen of the ballast water accommodated in the chamber; a sealing means which is disposed on the outside of the chamber to seal the chamber from the outside; a light source which emits light into the chamber; a controller which is electrically connected to the stirring means, the light source, and the sensor unit, stirs the ballast water by controlling the stirring means, controls the light source so that the chamber is put in a bright condition and a dark condition, and allows the dissolved oxygen to be measured in the bright condition and the dark condition by controlling the sensor unit; and a data treatment unit which turns the degree of microbial reduction of the ballast water into data based on a measurement value from the sensor unit in the bright condition and the dark condition, and to a ballast water treatment method using the same. According to the present invention, the degree of microbial reduction can be simply measured and ballast water inspection costs can be saved.

Description

[0001] Apparatus and Method for Ballast Water Examination [

The present invention relates to an apparatus and a method for inspecting the degree of microbial death of a ballast water of a ship, and more particularly, to a ballast water test apparatus capable of easily measuring the microbial death and reducing the ballast water inspection cost, ≪ / RTI >

In general, cargo vessels transported on the sea are mostly single-headed except for vessels that are traveling round-trip for the exchange of similar cargoes. When the ballast water is sailing under full load, ballast water (ballast water) is introduced into the ship for sailing in a ballast condition in order to improve the balance, safety and steering performance of the ship.

At this time, the ballast water is filled in a port through a ballasting operation and is transported elsewhere and discharged into a new port through a deballasting operation. As such, the release of marine organisms and pathogens contained in ballast water from a remote location is not only detrimental to the new environment, but can also be dangerous to both humans and animals in new ports.

The introduction of non-natural marine life into new ecosystems can have devastating effects on native flora and fauna that may not have a natural defense system against new species. In addition, harmful bacterial pathogens such as cholera may be present in the original harbor. These pathogens may proliferate in ballast tanks over time and cause disease in areas where they are released.

In order to eliminate the risks posed by these marine organisms and pathogens, the ballast water is electrolyzed or sterilized by injecting chemicals during the ballasting operation or the de-balusting operation. Here, the International Maritime Organization (IMO) strictly restricts the standards for containing microorganisms in ballast water discharged to the outside of the ship. Before discharging the sterilized ballast water, the microorganisms contained in the ballast water must meet the standards of the International Maritime Organization It should be checked whether it has been killed.

Open Patent Application No. 10-2010-0034718 discloses a system and method for treating water ballast water microorganisms for image processing so that various microorganisms in ballast water can be inspected in real time. This prior literature discloses that the light emitted from the ballast water is transmitted through a sample to emit microorganisms, the emitted microorganisms are photographed with a high resolution camera, and the photographed image is displayed as an image using an image processor, .

On the other hand, Japanese Patent Laid-Open Publication No. 10-2012-0112938 discloses a ballast treated water remaining microbial optical monitoring apparatus capable of detecting microorganisms remaining in the ballast treated water of a ship using light. This prior art discloses a method in which the ballast water to be inspected collected from the main conveyance pipe to which the ballast water is transferred is irradiated with light and the fluorescence generated from the microorganisms remaining in the ballast water to be inspected is detected, And determines the degree of microbial death of the ballast water.

However, since the prior art documents must include expensive optical equipment such as a high-resolution camera, an image processor, an optical fiber, and an optical filter, the cost of the inspection apparatus is high.

It is an object of the present invention to provide a ballast water testing apparatus and method which can simplify the ballast water test and reduce the ballast water test cost.

According to an aspect of the present invention, there is provided an apparatus for testing a ballast water supply system including a chamber for receiving ballast water to be inspected; Stirring means provided at a lower portion of the chamber for stirring the ballast water accommodated in the chamber; A sensor unit installed at an upper portion of the chamber and measuring a dissolved oxygen amount of the ballast water contained in the chamber; Shielding means provided outside the chamber for shielding the chamber from the outside; A light source for irradiating light into the chamber; The stirring unit, the light source, and the sensor unit, the stirring unit is controlled to stir the ballast water, and the light source is controlled so that the chamber is placed under light and dark conditions, and the sensor unit is controlled A controller for measuring the dissolved oxygen amount under the light condition and the dark condition, respectively; And a data processing section for converting the measurement values of the sensor section under the light condition and the dark condition into data.

Preferably, the controller controls the light source such that the cycle of the light condition and the dark condition is repeated a predetermined number of times, and the data processor generates the measured values of the sensor unit as data.

More preferably, the data processing unit further comprises a display unit for outputting data generated by the data processing unit in a numerical value or a graph.

The sensor unit is detachably installed on the upper portion of the chamber, and has a bottom surface inclined from one side to the other, and a hole for discharging bubbles inside the chamber to the outside at the highest point of the inclined bottom surface .

Preferably, the stirring means includes a magnetic member provided inside the chamber, and a magnetic field generating member provided outside the chamber to rotate the magnetic member by forming a magnetic field.

The present invention also provides a ballast water testing method using the ballast water testing apparatus, comprising the steps of: a) injecting ballast water into the chamber and installing the sensor unit; b) operating the magnetic field generating member to rotate the magnetic member to mix the ballast water; c) operating the light source such that the chamber is in light and dark conditions; d) measuring the amount of dissolved oxygen in the light condition and the dark condition by the sensor unit; And e) the data processing unit converts the measured value of the sensor unit into data.

Preferably, in the step c), the light source is operated so that the cycle of the light condition and the dark condition is repeated a predetermined number of times.

More preferably, after the step (e), the display unit may further include a step of outputting the data generated by the data processing unit as a numerical value or a graph.

According to the present invention, it can be easily confirmed whether or not the microorganisms contained in the ballast water are killed through the data indicating the change in the dissolved oxygen amount.

In addition, it is possible to measure the degree of microbial depletion without using expensive and complicated optical devices that have been used previously, thereby reducing the cost of testing ballast water.

1 is a schematic view showing a configuration of a ballast water testing apparatus according to the present invention,
2 is a flow chart schematically illustrating a ballast water testing method according to the present invention.

Hereinafter, preferred embodiments of the ballast water testing apparatus and method according to the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, it is to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting of the technical scope of the present invention. Will be.

1 is a schematic view of a configuration of a ballast water testing apparatus according to the present invention. As shown in the drawing, a ballast water testing apparatus according to the present invention includes a ballast water testing apparatus A sensor unit 130 for measuring the amount of dissolved oxygen generated from the ballast water to be inspected, a shielding unit 130 for shielding the chamber 110, A controller 160 for controlling the operation of the light source 150 and the sensor unit 130. The light source 150 irradiates the chamber 110 with light, the stirring unit, the sensor unit 130, And a data processing unit 170 for processing the data.

The chamber 110 is a cylindrical member having an open upper end, and collects a predetermined amount of ballast water treated for sterilization through a ballast water treatment apparatus, for example, an electrolysis chamber. A lower portion of the chamber 110 may be provided with an opening 111 for introducing and discharging the ballast water and a predetermined amount of ballast water introduced through the opening 111 may be introduced into the chamber 110, ). ≪ / RTI >

The stirring means is provided at a lower portion of the chamber 110 to stir the ballast water contained in the chamber 110 to mix the microorganisms contained in the ballast water to be tested evenly. The stirring means includes a magnetic member 121 provided inside the chamber 110 and a magnetic field generating member 122 provided outside the chamber 110 to rotate the magnetic member 121 by forming a magnetic field. However, the stirring means may be any device capable of mixing the ballast water in the chamber 110, such as a stirring wing driven by a motor, for example.

The sensor unit 130 is installed on the upper part of the chamber 110 to measure the dissolved oxygen amount of the ballast water contained in the chamber 110. More specifically, the sensor unit 130 is a cylindrical member detachably installed at the opened upper end of the chamber 110. When the sensor unit 130 is installed in the chamber 110, the chamber 110 is sealed. The sensor unit 130 has a bottom surface 131 which is inclined uniformly from one side to the other side. A hole 132 for discharging air (air bubbles) inside the chamber 110 to the outside is provided at the highest point of the inclined bottom surface 131, that is, at the highest position. A sensor 133 protruded downward from the center of the inclined bottom surface 131 measures the dissolved oxygen amount of the ballast water.

The shielding means 140 is provided outside the chamber 110 so as to surround the chamber 110 to shield the chamber 110 from the outside. By this shielding means 140, the chamber 110 can have a dark room condition (hereinafter referred to as a dark condition).

The light source 150 is installed outside the chamber 110, preferably inside the shielding means 140, and irradiates light into the chamber 110. That is, the light source 150 irradiates the chamber 110 with light to provide the chamber 110 with a bright room condition (hereinafter, referred to as a bright condition).

The controller 160 is electrically connected to the stirring unit, the sensor unit 130 and the light source 150 to control the operation of the stirring unit, the sensor unit 130, and the light source 150. Specifically, the controller 160 includes a switch 161 for on / off operation of the agitating means and a switch 162 for selecting on / off of the light source 150. Accordingly, the controller 160 mixes and mixes the ballast water in the chamber 110 by operating the stirring means through the operation switch 161 of the stirring means, Thereby turning the chamber 110 on and off so that the chamber 110 is placed under light and dark conditions. Then, the controller 160 controls the sensor unit 130 to measure the dissolved oxygen amount of the ballast water under the light condition and the dark condition.

Here, the control of the light source 150 to measure the dissolved oxygen amount of the ballast water under the light condition or the dark condition is performed in such a manner that when the microorganism lives in the ballast water, the dissolved oxygen amount This is because a difference occurs. That is, in the case of phytoplankton, the amount of dissolved oxygen is increased due to the release of oxygen through the photosynthesis action under the light condition, and the amount of dissolved oxygen is not increased because the photosynthesis is not performed in the dark condition. In addition, in the case of zooplankton, the amount of dissolved oxygen is reduced because it breathes regardless of light conditions and dark conditions. Therefore, when the microorganisms are not killed in the ballast water, the amount of dissolved oxygen is changed under the light condition and the dark condition, and the change of the dissolved oxygen amount can be confirmed to determine the microbial death.

Thus, in order to consider the difference in dissolved oxygen amount depending on the type of microorganism included in the ballast water, the present invention provides the condition (condition) and the dark condition in the chamber 110 in which the ballast water is received, .

The data processing unit 170 may be provided in the controller 160 and generates a numerical value by converting the change in the dissolved oxygen amount based on the measurement value of the sensor unit 130 under the above-mentioned light condition and dark condition. The data processing unit 170 can output the generated data value to the outside through the display unit 180 provided in the controller 160. [ Accordingly, it is possible to confirm whether the microorganisms included in the ballast water have been killed through the numerical value output from the data processing unit 170.

As described above, the ballast water treatment apparatus according to the present invention can easily measure the microbial destruction by checking the amount of generated oxygen of the microorganisms contained in the ballast water in real time. In addition, it is possible to measure the degree of microbial depletion without using expensive and complicated optical devices that have been used previously, thereby reducing the cost of testing ballast water.

Preferably, the controller 160 controls the ON / OFF operation of the light source 150 such that the light condition of the chamber 110 and the cycle of the dark condition are repeated a predetermined number of times. The data processing unit 170 generates data so that the increase / decrease of the dissolved oxygen amount measurement values of the sensor unit 130 measured in the light conditions and the dark conditions, And outputs the data as numerical values.

On the other hand, the display unit 180 provided in the controller 160 and outputting data of the data processing unit 170 may be constituted by a digital or chart printer, and can graphically display the amount of dissolved oxygen change in real time.

FIG. 2 is a flow chart schematically showing a method for treating ballast water according to the present invention, and a ballast water treatment method according to the present invention will be described with reference to FIGS. 1 and 2. FIG.

First, the ballast water sterilized through a ballast treatment apparatus (not shown) is injected into the chamber 110, and then the sensor unit 130 is installed on the opened top of the chamber 110 (S100). Here, the ballast water can be introduced into the chamber 110 through the opening 111 via an injection pump (not shown). When the sensor unit 130 is installed on the open top of the chamber 110, the ball 130 contacts the ballast water from the lowest point of the inclined bottom surface 131 of the sensor unit 130, Is discharged to the hole 132 provided at the highest point along the bottom surface 131. Therefore, the amount of oxygen in the air inside the chamber 110 does not affect the sensor 133.

When the installation of the sensor unit 130 is completed, the controller 160 outputs a signal to the magnetic field generating member 122 to generate a magnetic field, thereby causing the magnetic member 121 in the chamber 110 to rotate (S200 ). Then, the ballast water inside the chamber 110 is stirred by the rotation of the magnetic member 121, so that the microorganisms contained in the ballast water are evenly mixed.

Next, the controller 160 controls the operation of the light source 150 so that the chamber 110 is placed in the light condition and the dark condition (S300). Here, when the light source 150 is turned on, the light condition of the chamber 110 is achieved, and when the light source 150 is turned off, the dark condition of the chamber 110 is achieved.

At this time, the sensor unit 130 measures the dissolved oxygen amount of the ballast water under the light condition and the dark condition of the chamber 110 (S400). Here, when the chamber 110 is in the dark condition, the vegetable plaques do not function as photosynthesis, and both the animal plaques and the phytoplankton breathe, so that the measured dissolved oxygen amount will decrease and the chamber 110 When present, the vegetable plactone contained in the ballast water will act as a photosynthetic agent and the dissolved oxygen content will increase accordingly.

The data processing unit 170 converts the dissolved oxygen amount measurement value of the sensor unit 130 into data (S500). At this time, the data processing unit 170 converts the dissolved oxygen amount measurement value in the dark condition and the change in the dissolved oxygen amount measurement value in the light condition into a numerical value. Through the data thus generated, the inspector can check whether the microorganisms contained in the ballast water have been killed.

Preferably, the controller 160 controls the light source 150 such that the ON / OFF period of the light source 150 is repeated to repeat the periods of the light condition and the dark condition for a predetermined number of times. The data processing unit 170 generates data on dissolved oxygen measurements of the sensor unit 130 measured as described above. Through the data thus generated, the inspector can check the change of the dissolved oxygen amount in real time and confirm whether the microorganisms contained in the ballast water are dead or not.

Meanwhile, the data values of the data processing unit 170 may be output as numerical values or graphs in the data processing unit 170 through the display unit 180 (S600).

As described above, according to the ballast water treatment method of the present invention, it is possible to easily confirm whether microorganisms are killed or not by using data outputted in numerical values or graphs, and to prevent the microorganisms from extinction The ballast water test cost can be reduced.

The embodiments of the present invention described above are merely illustrative of the technical idea of the present invention, and the scope of protection of the present invention should be interpreted according to the claims. 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 should be interpreted that it is included in the scope of right.

110: chamber 111: opening
121: magnetic member 122: magnetic field generating member
130: sensor part 131: bottom surface
132: hole 133: sensor
140: shielding means 150: light source
160: Controller 161, 162: Switch
170: Data processing unit 180:

Claims (8)

A chamber for receiving ballast water to be inspected;
Stirring means provided at a lower portion of the chamber for stirring the ballast water accommodated in the chamber;
And a bottom surface that is detachably installed on the upper portion of the chamber and has an inclined bottom surface tapered from one side to the other side, wherein a hole for discharging bubbles inside the chamber to the outside is provided at the highest point portion of the inclined bottom surface, A sensor unit for measuring a dissolved oxygen amount of water;
Shielding means provided outside the chamber for shielding the chamber from the outside;
A light source for irradiating light into the chamber;
The stirring unit, the light source, and the sensor unit, the stirring unit is controlled to stir the ballast water, and the light source is controlled so that the chamber is placed under light and dark conditions, and the sensor unit is controlled A controller for measuring the dissolved oxygen amount under the light condition and the dark condition, respectively; And
And a data processing unit for converting the measured values of the sensor unit into data under the light condition and the dark condition.
The method according to claim 1,
Wherein the controller controls the light source such that the cycle of the light condition and the dark condition is repeated a predetermined number of times, and the data processing unit generates the measured values of the sensor unit as data.
3. The method of claim 2,
And a display unit for outputting data generated by the data processing unit in numerical values or graphs.
delete The method according to claim 1,
Wherein the stirring means includes a magnetic member provided inside the chamber and a magnetic field generating member provided outside the chamber to rotate the magnetic member by forming a magnetic field.
A ballast water testing method using the ballast water testing apparatus according to any one of claims 1 to 5,
a) injecting ballast water into the chamber and installing the sensor unit;
b) operating the magnetic field generating member to rotate the magnetic member to mix the ballast water;
c) operating the light source such that the chamber is in light and dark conditions;
d) measuring the amount of dissolved oxygen in the light condition and the dark condition by the sensor unit; And
and e) the data processing unit converts data measured by the sensor unit into data.
The method according to claim 6,
Wherein the light source is operated such that the cycle of the light condition and the dark condition is repeated a predetermined number of times in the step c).
8. The method of claim 7,
Further comprising the step of, after the step (e), the display unit outputting the data generated by the data processing unit in a numerical value or a graph.

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