KR20140090758A - Ship ballast water treatment device including integrated equipment and flow controlling method - Google Patents

Abstract

Disclosed are a ship ballast water treatment apparatus including integrated equipment and a flow control method. The ship ballast water treatment apparatus is installed in a ship having a main ballast tank, an AP ballast tank, a main pipe to the main ballast tank and an AP pipe to the AP ballast tank. The ship ballast water treatment apparatus comprises multiple flow meters measuring the flow of the main pipe, the flow of the AP pipe, and the flow of a sterilization solution sterilizing the ship ballast water progressing along the main pipe and the AP pipe; an integrated ballast water treatment module for controlling the amount of the sterilization solution to be injected to the main pipe and the AP pipe by using multiple flow control valves; and a control unit for controlling the operation of the multiple flow control valves to correspond to the flow of the main pipe and the flow of the AP pipe measured in the multiple flow meters.

Description

Technical Field [0001] The present invention relates to a ship ballast water treatment apparatus including an integrated facility and a flow control method,

The present invention relates to a ship ballast water treatment apparatus including an integrated facility and a flow rate control method.

For large vessels such as tankers, container ships or LNG carriers, ballast tanks are provided inside the vessel as a means of ensuring the stability and balance of the vessel. In order to balance the ship's balance, sea water (or fresh water) is circulated through a ballast water, a ballast water, Ballast water "). In other words, in case the cargo is unloaded, the ballast water is allowed to flow into the ballast tank, and when the cargo is loaded, the ballast water stored in the ballast tank is discharged so that the balance of the ship can be balanced.

On the other hand, vessels storing ballast water may discharge seawater from a first country to the marine environment of a second country in another marine environment. Since ballast water is seawater in the inflow area, ballast water includes microorganisms such as plankton, bacteria and the like, which are contained in seawater. In the event that ballast water from a first country is discharged into the ocean of a second country in a completely different environment, various foreign substances or microbes and bacteria or other organic substances of the first country may cause a change in the marine ecosystem of the second country Danger may occur.

Accordingly, the International Maritime Organization (IMO) has established the Convention on the Management of Ballast Water in 2004 for the purpose of preventing the movement of harmful species between countries. In order to control the release of harmful species, The exchange standard (D-1) and the processing standard (D-2) were enacted and made mandatory. Among them, the exchange of ballast water should be done in the ocean, and it causes the safety problem of the ship. Therefore, it is becoming more and more necessary to sterilize the ballast water instead of exchanging the ballast water. The Convention is underway to develop ballast water treatment systems for shipbuilding in all countries, since it will take effect one year from the time when the ship is approved by more than 30 countries.

Conventional ship ballast water treatment apparatus has sterilized ship ballast water by electrolyzing the side stream and re-injecting it into the main stream as disclosed in Korean Patent Laid-Open No. 10-2010-0017994.

In the case of a general ship, a plurality of equilibrium water treatment apparatuses may be provided since they are provided with after-perpendicular (AP) tanks other than ballast tanks. Especially, in the case of ballast water stored in the AP ballast tanks, it must be introduced into the tank through a separate pipe (AP Pipe) from the main pipe. to be. In particular, in the case of an electrolytic-type ballast water treatment apparatus, it is difficult to separately implement a main device such as a rectifier, an electrolysis tank, a gas-liquid separator, a blower, and a pump in order to realize two or more electrolysis systems.

Considering the installation space of a limited ship unlike on land, there are restrictions on the arrangement of equipment. Especially when installing a ballast water treatment system on a ship that is already in operation, a separate space is provided for this apparatus There are restrictions on the installation because there is no.

Korean Patent Publication No. 10-2010-0017994

The present invention enables the targeted sterilization process (e.g., injection of at least one of the desired concentrations of residual chlorine, chemicals, ozone) into both systems (main ballast tanks and AP ballast tanks) And an integrated facility capable of solving a space shortage due to redundant equipment and a problem of installation limitation in a limited space of a ship.

Other objects of the present invention will become readily apparent from the following description.

According to one aspect of the present invention, there is provided a ship ballast water treatment apparatus provided in a ship provided with a main ballast tank and an AP ballast tank, and having a main pipeline to the main ballast tank and an AP pipeline to the AP ballast tank A plurality of flow meters for measuring a flow rate of the main piping, a flow rate of the AP piping, and a flow rate of a sterilizing liquid for sterilizing ship equilibrium water flowing along the main piping and the AP piping; An integrated ballast water treatment module for controlling an amount of the sterilization liquid injected into the main piping and the AP piping by using a plurality of flow control valves; And a controller for controlling operations of the plurality of flow control valves in accordance with the flow rate of the main pipe and the flow rate of the AP pipe measured by the plurality of flow meters.

Wherein the integrated ballast water treatment module includes a main pipeline for supplying a part of the ship equilibrium water to generate electrolytic water containing hypochlorous acid at a predetermined concentration in an electrolytic manner as a sterilizing liquid, An injector injected into the main pipe and the AP pipe by distributing a mixed liquid mixed with ozone generated from the ozone generator by introducing a part of the ballast water into the main pipe and the AP pipe, The sterilizing liquid may be at least one of a main pipe and an injector injecting the medicine into the AP pipe from a storage tank for storing a medicament having a sterilizing function previously shipped to a ship for sterilizing the ship ballast water.

The integrated electrolytic apparatus includes a pressurizing pump for introducing a part of the ballast water into the side stream in the main piping and an electrolytic bath for electrolyzing the side stream in accordance with a current value applied by the rectifier to generate the electrolytic water .

The controller may further control the current value corresponding to the flow rate of the main pipe and the flow rate of the AP pipe measured in the plurality of flow meters.

Further comprising a sensor disposed in each of the main pipe and the AP pipe for measuring a dilution concentration of the sterilizing liquid, wherein the control unit controls the sterilization in accordance with the concentration of the sterilization liquid diluted in the main pipe and the AP pipe, The total amount of the liquid can be additionally controlled.

According to another aspect of the present invention, there is provided a ship equilibrium type ship having a main ballast tank and an AP after ballast tank installed therein, the main equilibrium tank being provided with a main pipeline to the main ballast tank and an AP pipeline to the AP ballast tank, (A) measuring a flow rate of the main piping and a flow rate of the AP piping in a control unit of the water treatment apparatus; (b) determining an amount of sterilizing liquid that sterilizes ship ballast water traveling along the main piping and the AP piping in the control unit; And (c) controlling the operation of the plurality of flow control valves to adjust the amount of the sterilization liquid injected into the main piping and the AP piping.

(d) measuring the concentration of the sterilization liquid diluted in the main piping and the AP piping; And (e) maintaining or adjusting the amount of the sterilizing liquid according to the measurement result.

The step (b) includes the steps of: (b1) determining a flow rate value of the side stream branched from the main pipe and a current value supplied to the electrolysis bath in the rectifier; (b2) measuring a flow rate of electrolytic water containing a predetermined concentration of hypochlorous acid generated by electrolysis in the electrolytic bath, wherein the step (c) The flow rate of the electrolytic water injected into the main pipe and the AP pipe can be distributed by controlling the plurality of flow control valves.

(d) measuring the concentration of the hypochlorous acid diluted in the main piping and the AP piping; And (e) maintaining the flow rate value and the current value of the side stream or adjusting at least one of the flow rate value and the current value of the side stream according to the measurement result.

Other aspects, features, and advantages will become apparent from the following drawings, claims, and detailed description of the invention.

According to the embodiment of the present invention, it is possible to achieve the desired disinfection treatment with two systems (main ballast tanks and AP ballast tanks) using an integrated facility, thereby solving the problem of space shortage and installation limitation due to redundant equipment in a limited space of the ship There is an effect that is possible.

1 is a conceptual view of an existing ship ballast water treatment apparatus installed on a ship having a main ballast tank and an AP ballast tank,
2 is a conceptual diagram of a ship ballast water treatment apparatus according to an embodiment of the present invention installed on a ship having a main ballast tank and an AP ballast tank,
FIG. 3 is a comparison chart of the quantity of components of a conventional ship ballast water treatment apparatus and a ship ballast water treatment apparatus according to an embodiment of the present invention,
4 is a conceptual view of a ship including a ship ballast water treatment apparatus according to an embodiment of the present invention,
5 is a flowchart of a flow rate control method performed in a ship ballast water treatment apparatus according to an embodiment of the present invention.
FIG. 6 is a flow chart of a flow control method performed in a ship ballast water treatment apparatus according to an embodiment of the present invention,
7 is a flowchart according to another scenario of a flow control method performed in a ship ballast water treatment apparatus according to an embodiment of the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, the terms "comprises" or "having" and the like refer to the presence of stated features, integers, steps, operations, elements, components, or combinations thereof, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

Also, the terms " part, "" module," and "group ", etc. in the specification mean units for processing at least one function or operation and may be implemented by hardware or software or a combination of hardware and software .

It is to be understood that the components of the embodiments described with reference to the drawings are not limited to the embodiments and may be embodied in other embodiments without departing from the spirit of the invention. It is to be understood that although the description is omitted, multiple embodiments may be implemented again in one integrated embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a conceptual diagram of an existing ship ballast water treatment apparatus installed on a ship having a main ballast tank and an AP ballast tank.

1, the first and second ballast water treatment modules 10 and 20, the first and second pressurizing pumps 11 and 21, the first and second electrolytic baths 12 and 22, The second gas-liquid separator 13 and 23, the blower 14, the pressure gauge P, the flow meter F and the temperature / salinity meter C are shown.

In the case of a conventional ship ballast water treatment apparatus, two independent ballast water treatment modules 10 and 20 are provided to supply the sterilized ballast water to the main pipeline connected to the main ballast tank and the AP pipeline connected to the AP ballast tank, respectively. .

The first ballast water treatment module 10 includes a first pressurizing pump 11 for introducing the side stream into the module and a second pressurizing pump 11 for electrolyzing the side stream by the current supplied from the rectifier A first gas-liquid separator 13 for separating impurities of a gas component generated in the electrolysis process from the electrolytic water, and a second gas-liquid separator 13 for discharging gas components separated from the first gas- And an air blower 14. The electrolytic water separated in the first gas-liquid separator 13 can be injected into the main pipe by the electrolytic water injector.

The second ballast water treatment module 20 includes a second pressurizing pump 21 for introducing the side stream into the module and a second electrolytic cell 21 for electrolyzing the side stream by the current supplied from the rectifier to generate residual chlorine A second gas-liquid separator 23 for separating the impurities of the gas component generated in the electrolysis process from the electrolytic water, a blower 14 for discharging the gas components separated from the second gas-liquid separator 23 to the outside, . The electrolytic water separated in the second gas-liquid separator 23 can be injected into the AP pipe by the electrolytic water injector. Also, although the blower 14 is illustrated as being shared with the first ballast water treatment module 10, the second ballast water treatment module 20 may be separately provided.

In the electrolytic baths 12 and 22 of each module, a high concentration of hypochlorous acid (or halogen disinfectant) is generated at a concentration of several hundred ppm and injected into the main piping and the AP piping through the electrolytic water injector to be diluted to a low concentration within 10 ppm do.

In this case, equipments such as the pressurizing pumps 11 and 12, the electrolytic baths 21 and 22, the gas-liquid separators 13 and 23, and the rectifier, which have the same function, are required in duplicate, , Which restricts the arrangement of the equipment and restricts the installation thereof.

2 is a conceptual diagram of a ship ballast water treatment apparatus according to an embodiment of the present invention installed on a ship having a main ballast tank and an AP ballast tank.

2, the integrated ballast water treatment module 30, the pressurizing pump 11, the electrolytic bath 12, the gas-liquid separator 13, the blower 14, the flow control valves 31 and 32, P, a flow meter F and a temperature / salinity meter C are shown.

A ship ballast water treatment apparatus according to an embodiment of the present invention includes an integrated ballast water treatment module (30). (Corresponding to the second ballast water treatment module 20 in Fig. 1) is omitted in the figure, and the entirety of the portion denoted by the fine dotted line is the pressure pump 11, the electrolytic bath 12, the gas-liquid separator 13, 14, and a rectifier (not shown), which are different from those shown in FIG.

The integrated ballast water treatment module 30 includes a pressurizing pump 11 for introducing the side stream into the module, an electrolysis tank 12 for electrolyzing the side stream by the current supplied from the rectifier to generate residual chlorine, A gas-liquid separator 13 for separating impurities of a gas component generated in the electrolysis process from the electrolytic water, and a blower 14 for discharging gas components separated from the gas-liquid separator 13 to the outside.

The electrolytic water (high-concentration hypochlorous acid-containing sterilizing liquid) separated by the gas-liquid separator 13 is suited to the capacity of each piping and is supplied to the main piping and the AP piping in an amount sufficient to maintain a proper TRO concentration And the flow rate is regulated by the flow rate control valves 31 and 32 installed in the respective injection paths and injected into the main piping and the AP piping. The piping and the valve are designed and arranged considering that the main piping capacity is 5 to 15 times larger than the AP piping, for example.

3 is a comparison chart of the number of components of a conventional ship ballast water treatment apparatus and a ship ballast water treatment apparatus according to an embodiment of the present invention.

3, an electrolytic bath, a rectifier, a pressurizing pump, a gas-liquid separator, and an On / Off automatic valve (corresponding to an electrolytic water injector) for installing an electrolytic apparatus outlet in a ship ballast water treatment apparatus according to an embodiment of the present invention, Compared with the ship ballast water treatment system of the present invention. This is because the dotted line in FIG. 2 is omitted, and it can be seen that most installation equipment is saved.

The number of flowmeters, hydrogen, chlorine, and differential pressure gauges is the same as before, and a flow control valve that was not previously required is additionally required. However, since many components are omitted and many piping are omitted, It is possible to obtain a large spatial gain.

Hereinafter, the structure and function of a ship ballast water treatment apparatus according to an embodiment of the present invention will be described in detail with reference to related drawings.

4 is a conceptual view of a ship including a ship ballast water treatment apparatus according to an embodiment of the present invention.

4, the ship 1, the main ballast tank 2, the AP ballast tank 3, the main piping 110, the AP piping 120, the main ballast pump 111, the AP ballast pump 121, The side piping 150, the preprocessing filters 113 and 123, the integrated ballast water processing module 130, the pressurizing pump 131, the electrolytic bath 132, the rectifier 133, the gas-liquid separator 134, The first and second flow control valves 138 and 139, the residual chlorine measurement sensors 114 and 124 and the control unit 140 are shown in FIG.

In the ship ballast water treatment apparatus according to an embodiment of the present invention, a side stream is applied to sterilize ship ballast water (for example, an electrolytic indirect system, a chemical injection system, an ozone injection system, etc.) (E.g., at least one of residual chlorine, chemicals, and ozone due to electrolysis) using one integrated facility instead of a plurality of conventional stand-alone facilities for the main piping to the tank and AP piping to the AP ballast tanks, It is possible to dispense with redundant equipment and / or piping, so that it can be easily installed even in a ship having a limited space.

4, one or more main ballast tanks 2 and AP ballast tanks 3 are provided in the vessel 1 and the main piping 110 to the main ballast tanks 2 and the AP ballast tanks 3, An AP pipe 120 is provided.

The main piping 110 is connected between the sea chest of the ship and the main ballast tank 2 so that seawater around the ship is introduced into the main ballast tank 2 by the main ballast pump 111. [ to be. The AP pipe 120 is connected between the seed chest of the ship and the AP ballast tank 3 so that seawater around the ship is introduced into the AP ballast tank 3 by the AP ballast pump 121. The side piping 150 is connected to the main piping 110 and the sidestream and the other end is branched to be connected to the main piping 110 and the AP piping 120 so that the electrolytic water passes through the main piping 110 and the AP piping 110, (120).

Hereinafter, the flow of ship ballast water along the main pipeline 110 will be referred to as main stream, the flow of ship ballast water along the AP pipeline 120 will be referred to as AP stream, the flow of some ship ballast water along the side pipeline 150 will be referred to as a side stream Quot; In the present specification, a description will be made assuming that the seed chest is upstream of the main stream and the AP stream, and the ballast tank is downstream of the main stream and AP stream.

The pre-processing filters 113 and 123 filter marine microorganisms upstream of the main stream and the AP stream. While the function of a general filter is performed, marine microorganisms larger than a predetermined size are removed. With the automatic backwash function, it is possible to have a structure and capacity for continuous ship ballast water treatment.

Flow meters 112 and 122 are provided at the front ends of the preprocessing filters 113 and 123 and are connected to the main piping 110 and the AP piping 120 through the main ballast pump 111 and the AP ballast pump 121, And transmits the measurement result to the control unit 140. The control unit 140 determines the flow rate of the main stream and the AP stream.

The integrated ballast water treatment module 130 generates hypochlorous acid (residual chlorine) through electrolysis of the side stream flowing through the side piping 150 branched from the main piping 110 and supplies it to the main piping 110, (Electrolytic water) in the AP pipe 120 to sterilize the ship ballast water. That is, the integrated ballast water treatment module 130 functions as a sterilizing treatment unit.

Hereinafter, the integrated ballast water treatment module 130 will be described as an integrated electrolytic solution that operates in accordance with an electrolytic indirect method among various ballast water treatment methods. However, the present invention is not limited to the chemical infusion method using a side stream It is needless to say that redundant equipment and / or piping can be omitted by applying an integrated ballast water treatment module similarly to chlorine-based chemicals, peracetic acid, hydrogen peroxide, and ozone injection method.

The integrated ballast water treatment module 130 includes a pressurizing pump 131, an electrolytic bath 132, a rectifier 133, a gas-liquid separator 134, a blower 135, and flow control valves 138 and 139.

The pressurizing pump 131 provides some of the ballast water supplied from the pretreatment filter 112 to the electrolytic bath 132. The pressurizing pump 131 is disposed in the vicinity of one end of the side piping 150 branched from the upstream side of the main piping 110 and supplies a constant pressure to the electrolytic bath 132 so as to supply a stable side stream. It can be a maintainable booster pump.

The electrolytic bath 132 electrolyzes the raw water introduced by the pressurizing pump 131, that is, the side stream, to generate hypochlorous acid (HClO) corresponding to the sterilizing material. Hypochlorous acid corresponds to the residual chlorine which kills the organisms to be sterilized in the ballast water.

In this process, the electrolytic bath 132 can change the concentration of the sterilizing liquid by changing the amount of hypochlorous acid produced according to the current value supplied from the rectifier 133.

The electrolytic bath 132 includes an anode portion and a cathode portion. Hypochlorous acid is generated in the cathode portion through an electrolysis process using a current supplied from the rectifier 133, and a byproduct Hydrogen (H ₂ ), chlorine gas (Cl ₂ ), and the like are produced.

The concentration of hypochlorous acid has a predetermined correlation with the current value applied to the side stream in the electrolytic bath 132. The correlation between the current value and the concentration of hypochlorous acid produced may be, for example, in the form of a table or a functional formula (e.g., a linear function such as y = ax where y is the hypochlorous acid concentration, x is the current value, And may be stored in the control unit 140. [0033]

That is, the control unit 140 generates and outputs a control signal based on the correlation between the stored current value and the concentration of hypochlorous acid, thereby controlling the current value supplied from the electrolytic bath 132 in the rectifier 133 So that the amount of hypochlorous acid produced through electrolysis can be controlled.

The gas-liquid separator 134 removes hydrogen and chlorine gas, which are by-products irrelevant to the equilibrium water treatment, among the substances generated in the electrolytic bath 132. That is, electrolytic water containing a high concentration of hypochlorous acid in the liquid component is allowed to pass therethrough to separate only hydrogen and chlorine gas of the gaseous component from being injected into the main stream. The blower 135 is configured to introduce external air into the gas-liquid separator 134 for removal of gas components.

The electrolytic water of the liquid component in which the gas component has been separated in the gas-liquid separator 134 is branched and discharged at the downstream point of the main piping 110 and the AP piping 120 by the first and second flow control valves 138, Are injected and mixed into the main stream and the AP stream, respectively. The first and second flow control valves 138 and 139 are installed in the first branch 151 and the second branch 152 of the side piping 150, respectively.

In the main piping 110 located downstream of the main stream, the seawater flowing into the main ballast tank 2 and the electrolytic water generated by the integrated ballast water treatment module 130 are mixed, and the AP piping The ballast water flowing into the AP ballast tank 3 and the electrolytic water generated in the integrated ballast water treatment module 130 are mixed.

The electrolytic water produced in the integrated ballast water treatment module 130 contains a high concentration of hypochlorous acid and merges at downstream points of the main stream and the AP stream and undergoes dilution and complete mixing so that the main stream and the AP stream have appropriate concentrations So that the treated water can be sterilized smoothly for a large amount of seawater (main stream and AP stream).

The residual chlorine measuring sensors 114 and 124 are provided downstream of the points where the electrolytic water generated in the integrated ballast water processing module 130 is injected in the main piping 110 and the AP piping 120, Respectively.

The control unit 140 controls the functions of each component included in the ship ballast water treatment apparatus. The control unit 140 controls the total flow rate of the electrolytic water generated in the electrolytic bath 132 based on the flow rate of the main piping 110 and the residual chlorine, the flow rate of the AP piping 120, The flow rate of the electrolytic water injected into the AP pipe 120, and the flow rate of the electrolytic water injected into the AP pipe 120 are controlled. By this flow rate control, the concentration of residual chlorine contained in the ballast water flowing into the main ballast tank 2 and the AP ballast tank 3 can be made uniform.

4, Qmain denotes the flow rate of the main pipe 110, Qap denotes the flow rate of the AP pipe 120, Qele denotes the total flow rate of the electrolytic water generated in the electrolytic bath 132, Qimain denotes the flow rate of the electrolytic water generated in the main pipe 110 And Qiap represents the flow rate of the electrolytic water injected into the AP pipe 120 in the Qele.

The control unit 140 dilutes the hypochlorous acid in each piping to have a target residual chlorine concentration value when injecting the electrolytic water flow corresponding to Qimain and Qiap for Qmain and Qap, respectively. The control unit 140 controls the flow rate control valves 138 and 139 so that the high concentration of hypochlorous acid is appropriately distributed to the Qimain and the Qiap .

That is, the control unit 140 can control the residual chlorine concentration of the Qmain and the Qap by adjusting the current value and the flow rate. The control unit 140 may be provided with a data value for the relation between the current and the hypochlorous acid production concentration and the relation between the residual chlorine concentration of Qmain and Qap depending on the Qimain and Qiap values at the specific hypochlorous acid concentration.

The flow chart of the flow control in the controller 140 will be described in detail as follows.

5 is a flowchart of a flow rate control method performed in a ship ballast water treatment apparatus according to an embodiment of the present invention.

The control unit 140 receives the flow rate measured by the main ballast pump 111 and the flow meters 112 and 122 located at the rear end of the AP ballast pump 121 at step S210.

The control unit 140 supplies the flow rate value Qele to be flowed into the electrolytic bath 132 to the electrolytic bath 132 in the rectifier 133 so as to inject the target residual chlorine concentration into Qmain and Qap The current value is determined (step S220).

When electrolysis is performed in the electrolytic bath 132 to generate a high concentration of hypochlorous acid, the flow rate of the electrolytic water is measured in the flow meter 136 located at the rear end of the gas-liquid separator 134, and the measured flow rate is transmitted to the controller 140 The control unit 140 controls the flow rate control valves 138 and 139 based on the input data of the flow rate-residual chlorine concentration so as to distribute the electrolytic water containing the hypochlorous acid at a high concentration to the Qimain and the Qiap (Step S230) Step S240).

When hypochlorous acid is injected into the main piping 110 and the AP piping 120 at the flow rates of Qimain and Qiap at step S250, the residual chlorine measuring sensors 114 and 124 at the subsequent stage measure the residual chlorine concentration value, 140 (step S260).

At this time, the measured residual chlorine concentration value is compared with a target residual chlorine concentration value (step S270). When the target residual chlorine concentration value is obtained as a result of comparison, the flow rate value of the current value of the rectifier 133, Qimain, Qiap is maintained as it is (step S280), and the residual chlorine concentration value is set to a predetermined error range The remaining chlorine measuring sensors 114 and 124 and the control unit 140 perform continuous feedback so that at least the flow rate values of the current values of the rectifier 133, Qimain and Qiap So that the target residual chlorine concentration value is achieved (step S290).

In the present invention, three types of flow rate control scenarios can be derived depending on whether the main ballast tank 2 and the AP ballast tank 3 are in operation. Case 1 is the time when only the main ballast tank 2 is operated, Case 2 is the case where only the AP ballast tank 3 is operated, and Case 3 is the case where the main ballast tank 2 and the AP ballast tank 3 are operated simultaneously . The flow control in each case is as follows.

FIG. 6 is a flow chart according to one scenario of a flow rate control method performed in a ship ballast water treatment apparatus according to an embodiment of the present invention, and FIG. 7 is a flow chart of a flow rate control method performed in the ship ballast water treatment apparatus according to an embodiment of the present invention. Fig. 5 is a flowchart according to another scenario of the control method. Fig.

6, the flow rate Qmain (or Qap) of the main piping 110 (or the AP piping 120) is first measured using the flow meter 112 or 122 in Case 1 (or Case 2) (Step S310).

The flow rate Qele flowing into the integrated ballast water treatment module 130 is measured using the flow meter 136 (step S320), and the flow rate Qmain (or Qap) measured in step S310 is taken into consideration to calculate the target hypochlorous acid The current value supplied to the electrolytic bath 132 is adjusted so that injection can be performed (step S330).

After the generated hypochlorous acid is injected into the main piping 110 (or the AP piping 120), the diluted concentration is sensed through the sensor 114 or 124 and fed back so as to continuously supply the hypochlorous acid (Step S340).

Referring to FIG. 7, in case 3, the flow rates Qmain and Qap of the main piping 110 and the AP piping 120 are measured using the flow meters 112 and 122 (step S410). The controller 140 calculates the flow rate of the main piping 110 and the flow rate of the AP piping 120 (step S420).

The flow rate Qele flowing into the integrated ballast water treatment module 130 is measured using the flow meter 136 (step S430). In step S440, the control unit 140 adjusts the current value supplied to the electrolytic bath 132 so that the target hypochlorous acid injection can be performed in consideration of the summed flow rate in step S420.

The generated hypochlorous acid is distributed and injected at a flow rate ratio of the main piping 110 and the AP piping 120 (step S450), and the diluted concentration after the injection is sensed through the sensors 114 and 124, The current value is maintained or adjusted to enable the target hypochlorous acid injection (step S460).

It is needless to say that the flow rate control method described above may be performed in an automated procedure in a time-series sequence by a built-in or installed program in the digital processing apparatus. The codes and code segments that make up the program can be easily deduced by a computer programmer in the field. In addition, the program is stored in a computer readable medium readable by the digital processing apparatus, and is read and executed by the digital processing apparatus to implement the method. The information storage medium includes a magnetic recording medium, an optical recording medium, and a carrier wave medium.

In the above description, the integrated ballast water treatment method is described as an electrolysis method. However, the scope of the present invention is not limited thereto. For example, according to the embodiment, ozone injection method, The present invention can be applied to any ship ballast water treatment apparatus that processes the ship water.

In the case of the ozone injection system, the ship ballast water treatment system is an integrated ballast water treatment module, in which a portion of the ship ballast water is introduced into the main pipeline instead of the integrated electrolytic facility described above, mixed with ozone generated from the ozone generator, And an injector injected into the main piping and the AP piping. In the case of the chemical injection system, the ship ballast water treatment system is an integrated ballast water treatment module. Instead of the integrated electrolytic system described above, the ship water ballast water treatment system is used to sterilize ship equilibrium water from the storage tank storing the sterilization- And an injector for injecting the main pipe and the AP pipe into the main pipe and the AP pipe.

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 or scope of the invention as defined in the following claims And changes may be made without departing from the spirit and scope of the invention.

1: Vessel 2: Main ballast tank
3: AP Ballast Tank 111: Main Ballast Pump
121: AP ballast pump 112, 122: flow meter
113, 123: Pretreatment filter 114, 124: Residual chlorine measuring sensor
130: integrated ballast water treatment module 131: pressure pump
132: Electrolysis tank 133: Rectifier
134: gas-liquid separator 135: blower
136, 137: Flowmeter 138, 139: Flow control valve
140: control unit 150: side piping

Claims (9)

A ship ballast water treatment apparatus provided in a ship provided with a main ballast tank and an after-perpendicular ballast tank (AP), and having a main pipeline to the main ballast tank and an AP pipeline to the AP ballast tank,
A plurality of flow meters for measuring a flow rate of the main piping, a flow rate of the AP piping, and a flow rate of a sterilizing liquid for sterilizing ship equilibrium water flowing along the main piping and the AP piping;
An integrated ballast water treatment module for controlling an amount of the sterilization liquid injected into the main piping and the AP piping by using a plurality of flow control valves; And
And a control unit for controlling operations of the plurality of flow rate control valves in accordance with the flow rate of the main pipe and the flow rate of the AP pipe measured by the plurality of flow meters. The method according to claim 1,
The integrated ballast water treatment module comprises:
An integrated electrolytic facility for introducing a part of the ship equilibrium water from the main pipeline and generating electrolytic water containing hypochlorous acid at a predetermined concentration by an electrolysis method as the sterilizing liquid and dispensing the electrolytic water into the main piping and the AP piping,
An injector injected into the main pipe and the AP pipe by distributing a mixed liquid mixed with ozone generated from an ozone generator into the main pipe and a portion of the ballast water from the main pipe,
And the injector injects the medicine into the main pipe and the AP pipe from the storage tank storing the medicine having the sterilizing function previously shipped to the ship for sterilizing the ship equilibrium water, Processing device. 3. The method of claim 2,
In the integrated electrolytic facility,
A pressurizing pump for introducing part of the ballast water into the side stream in the main piping,
And an electrolysis tank for electrolyzing the side stream in accordance with a current value applied by the rectifier to generate the electrolytic water. The method of claim 3,
Wherein the controller further controls the current value corresponding to the flow rate of the main pipe and the flow rate of the AP pipe measured in the plurality of flow meters. The method according to claim 1,
Further comprising: a sensor installed in each of the main piping and the AP piping to measure a dilution concentration of the sterilization liquid,
Wherein the control unit further controls the total amount of the sterilizing liquid in accordance with the concentration of the sterilization liquid diluted in the main piping and the AP piping. Flow rate control in a control unit of a ship ballast water treatment apparatus provided in a ship provided with a main ballast tank and an AP (after-perpendicular) ballast tank, and having a main piping to the main ballast tank and an AP piping to the AP ballast tank In the method,
(a) measuring a flow rate of the main pipe and a flow rate of the AP pipe;
(b) determining an amount of sterilizing liquid that sterilizes ship ballast water traveling along the main piping and the AP piping in the control unit; And
(c) controlling the operation of the plurality of flow control valves to regulate an amount of the sterilization liquid injected into the main piping and the AP piping. The method according to claim 6,
(d) measuring the concentration of the sterilization liquid diluted in the main piping and the AP piping; And
(e) maintaining or adjusting the amount of the sterilizing liquid according to the measurement result. The method according to claim 6,
The step (b)
(b1) determining a flow rate value of a side stream branched from the main pipe and a current value to be supplied to the electrolysis bath in the rectifier;
(b2) measuring the flow rate of electrolytic water containing hypochlorous acid at a predetermined concentration produced by electrolysis in the electrolytic bath,
Wherein the step (c) controls the plurality of flow control valves based on the input data of the flow rate-residual chlorine concentration and distributes the flow rate of the electrolytic water injected into the main pipe and the AP pipe. 9. The method of claim 8,
(d) measuring the concentration of the hypochlorous acid diluted in the main piping and the AP piping; And
(e) maintaining the flow rate value and the current value of the side stream or adjusting at least one of the flow rate value and the current value of the side stream according to the measurement result.

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