KR20180015605A - Ballast water treatment device and ballast water treatment method - Google Patents

Abstract

The ballast water treatment apparatus 1 of the present invention includes a filter 52 for filtering the ballast water W, a casing 51 for housing the filter 52, A first line L1 through which the ballast water W1 flows and a second line L11 through which the ballast water W2 filtered by the filter 52 flows toward the ballast tank 62 storing the ballast water W2, A storage water supply section 45 for supplying the storage water Wk to the casing 51 and a storage water supply section 45 for substantially filling the internal space 51a of the casing 51 with the storage water Wk, And a control section (9) for controlling the control section (45).

Description

TECHNICAL FIELD [0001] The present invention relates to a ballast water treatment apparatus and a ballast water treatment method,

The present invention relates to a ballast water treatment apparatus having a filter for filtering ballast water, and a ballast water treatment method. The present application claims priority based on Japanese Patent Application No. 2015-108430, filed on May 28, 2015, the contents of which are incorporated herein by reference.

When a vessel such as a tanker descends a crude oil or the like of a cargo and then navigates to a destination again, water called ballast water is generally stored in a ballast tank installed in the vessel in order to balance the ship under running. The ballast water is basically taken from the river only, and discharged from the river only. Therefore, if their locations are different, microbes of plactones and fungi contained in the ballast water will travel all over the world. Therefore, if the ballast water is discharged from the port of loading (loading port) and the loading port of another sea area (loading port), microbes in the other sea area may be released to that port, which may destroy the ecosystem in the sea area.

A ballast water treatment apparatus is used to reduce the content of microorganisms contained in the ballast water. Further, the ballast water treatment apparatus may be provided with a filter for filtering the ballast water.

Japanese Patent Application Laid-Open No. 2010-254281

In the ballast water treatment apparatus, corrosion and seawater scale attachment may occur due to the ballast water (mainly seawater), and these are required to be suppressed. Further, surface treatment such as galvanizing may be applied to the inside of the line through which the ballast water flows (see [0072] of Patent Document 1). In this case, zinc or the like is eluted from the surface treatment, and the eluted material eluted has an adverse effect on various rotating shafts and driving parts in the ballast water treatment apparatus.

The present invention provides a ballast water treatment apparatus capable of suppressing corrosion and adhesion of seawater scale caused by ballast water and suppressing elution of a leached material from a surface treatment, and a ballast water treatment method The purpose.

The present invention relates to a ballast water filtration system, comprising: a filter for filtering ballast water; a casing accommodating the filter; a first line through which the ballast water flows toward the filter; and a ballast water filtered by the filter, And a control section for controlling the storage water supply section so as to substantially fill the internal space of the casing with the storage water at the time of stopping the operation of the ballast water treatment apparatus .

The apparatus may further include a water level detector for detecting a water level of the internal space of the casing, wherein when the water level detected by the water level detector reaches a predetermined lower limit water level, The storage water supply unit may be controlled to start.

The control unit may control the storage water supply unit to stop the supply of the storage water to the casing when the water level detected by the water level detection unit becomes the predetermined upper limit water level or more.

The ultraviolet irradiation unit may further include an ultraviolet irradiation unit installed on the second line for irradiating ultraviolet rays to the ballast water flowing through the second line, the storage water supply unit supplies storage water to the ultraviolet irradiation unit, The storage water supply portion may be controlled so as to substantially fill the internal space of the ultraviolet ray irradiating portion with the storage water when the operation is stopped.

The present invention is characterized in that when the ballast water treatment apparatus including the filter for filtering the ballast water and the casing for housing the filter is stopped, the storage water is supplied to the casing so as to substantially fill the internal space of the casing with the storage water And a ballast water treatment method.

The supply of the storage water to the casing may be started when the level of the internal space of the casing is detected and the detected level becomes less than a predetermined lower limit level.

When the detected water level is equal to or higher than a predetermined upper limit water level, the supply of the water for storage to the casing may be stopped.

(Effects of the Invention)

According to the present invention, there is provided a ballast water treatment apparatus and ballast water treatment method capable of suppressing corrosion and adhesion of seawater scale attributable to ballast water and inhibiting the elution of leached substances from the surface treatment .

1 is a flow chart showing an embodiment of a ballast water treatment apparatus of the present invention.
Fig. 2 is a diagram schematically showing a part of Fig. 1 in an enlarged manner.
3 is a flowchart showing the control of the supply of the storage water in the embodiment.

One embodiment of the ballast water treatment apparatus of the present invention will be described with reference to the drawings. 1 is a flow chart showing an embodiment of a ballast water treatment apparatus of the present invention. Fig. 2 is a diagram schematically showing a part of Fig. 1 in an enlarged manner.

1, the ballast water treatment apparatus 1 of the present embodiment includes a ballast water filtration apparatus 2, an ultraviolet reactor 61 as an ultraviolet irradiation unit, a backwash water supply unit 7, a storage water supply unit 45, and a control unit 9. [ The control unit 9 is connected to each device by a signal line (not shown) so that each device to be controlled can be controlled. A ballast tank 62, a first clean water tank 65, and a second clean water tank (clean water tank) 66 are connected to the ballast water treatment apparatus 1 as an external configuration thereof.

The ballast water treatment apparatus 1 includes a line L1 as a first line, a line L2, a line L11 as a second line, a line L12, a line L21, A line L24, and a line L31. The term " line " is a generic term for a line through which fluid such as a flow path, a path, and a pipeline can flow.

The ballast water treatment apparatus 1 further includes a line L41, a line L42, a line L43, a line L44 and a line L45 as a line for the storage water supply unit 45 Respectively.

The ballast water filtering apparatus 2 includes a casing 51, a filter 52, a filter rotating means 3, a suction nozzle 4, a backwash water spray nozzle 6, 5, a filter differential pressure measuring means 8, and a first water level detecting portion 53 (see FIG. 2) as a water level detecting portion.

The casing 51 is cylindrical and accommodates the filter 52 therein. The filter 52 has a cylindrical shape when viewed from the whole and filters the ballast water W1 (mainly seawater) as the for-treatment water flowing into the inside thereof, and flows out to the outside as the filtered water W2. The filter rotating means 3 rotates the filter 52 around its axis. The suction nozzle 4 is provided on the primary side of the filter 52 and opens toward the inner peripheral surface of the filter 52.

The backwash water injection nozzle 6 is provided on the secondary side of the filter 52 and injects backwash water during the ballast water treatment operation toward the outer peripheral surface of the filter 52. The injection of the backwash water from the backwash water injection nozzle 6 is performed in the state where the ballast water W2, W1 is present (filled) in the casing 51 and the filter 52. [

The backwashing wastewater discharging means 5 discharges the backwashing wastewater W11 sucked by the suction nozzle 4 from the inside of the casing 51 to the outside. The filter differential pressure measuring means 8 measures the differential pressure between the primary side and the secondary side of the filter 52. The control unit 9 controls the presence or absence of injection of backwash water, the injection pressure at the time of injection of the backwash water, and the like based on the differential pressure measured by the filter differential pressure measuring means 8 and the like.

Details of the ballast water filtration device 2 will be described later.

The ultraviolet reactor 61 irradiates ultraviolet rays to the ballast water (filtration treatment water) W2 filtered by the filter 52 of the ballast water filtration device 2. [ The ultraviolet reactor 61 has a second water level detection unit 63 (see Fig. 2). Details of the ultraviolet reactor 61 will be described later.

The ballast tank 62 stores the ballast water (filtration treatment water) W2 that has been irradiated with ultraviolet rays by the ultraviolet reactor 61 as the stored treatment water W3.

The ultraviolet reactor 61 irradiates ultraviolet rays to the stored water W3 when ballast water (stored water W3) stored in the ballast tank 62 is discharged outboard.

The first clean water tank 65 stores the first clean water W5 separately prepared from the ballast water. The second clean water tank 66 stores the second purified water W6 separately prepared from the ballast water. The first clean water tank 65 and the second clean water tank 66 may be made of the same tank (the same tank may be shared).

The "ballast water" may be supplied to the ballast tank 62 before it is introduced (introduced) into the ballast tank 62 or after it is discharged (discharged) from the ballast tank 62, Ballast water "irrespective of whether it is discharged (flowed out) from the ultraviolet reactor 61 or before (introduced) into the ultraviolet reactor 61 or after discharged (outflow) from the ultraviolet reactor 61. Also, the "ballast water" is appropriately expressed as "for-treatment water", "filtration water", "storage water", "drainage" Also, the ballast water includes seawater, fresh water, and nose.

Next, each line will be described in detail. The line L1 is connected to the introduction port 20 at the other end of the ballast water WTP (mainly water for treatment) from one end thereof and the ballast water W1 And flows toward the introduction port 20 of the device 2. [ A pump P1, a valve V1, a connecting portion J1, and an inlet 20 are connected to the line L1 in this order.

The line L2 is connected to the connection J1 of the line L1 at one end and the line through which water (ballast water W1) in the filter 52 is discharged from the other end.

The line L11 is connected at one end to the outlet 26 of the ballast water filtration device 2 and at the other end to the ballast tank 62. The ballast water filtration device 2 performs filtration (Filtration treatment water) W2 flows toward the ballast tank 62. The ballast water (W2) The line L11 is provided with an outlet 26, a connection J21, a valve V11, a connection J11, an ultraviolet reactor 61, a valve V12 and a ballast tank 62 in this order.

The line L12 is connected to the connection J11 of the line L11 at one end and is a line for discharging the ballast water (stored water W3) from the other end. The line L12 is provided with a connection J11, a valve V13 and a pump P11 in this order.

The line L21 is connected to the connection J21 of the line L11 at one end and connected to the backwash water injection nozzle 6 at the other end. The ballast water (filtration treatment water) W2 flows to the backwashing water purifying nozzle 6 on the line L21. The line L21 is provided with a connection J21, a valve V21 and a pump P21 in this order.

The line L24 is connected to the first clean water tank 65 at one end and connected to the connection J24 of the line L21 at the other end. The connection J24 is provided between the valve V21 and the pump P21 in the line L21. The first clean water W5 stored in the first clean water tank 65 is circulated in the line L24 as backwash water.

A description will be given of a line related to the storage water supply unit 45. Fig. The line L41 is a line in which the first storage water W1c (seawater) is introduced from one end and connected to the connection J41 at the other end. In the line L41, seawater W1c flows as (first) storage water. The connection section J41 is a connection between the line L41 and the line L42 and the line L43. A valve V41 is connected to the line L41.

The line L42 is connected to the second clean water tank 66 at one end and connected to the connection J41 at the other end. And the second purified water W6 stored in the second clean water tank 66 flows to the line L42 as (second) storage water. A valve V42 is connected to the line L42.

The line L43 is connected to the connection J41 at one end and is connected to the connection J42 at the other end. The connection J42 is a connection between the line L43 and the line L44 and the line L45. The seawater W1c or the second purified water W6 flows through the line L43. A pump P41 is connected to the line L43. The pump P41 sucks and pressurizes the water flowing through the line L43.

The line L44 is connected to the connection portion J42 at one end and is in communication with the internal space 51a of the casing 51 at the other end. The sea water W1c or the second purified water W6 (storage water Wk) flows through the line L44. A valve V44 is connected to the line L44.

The line L45 is connected to the connection portion J42 at one end and communicates with the internal space 61a of the ultraviolet reactor 61 at the other end. The seawater W1c or the second purified water W6 (the water for storing water Wk) flows in the line L45. A valve V45 is connected to the line L45.

Various valves and pumps are installed in each line. Specifically, the pump P1 is provided on the upstream side of the connecting portion J1 in the line L1. The pump P1 pumps ballast water (for-treatment water) W1 (mainly sea water) from one end of the line L1. A valve V1 is provided between the pump P1 and the connection J1 in the line L1. The line L2 is provided with a valve V2. The line L24 is provided with a valve V24.

A valve V11 is provided between the outlet 26 of the line L11 and the ultraviolet reactor 61 (more specifically, between the connection J21 and the connection J11). A valve V12 is provided between the ultraviolet reactor 61 and the ballast tank 62 in the line L11. The line L12 is provided with a valve V13 and a pump P11. The pump P11 sucks (pressurizes) the water flowing through the line L12.

A valve V21 is provided between the connection portion J21 in the line L21 and the pump P21. A pump P21 is provided between the valve V21 in the line L21 and the backwash water injection nozzle 6. The pump P21 sucks (pressurizes) the water flowing through the line L21.

The reservoir water supply unit 45 is composed of a pump P41, a valve V41, a valve V42, a valve V44, a valve V45, and the like. The storage water supply unit 45 selectively pressurizes the seawater W1c introduced from the line L41 or the second purified water W6 stored in the second purified water tank 66 as the storage water, Or the ultraviolet reactor 61.

Specifically, the storage water supply unit 45 pressurizes the seawater W1c introduced from the line L41 as the first storage water, supplies it to the casing 51 via the line L44, and / (L45) to the ultraviolet reactor (61). The storage water supply unit 45 pressurizes the second clean water W6 stored in the second clean water tank 66 and the line L42 as the second storage water, Is supplied to the casing (51), and / or supplied to the ultraviolet reactor (61) through the line (L45).

The opening / closing pattern of the valve in the storage water supply portion 45 is as follows.

The valve V41 is opened and the valve V42 is closed when the seawater W1c introduced from the line L41 is selectively flowed toward the connection J41.

When the second clean water W6 stored in the second clean water tank 66 is selectively flowed toward the connection J41, the valve V42 is opened and the valve V41 is closed.

When the seawater W1c or the second purified water W6 (storage water Wk) pressurized by the pump P41 is supplied to both the casing 51 and the ultraviolet reactor 61, the valve V44 and the valve (V45) are opened.

When the seawater W1c or the second purified water W6 (storage water Wk) pressurized by the pump P41 is supplied to the casing 51 and not supplied to the ultraviolet reactor 61, And closes the valve V45.

When the seawater W1c or the second purified water W6 (storage water Wk) pressurized by the pump P41 is supplied to the ultraviolet reactor 61 and not supplied to the casing 51, And closes the valve V44.

Next, details of the ballast water filtering apparatus 2 will be described. The casing 51 is formed in a cylindrical shape having an upper opening portion and a lower opening portion. The upper opening portion is closed by the lid portion 10, and the lower opening portion is closed by the bottom portion 11. [ The lid portion 10 is connected to the line L31. The line L31 is provided with an air discharge valve V31 for discharging the air inside the casing 51. [

The first water level detection unit 53 detects the water level H1 of the internal space 51a of the casing 51. [ The first water level detection unit 53 determines whether the water level H1 of the internal space 51a of the casing 51 is less than the predetermined lower limit water level H1L or not higher than the lower limit water level H1L and less than the upper water level H1h , Or the upper water level H1h or higher can be detected.

The first water level detection unit 53 includes a lower limit water level detection electrode 53a and an upper limit water level detection electrode 53b. The lower end of the lower limit level detecting electrode bar 53a is located below the lower end of the upper limit water level detecting electrode bar 53b.

The water level H1 of the internal space 51a of the casing 51 is lowered to a predetermined lower limit level based on whether or not the lower end portion of the lower limit water level detection electrode rod 53a is in contact with water in the internal space 51a of the casing 51 It is possible to detect whether or not the lower limit water level H1L is lower than the lower limit water level H1L (does not make contact) and the lower limit water level H1L (contact). The detection signal by the lower limit level detecting electrode rod 53a is transmitted to the control unit 9. [

The water level H1 of the internal space 51a of the casing 51 is lower than a predetermined upper water level (lower limit level) based on whether the lower end portion of the upper water level detection electrode rod 53b is in contact with water in the internal space 51a of the casing 51 It is possible to detect whether it is less than the upper limit water level H1h (does not make contact) or is higher than the upper water level H1h (makes contact). The detection signal by the upper limit level detecting electrode rod 53b is transmitted to the control unit 9. [

The transmission of the detection signal to the control unit 9 is started at the start of the storage operation after the normal operation such as filtration treatment or cleaning of the ballast water treatment apparatus is stopped.

The other end of the line L44 is connected to the first storage water inlet 46. [ The storage water Wk flowing through the line L44 is introduced into the internal space 51a of the casing 51 through the first storage water inlet 46. [ 2, the first storage water introducing port 46 is connected to the upper portion of the inner space 51a of the casing 51, but the present invention is not limited to this and the inner space 51a of the casing 51 Or may be connected to the vicinity of the bottom of the housing.

The filter 52 has an upper opening portion and a lower opening portion, and is formed into a cylindrical shape as a whole. A treatment water outflow space 27 is formed between the casing 51 and the filter 52. The upper opening is closed by the upper closure part (13). The lower opening portion is sealed by the lower closure portion 14 and the lower rotating shaft member 16 described later.

The filter rotating means 3 is constituted by an upper rotating shaft member 15, a lower rotating shaft member 16 and a motor 17 for rotating the upper rotating shaft member 15. The upper rotating shaft member 15 is provided on the upper closure part 13 of the filter 52 so as to protrude upward in the axial direction at the axial center position of the filter 52. The lower rotating shaft member 16 is provided in the lower closure part 14 of the filter 52 so as to protrude downward in the axial direction at the axial center position of the filter 52.

The upper rotating shaft member 15 is rotatably and liquid-tightly supported by the lid portion 10 through the lid portion 10 of the casing 51 and through the sealed bearing member 18. The lower rotating shaft member 16 is rotatably and liquid-tightly supported on the bottom portion 11 through the bottom portion 11 of the casing 51 and also through the sealed bearing member 19. The lower rotating shaft member 16 is a tubular member communicating with the inside of the filter 52 and protrudes from the bottom 11 of the casing 51 to the outside of the casing 51. An inlet 20 to the casing 51 is connected to the lower rotating shaft member 16.

A line L1 is connected to the introduction port 20. An outlet 26 is formed at the side of the casing 51. A line L11 is connected to the outlet 26.

The water L1 to be treated flows into the filter 52 through the lower rotary shaft member 16 and the WTBT introduced from the inlet 20 enters the interior of the filter 52 through the lower rotary shaft member 16. [ The untreated water W1 is filtered through the filter 52 and enters the treated water discharge space 27 formed between the casing 51 and the filter 52 and flows out from the outlet 26.

The backwashing wastewater discharging means 5 includes a backwashing / collecting wastewater collection pipe 28 as a backwashing / washing wastewater line through which backwash water flows, a backwashing wastewater discharge pipe 29 as a backwashing wastewater line, and a valve V32. The backwashing wastewater collection pipe 28 is connected to the suction nozzle 4. In the backwashing wastewater collection pipe 28, the backwashing wastewater W11 sucked by the suction nozzle 4 is collected. The backwashing wastewater discharge pipe (29) is connected to the lower end of the backwashing wastewater collection pipe (28) and discharges the backwashing wastewater (W11) to the outside. The valve (V32) is installed in the backwashing wastewater discharge pipe (29).

In the backwashing wastewater collection pipe 28, the upper end is closed and the lower end is opened. The backwashing wastewater collection pipe 28 is disposed at the axial center of the filter 52. The upper end of the backwashing wastewater collection pipe 28 is supported by being fitted in a hole formed at the center of the upper closure part 13 of the filter 52. The lower end of the backwashing wastewater collecting pipe 28 passes the inside of the lower rotating shaft member 16 of the lower closure part 14 of the filter 52 so as not to interfere with the rotation of the filter 52, 20, respectively.

The suction nozzle 4 is installed on the primary side of the filter 52 and connected to the backwashing dirty collecting pipe 28 and opened toward the inner peripheral surface of the filter 52. The suction nozzle 4 sucks backwashing wastewater W11, which is a backwheel constant sprayed from the backwash water injection nozzle 6 and passed through the filter 52 from the outer circumferential surface toward the inner circumferential surface. It is preferable that the suction nozzle 4 can be suctioned from the entire axial direction of the filter 52. The configuration of the suction nozzle 4 is not particularly limited. For example, a plurality of suction nozzles 4 can be arranged in the linear direction and / or the circumferential direction of the filter 52 at different angles. The suction nozzles 4 arranged at plural angles in the circumferential direction may be arranged at the same height or at different heights.

In the present embodiment, the plurality of suction nozzles 4 are arranged in a straight line in the axial direction (vertical direction) of the filter 52 and connected to the backwashing and dirty collecting pipe 28. The opening of the suction nozzle 4 opened toward the filter 52 at a position opposite to the inner peripheral surface of the filter 52 is in close contact with the inner peripheral surface of the filter 52 in a slidable manner.

The suction nozzles 4 are arranged in two rows in the axial direction of the filter 52 in order to eliminate insufficient tangs between the suction nozzles 4 arranged in the vertical direction, (4). Specifically, the plurality of suction nozzles 4 are arranged alternately in the height direction on the left and right sides of the backwashing wastewater collection pipe 28. As another example of arranging the suction nozzle 4 in the axial direction of the filter 52, there is a case in which a plurality of suction nozzles 4 are not present between the suction nozzles 4 in the axial direction of the filter 52 It may be arranged in a spiral manner at an interval.

The plurality of suction nozzles 4 are arranged in a straight line in the axial direction of the filter 52 in a state in which the opening of the suction nozzle 4 is slidably in close contact with the inner peripheral surface of the filter 52, As shown in FIG. The plurality of suction nozzles 4 arranged in the vertical direction are arranged alternately in the height direction on the right and left sides of the backwashing wastewater collection pipe 28 in order to eliminate insufficient tangs between the suction nozzles 4. Therefore, the filter 52 can be sucked from the entire inner circumferential surface of the filter 52 by one rotation.

The backwashing water jetting nozzle 6 is provided on the side of the casing 51 and opens inside the casing 51. It is preferable that the backwashing water jetting nozzle 6 is capable of injecting a backwash water into the entire axial direction of the filter 52. The constitution of the backwash water spraying nozzle 6 is not particularly limited. It is possible to arrange a plurality of backwashing water injection nozzles 6 in the axial direction of the filter 52 at angles in a straight line and / or a circumferential direction. The plurality of backwashing purified water injection nozzles 6 arranged at different angles in the circumferential direction may be arranged at the same height or at different heights. The backwash water spray nozzles 6 are disposed on the same circumference as the plurality of suction nozzles 4 disposed in the plurality of arranged backwashing water injection nozzles 4 and are arranged so as to face the suction nozzles 4 in the direction opposite to the rotating direction of the filter 52, As shown in FIG. The backwashing water jetting nozzles 6 may be provided at respective positions opposing to the suction nozzles 4 or may be disposed behind the suction nozzles 4 in the direction opposite to the rotating direction of the filter 52 It may be installed so as to be located.

The backwashing water supply means 7 pressurizes the ballast water (filtration treatment water) W2 filtered by the filter 52 and supplies it to the backwash water purifying nozzle 6 as the backwash water W2. The backwashing water supply means 7 is composed of a pump P21, a valve V21, and the like.

The backwash water injection nozzle 6 blows the backwash water W2 to the outer peripheral surface (secondary side) of the filter 52 to remove the foreign matter accumulated on the primary side of the filter 52. [ The suction by the suction nozzle 4 is performed immediately after peeling off. The foreign matters separated from the filter 52 by the backwash water W2 sprayed from the backwashing water jetting nozzle 6 are effectively sucked out by the suction nozzle 4 by opening the valve V32 provided in the backwashing wastewater discharge pipe 29 And is sucked. The pressure inside the backwashing wastewater collection pipe 28 becomes lower than the pressure at the secondary side of the filter 52 and the pressure of the secondary side of the filter V32 The backwash water W2 injected from the backwash water spray nozzle 6 and the part of the filtered water W2 having the filtrate water W2 flow through the interior of the backwashing wastewater collecting pipe 28 as the backwashing wastewater W11, And is discharged to the outside from the discharge pipe (29).

The filter differential pressure measuring means 8 measures the filter differential pressure which is a differential pressure between the primary side and the secondary side of the filter 52. The filter differential pressure measuring means 8 includes a primary pressure sensor 37 disposed inside the filter 52 and a secondary pressure sensor 38 disposed in the process water outlet space 27. [ The filter differential pressure measuring means 8 detects the primary pressure of the filter 52 by the primary pressure sensor 37 and detects the secondary pressure of the filter 52 by the secondary pressure sensor 38, The filter differential pressure between the primary side and the secondary side of the filter 52 is measured. The contamination state of the filter 52 can be determined based on the filter differential pressure. When the filter differential pressure is large, it indicates that the accumulation amount of the foreign matter on the filter 52 is increasing. When the filter differential pressure is small, the filter 52 is in a state close to the initial state (the accumulation amount of foreign matter is small).

As the backwash water to be supplied to the backwash water injection nozzle 6, the ballast water (filtration treatment water) W2 filtered by the filter 52 is used in the present embodiment. As the backwash water to the filter 52, first purified water W5 stored in the first purified water tank 65 or the like may be used.

The ultraviolet reactor 61 will be described in detail. The second water level detection unit 63 detects the water level H2 in the internal space 61a of the ultraviolet reactor 61. [ The second water level detection unit 63 detects whether or not the water level H2 in the internal space 61a of the ultraviolet reactor 61 is lower than the predetermined lower limit water level H2L or lower than the lower water level H2L and less than the upper water level H2h Or the upper limit water level H2h or higher can be detected.

The second water level detection unit 63 includes a lower limit water level detection electrode 63a and an upper limit water level detection electrode 63b. The lower end of the lower limit level detecting electrode rod 63a is located below the lower end of the upper limit water level detecting electrode rod 63b.

The water level H2 of the internal space 61a of the ultraviolet reactor 61 is set to a predetermined value on the basis of whether or not the lower end portion of the lower limit water level detection electrode rod 63a is in contact with the water in the internal space 61a of the ultraviolet reactor 61 It is possible to detect whether or not the lower limit water level H2L is lower than the lower limit water level H2L (does not touch), and the lower limit water level H2L is higher than the lower limit water level H2L. The detection signal by the lower limit level detecting electrode rod 63a is transmitted to the control unit 9. [

The water level H2 of the internal space 61a of the ultraviolet reactor 61 is set to a predetermined value based on whether or not the lower end portion of the upper limit water level detection electrode rod 63b is in contact with the water in the internal space 61a of the ultraviolet reactor 61 It is possible to detect whether or not the upper limit water level H2h is less than the upper limit water level H2h or not. The detection signal by the upper limit level detecting electrode rod 63b is transmitted to the control unit 9. [

The transmission of the detection signal to the control unit 9 is started at the start of the storage operation after the normal operation such as filtration treatment or cleaning of the ballast water treatment apparatus is stopped.

The other end of the line L45 is connected to the second storage water inlet 47. [ The storage water Wk flowing through the line L45 is introduced into the internal space 61a of the ultraviolet reactor 61 through the second storage water introducing port 47. [

A plurality of protective tubes 61b for liquid-tightly accommodating ultraviolet lamps (not shown) are provided in the inner space 61a of the ultraviolet reactor 61.

When the water level H1 of the internal space 51a of the casing 51 is equal to or more than the lower limit water level H1L or when the water level H2 in the internal space 61a of the ultraviolet reactor 61 is equal to or more than the lower water level H2L Most of the lines, such as line L11, are completely or substantially filled with water.

The control unit 9 controls the storage water supply unit 45 to substantially fill the internal space 51a of the casing 51 and / or the internal space 61a of the ultraviolet reactor 61 with the storage water Wk at the time of the operation stoppage, . "At the time of stopping operation" refers to the time when the normal operation related to the various treatment of the ballast water and the various cleaning treatments of the apparatus is stopped, and is typically during the storage operation. The term " substantially fill " means not only fully filling but also filling to such an extent that the effects of the present invention are exerted.

The control unit 9 controls the level H1 of the internal space 51a of the casing 51 detected by the first water level detection unit 53 and the level H1 of the ultraviolet reactor 61 detected by the second water level detection unit 63 On / off of the pump P41 in the storage water supply unit 45, and opening and closing of the valve are switched based on the water level H2 in the internal space 61a.

The control unit 9 causes the supply of the storage water Wk to the casing 51 to be started when the water level H1 detected by the first water level detection unit 53 becomes less than the predetermined lower limit water level H1L And supply of the storage water Wk to the ultraviolet reactor 61 is started when the water level H2 detected by the second water level detection unit 63 becomes less than the predetermined lower limit water level H2L And controls the supply unit 45.

When the level H1 detected by the first level detector 53 reaches a predetermined upper limit level H1h or higher, the control unit 9 controls the supply of the storage water Wk to the casing 51 The supply of the storage water Wk to the ultraviolet reactor 61 is stopped so that the water level H2 detected by the second water level detection unit 63 becomes equal to or higher than the predetermined upper water level H2h And controls the storage water supply unit 45.

Next, the main processing operation in the normal operation of the ballast water treatment apparatus 1 of the present embodiment will be briefly described.

(1) Filtration of the for-treatment water (W1) by the ballast water filtration device (2) (ballast water treatment operation)

The valve V1, the valve V11 and the valve V12 are opened and the valve V2, the valve V13, the valve V21, the valve V31 and the valve V32 are closed. In this state, the pump P1 is driven. Thus, the for-treatment water W1 flowing from one end of the line L1 flows through the line L1. The ballast water (for-treatment water) W1 introduced from the inlet 20 is filtered by the filter 52 and discharged from the outlet 26 as the filtered water W2. The filtered treatment water W2 flows through the line L11 and is ultraviolet treated by the ultraviolet reactor 61 and stored in the ballast tank 62 as the stored treatment water W3.

(2) Backwashing treatment of the filter 52 by backwashing water jetting nozzle 6 (backwashing during ballast water treatment operation)

The valve V1, the valve V11, the valve V12, the valve V21 and the valve V32 are opened and the other valves are closed and the ballast water (filtration treatment water) W2 (backwash water W2) ) Flows into the backwash water purifying nozzle (6). The suction of the pump P21 and the suction nozzle 4 is activated in a state in which the ballast water W2, W1 is present in the casing 51 and the filter 52. As a result, the backwash water W2 from the backwash water spray nozzle 6 is sprayed toward the filter 52 and backwashed.

(3) Drainage of the stored water W3 from the ballast tank 62 to the outside

The valve V12 and the valve V13 are opened and the valve V11 and the valve V24 are closed. In this state, the pump P11 installed in the line L12 is operated. The ballast water W3 stored in the ballast tank 62 is ultraviolet-ray-treated by the ultraviolet reactor 61 and discharged to the outside through the line L11 and the line L12.

The ballast water treatment apparatus 1 of the present embodiment operates as follows in the storage operation and executes an embodiment of the ballast water treatment method. Fig. 3 is a flowchart showing control of supply of the storage water in the embodiment. Fig.

First, in step S1, the ballast water treatment apparatus 1 is instructed to start the storage operation.

In step S2, the control unit 9 selects the type of storage water (seawater W1c / second clean water W6). For example, in the case of short-term storage (such as during one voyage), the control section 9 selects the first storage water, seawater W1c, based on an instruction signal from the crew or various detection signals. In this case, the valve V41 is opened and the valve V42 is closed.

In the case of long-term storage (such as when the water is taken from a lower port, when anchored for a long period of time), or when the temperature or temperature of sea water (ballast water) is high, The control unit 9 selects the second clean water W6 as the second storage water on the basis of the instruction signal of the control unit 9 and various detection signals. In this case, the valve V42 is opened and the valve V41 is closed. Also, even if the water is stored for a short period of time, the second clean water (W6) may be used as the storage water when the water level drops for some reason during the storage operation.

In step S3, the control unit 9 determines whether the water level H1 of the internal space 51a of the casing 51 detected by the first water level detection unit 53 is less than the lower limit water level H1L, It is determined whether or not the water level H2 of the internal space 61a of the ultraviolet reactor 61 detected by the water level sensor 63 is lower than the lower limit water level H2L.

If the controller 9 determines that the water level H1 is lower than the lower water level H1L or the water level H2 is the lower water level H2L (step S3: YES), the control unit 9 advances the processing to step S4. Further, the control unit 9 returns the processing to step S3 in other cases (step S3: NO).

In step S4, the control unit 9 turns on the pump P41 and activates the pump P41. The control unit 9 also opens the valve V44 and the valve V31 when it is determined that the water level H1 is lower than the lower limit water level H1L. The control unit 9 opens the valve V45 when it is determined that the water level H2 is lower than the lower water level H2L. When the storage water Wk is supplied to both the casing 51 and the ultraviolet reactor 61, the control unit 9 opens both the valve V44 and the valve V45.

The storage water Wk is pressurized by the pump P41 so as to flow through the line L44 and / or the line L45 and is supplied to the casing 51 and / or the ultraviolet reactor 61.

In step S5, the controller 9 determines whether the water level H1 of the internal space 51a of the casing 51 detected by the first water level detection unit 53 is equal to or greater than the upper water level H1h, It is determined whether or not the water level H2 in the internal space 61a of the ultraviolet reactor 61 detected by the water level sensor 63 is equal to or more than the upper water level H2h.

If the control unit 9 determines that the water level H1 is higher than the upper water level H1h or the water level H2 is higher than the upper water level H2h (step S5: YES), the control unit 9 advances the process to step S6. Further, the control unit 9 returns the processing to step S5 in other cases (step S5: NO).

The control unit 9 turns off the pump P41 and closes the valve V41, the valve V42, the valve V44 and the valve V45 in the step S6 and controls the casing 51 and / And stops the supply of the storage water Wk to the reactor 61.

In step S7, the control unit 9 confirms whether or not an instruction to stop the storage operation is received. If the control unit 9 has not received an instruction to stop the storage operation (step S7: NO), the control unit 9 returns the processing to step S3. When the control unit 9 receives an instruction to stop the storage operation (step S7: YES), the control unit 9 controls each unit to stop the storage operation.

According to the ballast water treatment apparatus 1 of the present embodiment, for example, the following effects are exhibited.

The ballast water treatment apparatus 1 of the present embodiment includes a filter 52 for filtering the ballast water W1, a casing 51 for housing the filter 52, and a ballast water W1, A line L11 through which the ballast water W2 filtered by the filter 52 flows toward the ballast tank 62 for storing the ballast water W2, An ultraviolet reactor 61 provided between the ballast tanks 62 for irradiating ultraviolet rays to the filtrate water W2 and a storage tank 62 for storing water Wk (W1c, Wk) in the casing 51 and / And the internal space 51a of the casing 51 and / or the internal space 61a of the ultraviolet reactor 61 at the time of the stop of the operation are stored substantially in the storage water Wk And a control unit (9) for controlling the storage water supply unit (45) so as to fill it.

Therefore, according to the present embodiment, the internal space 51a of the casing 51 and / or the internal space 61a of the ultraviolet reactor 61 at the time of the operation stop such as during the storage operation are substantially stored in the storage water Wk It is filled. Therefore, the internal space 51a of the casing 51 and / or the internal space 61a of the ultraviolet reactor 61 are difficult to dry at the time of stopping the operation. Depending on the structure of the apparatus, the inner space of the line through which the ballast water flows is also substantially filled with the storage water Wk.

It has been said that when it is in a dry state from a flooded state, corrosion due to ballast water (mainly sea water) and adhesion of seawater scale, elution of surface treatment inside the line through which ballast water flows, and the like are likely to occur. However, according to the present embodiment, it is difficult to become a dry state at the time of stopping the operation. For this reason, according to the present embodiment, it is possible to suppress corrosion due to ballast water and adhesion of seawater scale, and to prevent leaching of leached material from the surface treatment.

The ballast water treatment apparatus 1 of the present embodiment includes a first water level detection unit 53 for detecting the water level H1 of the internal space 51a of the casing 51, a first water level detection unit 53 for detecting the water level H1 of the internal space 61a of the ultraviolet reactor 61, And a second water level detection unit 63 for detecting the water level H2 of the water level. The control unit 9 determines whether the water level H1 detected by the first water level detection unit 53 is less than a predetermined lower limit water level H1L and / or when the water level detected by the second water level detection unit 63 Water supply unit 45 to start supply of the storage water Wk to the casing 51 and / or the ultraviolet reactor 61 when the water level H2 becomes lower than the predetermined lower limit water level H2L.

The internal space 51a of the casing 51 and / or the internal space 61a of the ultraviolet reactor 61 are substantially filled with the storage water Wk at the time of stopping the operation easy.

In the present embodiment, the control unit 9 determines whether the water level H1 detected by the first water level detection unit 53 is equal to or higher than the predetermined upper water level H1h and / or when the second water level detection unit 63 The supply of water to the casing 51 and / or the ultraviolet reactor 61 is stopped when the water level H2 detected by the ultraviolet reactor 61 reaches a predetermined upper water level H2h or higher 45).

Therefore, according to the present embodiment, excessive supply of the water for storing water Wk to the internal space 51a of the casing 51 and / or the internal space 61a of the ultraviolet reactor 61 can be suppressed .

The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiment, but can be carried out in various forms.

The seawater W1 introduced through the line L1 may be used as the holding water Wk in the casing 51. [

The configuration of the first water level detection unit 53, the second water level detection unit 63 and the control unit 9 is not limited as long as it can appropriately control the storage water supply unit 45.

The storage water supply unit 45 may be configured to supply the storage water Wk only to one side of the casing 51 or the ultraviolet reactor 61. [ The control unit 9 controls the storage water supply unit 45 such that only one of the internal space 51a of the casing 51 or the internal space 61a of the ultraviolet reactor 61 is filled with the storage water Wk, .

In the above embodiment, the filtration treatment water W2 that is filtered by the filter 52 and does not pass through the ballast tank 62 is used as the backwashing water W2 to the filter 52, but is not limited thereto . The treated water W1 stored in the ballast tank 62 and the purified water (such as domestic water or drinking water) stored in other tanks may be used as the backwash water W2.

In the above embodiment, the ballast water stored in the ballast tank 62 is the ballast water subjected to the filtering treatment by the filter 52 and the ultraviolet treatment by the ultraviolet reactor 61 (ultraviolet ray irradiating unit), but is not limited thereto . The ballast water stored in the ballast tank 62 may be ballast water not subjected to filtration treatment and / or ultraviolet ray treatment.

In the above-described embodiment, the filter 52 is a tubular filter that filters the ballast water W1 flowing therein and flows out to the outside. However, the present invention is not limited to this. The filter may be a tubular filter that filters the ballast water flowing from the outside and flows out from the inside, or may be a non-cylindrical filter.

1: Ballast water treatment system
9:
45: Storage water supply part
51: casing
51a: inner space
52: Filter
53: first water level detection unit (water level detection unit)
61: ultraviolet reactor (ultraviolet ray irradiation part)
61a: inner space
62: Ballast tank
63: second water level detector
66: 2nd clean water tank (clean water tank)
L1: line (first line)
L11: line (second line)
H1: Level
H2: Water level
H1L, H2L: Low water level
H1h, H2h: Upper water level
W1: Water to be treated (ballast water)
W1c: Seawater
W2: Filtration treated water (ballast water)
W6: 2nd clean water (clean water)
Wk, W1c, W6: Storage water

Claims (7)

A filter for filtering the ballast water,
A casing for housing the filter,
A first line through which the ballast water flows toward the filter,
A second line through which the ballast water filtered by the filter flows to a ballast tank storing the ballast water,
A storage water supply unit for supplying storage water to the casing,
And a control section for controlling the storage water supply section so as to substantially fill the internal space of the casing with the storage water when the operation is stopped. The method according to claim 1,
Further comprising a water level detector for detecting the water level of the internal space of the casing,
Wherein the control unit controls the storage water supply unit so as to start supply of the storage water to the casing when the water level detected by the first water level detection unit becomes less than a predetermined lower limit water level. 3. The method of claim 2,
Wherein the control unit controls the storage water supply unit so as to stop supply of the storage water to the casing when the water level detected by the first water level detection unit becomes a predetermined upper water level or more. 4. The method according to any one of claims 1 to 3,
Further comprising an ultraviolet ray irradiating unit installed on the second line for irradiating ultraviolet rays to the ballast water flowing through the second line,
The storage water supply unit supplies storage water to the ultraviolet ray irradiation unit,
Wherein the control unit controls the storage water supply unit so as to substantially fill the internal space of the ultraviolet ray irradiation unit with the storage water when the operation is stopped. Wherein the storage water is supplied to the casing so as to substantially fill the inner space of the casing with the storage water when the ballast water treatment apparatus including the filter for filtering the ballast water and the casing for housing the filter is stopped. 6. The method of claim 5,
Detecting the level of the internal space of the casing,
And the supply of the storage water to the casing is started when the detected water level becomes less than a predetermined lower limit water level. The method according to claim 6,
And stopping the supply of the storage water to the casing when the detected water level becomes a predetermined upper limit water level or more.

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