JP2017100075A - Ballast water treatment apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ballast water treatment apparatus capable of irradiating ballast water with sufficient ultraviolet rays for sterilization when switching a ballast water destination from a ballast tank to another ballast tank.SOLUTION: A ballast water treatment apparatus 1 includes destination switching means V121, V122, V123 for switching destination ballast tanks 62 based on a switching signal, an ultraviolet rays irradiation unit 61 for irradiating filtered water W2 and/or stored water W3 with ultraviolet rays, flow rate regulating means P1, V1, V11 in the ultraviolet rays irradiation unit for regulating a flow rate of water passing the ultraviolet rays irradiation unit 61, and flow rate control means 9 for controlling the flow rate regulating means P1, V1, V11 in the ultraviolet rays irradiation unit so as to reduce the flow rate of water passing the ultraviolet irradiation unit 61 based on the switching signal.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a ballast water treatment apparatus that performs ultraviolet treatment on ballast water.

  In a ship such as a tanker, when navigating to the destination again after unloading the crude oil, etc., the ballast water is generally placed in the ballast tank provided in the ship in order to balance the navigating ship. It stores water called. Ballast water is basically taken at the loading port and discharged at the loading port. Therefore, if they are different, plankton and bacterial microorganisms contained in the ballast water will move around the world. Therefore, if ballast water is discharged from a loading port in a sea area different from the cargo port, microorganisms in another sea area will be released to that port, which may destroy the ecosystem in that sea area.

  As a filter for filtering water to be treated such as ballast water stored in a ship and contaminated water containing other pollutants, a cylindrical filter is provided that filters the water to be treated flowing into the interior and flows it out. A ballast water treatment apparatus having a filter is known. In order to sterilize ballast water, the ballast water treatment apparatus has an ultraviolet irradiation unit that performs ultraviolet treatment to irradiate the ballast water with ultraviolet rays. An ultraviolet irradiation part irradiates ultraviolet rays with respect to the ballast water (filtered water) filtered with the filter of the filter, and performs disinfection (for example, refer patent document 1).

JP 2013-023187 A

  The ship has a plurality of ballast tanks. In order to supply one ballast water to each ballast tank one by one for a plurality of ballast tanks, and appropriately select a ballast tank from a plurality of ballast tanks, and select a ballast tank from the selected ballast tanks. The ship has distribution destination switching means so that water can be discharged.

  Moreover, the illuminance of the ultraviolet rays irradiated from the ultraviolet irradiation unit is detected by an ultraviolet illuminance sensor. Further, the flow rate of the ballast water flowing through the ultraviolet irradiation unit is detected by a flow meter. The flow rate detected by the flow meter and the ultraviolet sensor so that the control unit can irradiate the ballast water with sufficient illuminance with respect to the flow rate of the ballast water flowing through the ultraviolet irradiation unit. Based on the illuminance detected by, the illuminance of ultraviolet rays emitted from the ultraviolet irradiation unit is controlled and adjusted. Further, the flow rate is controlled and adjusted by the flow rate adjusting valve so that the flow rate of the ballast water to be subjected to the ultraviolet ray treatment falls within the rated processing flow rate.

For example, when switching the supply destination of ballast water that has been subjected to UV treatment by the distribution destination switching means, first, the ballast water is supplied to one ballast tank, and a predetermined amount of ballast water is supplied to one ballast tank. When the tank is stored, the supply destination of the ballast water is switched to another ballast tank. At this time, if the ballast water is empty in the other ballast tanks, the resistance when the ballast water flows is drastically reduced, which is far from the flow rate of the ballast water that has flowed into the one ballast tank until now. The flow rate suddenly changes to a higher flow rate. The control of the flow rate adjustment valve cannot follow the change in the flow rate, or the adjustment of the illuminance of the ultraviolet rays from the ultraviolet irradiation unit cannot follow, and the ultraviolet irradiation unit cannot sufficiently sterilize the ballast water. There is a fear.
Further, the same may occur not only when the ballast water is supplied to each ballast tank, but also when the ballast water is discharged from each ballast tank.

  The present invention provides a ballast water treatment apparatus capable of performing sterilization by sufficiently irradiating ultraviolet light onto ballast water when the distribution destination of the ballast water is switched from one ballast tank to another ballast tank. For the purpose.

  The present invention includes a filter for filtering the ballast water as the treated water to obtain filtered treated water, a treated water introduction line through which the treated water flows toward the filter, and the filtered treated water filtered by the filter Is circulated selectively toward a plurality of ballast tanks storing filtered treated water as stored treated water, or a treated water line through which ballast water selectively discharged from the plurality of ballast tanks circulates, Distribution destination switching means for switching the ballast tank at the distribution destination based on the switching signal, an ultraviolet irradiation unit for irradiating the filtered treated water and / or the stored treated water with ultraviolet rays, and water passing through the ultraviolet irradiated unit The ultraviolet irradiation unit passage flow rate adjusting means for adjusting the flow rate of the ultraviolet irradiation unit, and the ultraviolet irradiation unit passage flow so as to reduce the flow rate of water passing through the ultraviolet irradiation unit based on the switching signal. And flow control means for controlling the adjusting means, on Ballast water treatment system comprising a.

  In addition, a switching operation unit that receives a switching operation of the distribution destination switching unit is further provided, and the switching operation unit is configured to output the switching signal when the switching operation of the distribution destination switching unit is received. preferable.

  Further, the storage device further includes a storage amount measuring unit that measures a storage amount of the stored treated water, and the storage amount measuring unit outputs the switching signal based on the storage amount of the stored treated water measured by the storage amount measuring unit. It is preferable that it is comprised.

  Further, the ultraviolet irradiating unit is in contact with the housing member, an ultraviolet lamp, a housing member that directly or indirectly houses the ultraviolet lamp and has a transmission region through which the ultraviolet light from the ultraviolet lamp is transmitted. A cleaning member that moves and cleans the transmission region of the housing member, and the ballast water treatment device includes an ultraviolet illuminance sensor that measures the illuminance of the ultraviolet light emitted from the ultraviolet lamp and transmitted through the transmission region; It is preferable that the apparatus further includes irradiation unit control means for controlling the ultraviolet irradiation unit so as to maintain or increase the output of the ultraviolet lamp based on the timing at which the cleaning member blocks the transmission region.

  According to the present invention, there is provided a ballast water treatment apparatus capable of performing sterilization by sufficiently irradiating ultraviolet light onto ballast water when the distribution destination of the ballast water is switched from one ballast tank to another ballast tank. Can be provided.

It is a flowchart which shows the ballast water treatment apparatus 1 of 1st Embodiment of this invention. It is sectional drawing along the flow of the ballast water W2 which shows the ultraviolet reactor 61 of the ballast water treatment apparatus 1 of 1st Embodiment of this invention. It is sectional drawing in the direction orthogonal to the flow of the ballast water W2 which shows the ultraviolet reactor 61 of the ballast water treatment apparatus 1 of 1st Embodiment of this invention. It is a flowchart which shows control of supply of the ballast water W2 to the ballast tank 62 in the control part 9 of the ballast water treatment apparatus 1 of 2nd Embodiment of this invention. It is a flowchart which shows control of discharge | release of the ballast water W3 from the ballast tank 62 in the control part 9 of the ballast water treatment apparatus 1 of 2nd Embodiment of this invention.

A ballast water treatment apparatus 1 according to a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a flowchart showing a ballast water treatment apparatus 1 according to a first embodiment of the present invention.
[First Embodiment]
As shown in FIG. 1, the ballast water treatment device 1 includes a ballast water filtration device 2, an ultraviolet reactor 61, backwash water supply means 7, and a control unit 9. The control unit 9 is connected to each device by a signal line (not shown) so as to control each device to be controlled. A ballast tank 62 is connected to the ballast water treatment apparatus 1 as an external configuration.

  The ballast water treatment apparatus 1 includes, as lines, a treated water introduction line L1, a treated water discharge line L2, a treated water line L11, a stored treated water discharge line L12, a backwash water distribution line L21, and an air vent. A line L31. “Line” is a general term for lines capable of flowing fluid such as flow paths, paths, and pipelines.

  The ballast water filtration device 2 includes a casing 51, a filter 52, a filter rotating means 3, a suction nozzle 4, a backwash water injection nozzle 6, and a backwash wastewater discharge means 5.

  The casing 51 has a cylindrical shape and houses the filter 52 therein. The filter 52 has a cylindrical shape as a whole, and filters the water to be treated (ballast water) W1 (mainly seawater) that has flowed into the filter 52 so as to flow out to the outside as ballast water (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 (inner surface) of the filter 52.

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

  The backwashing sewage discharge means 5 discharges the backwashing sewage W11 sucked by the suction nozzle 4 from the inside of the casing 51 to the outside.

The ultraviolet reactor 61 performs sterilization by irradiating the ballast water (filtered water) W2 filtered by the filter 52 of the ballast water filtration device 2 with ultraviolet rays. Details of the ultraviolet reactor 61 will be described later.
A plurality of ballast tanks 62 (62-1, 62-2, 62-3) are provided. The ballast tank 62 stores ballast water (filtered water) W2 that has been irradiated with ultraviolet rays by the ultraviolet reactor 61 as stored treated water W3.

The ballast tank 62 includes a water level detection means 42 as a storage amount measurement means. The water level detection means 42 detects the storage amount by detecting the water level of the stored treated water W3 stored in the ballast tank 62. For example, the detected water level is determined by the ballast tank 62 (62-1, 62-2, 62- In 3), it is detected that the first specific water level close to full water or the second specific water level close to the sky in the ballast tank 62 (62-1, 62-2, 62-3) has been reached. The water level detection means 42 is configured to transmit a detection signal to the control unit 9 when it is detected that the water level inside the ballast tank 62 has reached the first specific water level and the second specific water level. Is done.
The ultraviolet reactor 61 sterilizes the stored treated water W3 by irradiating the stored treated water W3 with ultraviolet rays when discharging the ballast water (stored treated water) W3 stored in the ballast tank 62 to the outside of the ship.

  The control unit 9 controls the presence / absence of the backwash water injection, the injection pressure at the time of backwash water injection, and the like based on the differential pressure between the primary side and the secondary side of the filter 52. Further, the control unit 9 draws a pump P1, pump P11, pump P21, and valve V1 as ultraviolet irradiation unit passage flow rate adjusting means so as to reduce the flow rate of water passing through the ultraviolet reactor 61 based on a switching signal described later. , A flow rate control means for controlling the valve V2, the valve V11, the valve V12, the valve V13, the valve V31, and the valve V32. Further, the control unit 9 controls the ultraviolet reactor so as to maintain the output of the ultraviolet lamp 612 based on the timing at which the protective tube cleaning material 618 as a cleaning member described later blocks the transmission region of the peripheral surface of the protective tube 613 described later. The irradiation part control means to control is comprised. Details of the ballast water filtration device 2 and the control unit 9 will be described later.

Next, each line will be described in detail. The treated water introduction line L1 is introduced with treated water W1 (mainly seawater) from one end and is connected to the treated water inlet 20 at the other end, and the treated water W1 is the ballast water filtration device 2. This is a line that circulates toward the treated water inlet 20. The treated water introduction line L1 is provided with a pumping pump P1, a valve V1, a connecting portion J1, and a treated water introduction port 20 in this order.
The treated water discharge line L2 is connected to the connection portion J1 of the treated water introduction line L1 at one end, and is a line through which water (ballast water W1) in the filter 52 is discharged from the other end.
The pumping pump P1, the valve V1, and the valve V11 constitute ultraviolet irradiation unit passage flow rate adjusting means for adjusting the flow rate of water passing through the ultraviolet reactor 61 as the ultraviolet irradiation unit.

  The treated water line L11 is connected to the treated water outlet 26 of the ballast water filtration device 2 at one end, and is one for the plurality of ballast tanks 62-1, 62-2, 62-3 at the connection portion J12 on the way. Branched one by one and connected to the ballast tanks 62-1, 62-2, 62-3 one by one at the other end, respectively, and ballast water filtered by the ballast water filtration device 2 (filtered water) ) W2 is a line that selectively circulates toward the plurality of ballast tanks 62. The treated water line L11 is provided with a treated water outlet 26, a connection portion J21, a valve V11, a connection portion J11, an ultraviolet reactor 61, a flow meter 43, a connection portion J12, a valve V12, and a ballast tank 62 in this order.

  The valve V12 includes a plurality of distribution destination switching valves V121, 122, 123 (hereinafter referred to as “switching valves V121, V122, V123”), and the switching valves V121, 122, 123 are branched treated water lines L11. Are provided one by one. In the switching valves V121, 122, and 123, an operation switch (not shown) as a switching operation unit that receives a switching operation of the switching valves V121, 122, and 123 is operated by an operator, and opening / closing is controlled by the control unit 9. Is done. When a switching operation of the switching valves V121, 122, 123 is accepted, an operation switch (not shown) outputs a switching signal to the control unit 9. Then, under the control of the control unit 9, for example, the switching valves V121 and V123 are closed, the switching valve V122 is opened, the supply destination of the ballast water W2 supplied to the ballast tank 621 is switched, and the ballast water W2 is generated. , And is configured to be supplied to an empty ballast tank 622. The switching valves V121, 122, 123 constitute distribution destination switching means for switching the distribution destination ballast tank 62 (62-1, 62-2, 62-3) based on a switching signal described later. The flow meter 43 measures the flow rate of the ballast water W2 flowing through the treated water line L11.

  The stored treated water discharge line L12 is connected to the connecting portion J11 of the treated water line L11 at one end, and discharges ballast water (stored treated water) W3 from the other end. In the stored treated water discharge line L12, a connecting portion J11, a valve V13, and a stored treated water discharge pump P11 are provided in this order.

  The backwash water distribution line L21 is a line that is connected to the connection portion J21 of the treated water line L11 at one end and is connected to the backwash water jet nozzle 6 at the other end. Ballast water (filtered water) W <b> 2 flows toward the backwash water distribution line L <b> 21 toward the backwash water injection nozzle 6. The backwashing water distribution line L21 is provided with a connecting portion J21, a valve V21, a backwashing water pressurizing pump P21, and a backwashing water injection nozzle 6 in this order.

  Various valves and pumps are provided at various points in the line. Specifically, a pumping pump P1 is provided upstream of the connecting portion J1 in the treated water introduction line L1. The pumping pump P1 pumps up the treated water W1 (mainly seawater) from one end of the treated water introduction line L1. A valve V1 is provided between the pumping pump P1 and the connection portion J1 in the treated water introduction line L1. The treated water discharge line L2 is provided with a valve V2.

  A valve V11 is provided between the treated water outlet 26 and the ultraviolet reactor 61 in the treated water line L11 (specifically, between the connecting portion J21 and the connecting portion J11). A valve V12 is provided between the ultraviolet reactor 61 and the ballast tank 62 in the treated water line L11. The stored treated water discharge line L12 is provided with a valve V13 and a stored treated water discharge pump P11.

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

  Next, the detail of the ballast water filtration apparatus 2 is demonstrated. The casing 51 is formed in a cylindrical shape having an upper opening and a lower opening. The upper opening is sealed with the lid 10 and the lower opening is sealed with the bottom 11. An air vent line L31 is connected to the lid portion 10. The air vent line L31 is provided with an air vent valve V31 for venting air inside the casing 51.

  The filter 52 has an upper opening and a lower opening, and is formed in a cylindrical shape as a whole. Details of the filter 52 will be described later. A treated water outflow space 27 is formed between the casing 51 and the filter 52. The upper opening is sealed with an upper closing portion 13. The lower opening is sealed with a lower closing portion 14 and a lower rotating shaft member 16 described later.

  The filter rotating means 3 includes an upper rotating shaft member 15, a lower rotating shaft member 16, and a motor 17 that rotates the upper rotating shaft member 15. The upper rotary shaft member 15 is provided on the upper closing portion 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 on the lower closing portion 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 rotary shaft member 15 is rotatably and liquid-tightly supported by the lid portion 10 through a bearing member 18 that passes through and is sealed through the lid portion 10 of the casing 51. The lower rotary shaft member 16 is rotatably and liquid-tightly supported on the bottom portion 11 through a bearing member 19 that passes through the bottom portion 11 of the casing 51 and is sealed. The lower rotary shaft member 16 is a tubular body that communicates with the inside of the filter 52, and protrudes from the bottom 11 of the casing 51 to the outside of the casing 51. The lower rotating shaft member 16 is connected to the treated water inlet 20 to the casing 51.

A treated water introduction line L1 is connected to the treated water introduction port 20. A treated water outlet 26 is provided on the side of the casing 51. A treated water line L11 is connected to the treated water outlet 26.
The treated water W1 that flows through the treated water introduction line L1 and introduced from the treated water introduction port 20 passes through the lower rotary shaft member 16 and enters the filter 52. The treated water W1 is filtered through the filter 52, enters the treated water outflow space 27 formed between the casing 51 and the filter 52, and flows out from the treated water outlet 26.

  The backwash sewage discharge means 5 includes a backwash sewage collecting pipe 28 as a backwash sewage line, a backwash sewage discharge pipe 29 as a backwash sewage line, and a valve V32. In the backwashing sewage collecting pipe 28, backwashing sewage W11 sucked by the suction nozzle 4 is gathered. The backwash wastewater discharge pipe 29 is connected to the lower end of the backwash wastewater collecting pipe 28 and discharges the backwash wastewater W11 to the outside. The valve V32 is provided in the backwash wastewater discharge pipe 29.

  In the backwashing sewage collecting pipe 28, the upper end is closed and the lower end is opened. The backwashing sewage collecting pipe 28 is disposed at the axial center of the filter 52. The upper end portion of the backwash sewage collecting pipe 28 is fitted and supported in a hole provided in the center of the upper closing portion 13 of the filter 52. The lower end of the backwash sewage collecting pipe 28 is fixed to the treated water inlet 20 of the casing 51 through the inside of the lower rotary shaft member 16 of the lower closing portion 14 of the filter 52 so as not to prevent the rotation of the filter 52. Has been supported.

  The backwashing water supply means 7 pressurizes the filtered water W2 filtered by the filter 52 and supplies the filtered water W2 to the backwashing water jet nozzle 6 as backwashing water W2. The backwash water supply means 7 includes a backwash water pressurizing pump P21, a valve V21, and the like.

  The backwashing water injection nozzle 6 injects backwashing water W <b> 2 onto the outer peripheral surface (secondary side) of the filter 52, and peels off foreign matter accumulated on the primary side of the filter 52. Suction by the suction nozzle 4 is performed immediately after peeling. The foreign matter separated from the filter 52 by the backwash water W2 ejected from the backwash water jet nozzle 6 is effectively sucked by the suction nozzle 4 by opening the valve V32 provided in the backwash wastewater discharge pipe 29. . Since the pressure on the secondary side of the valve V32 is open to atmospheric pressure, the pressure inside the backwash sewage collecting pipe 28 is lower than the pressure on the secondary side of the filter 52 and is on the secondary side of the filter 52. A part of the filtered water W2 and the backwash water W2 sprayed from the backwash water jet nozzle 6 become the backwash wastewater W11 and circulate in the backwash wastewater collecting pipe 28, and from the backwash wastewater discharge pipe 29 to the outside. Is discharged.

  As the backwash water supplied to the backwash water jet nozzle 6, in this embodiment, filtered water W2 filtered by the filter 52 is used.

Next, the ultraviolet reactor 61 as an ultraviolet irradiation part is explained in full detail.
FIG. 2 is a cross-sectional view along the flow of the ballast water W2, showing the ultraviolet reactor 61 of the ballast water treatment apparatus 1 according to the first embodiment of the present invention. FIG. 3 is a cross-sectional view showing the ultraviolet reactor 61 of the ballast water treatment apparatus 1 according to the first embodiment of the present invention in a direction orthogonal to the flow of the ballast water W2.

The ultraviolet reactor 61 irradiates the ballast water W2 flowing through the ultraviolet reactor 61 with ultraviolet rays, and kills organisms and microorganisms in the ballast water W2. The ultraviolet reactor 61 includes a case 611, an ultraviolet lamp 612, a protective tube 613, a main body case 614, and an ultraviolet illuminance sensor 641.
The plurality of ultraviolet lamps 612 are provided in a case 611 through which ballast water is passed. Each ultraviolet lamp 612 is directly stored in a protective tube (quartz glass tube) 613 in a liquid-tight manner.

  The case 611 is provided with a main body case 614 through which the ballast water W2 is passed. The main body case 614 is formed of a cylindrical body having a substantially rectangular cross section, and both axial ends thereof are connected to L11.

  The protective tube 613 has an ultraviolet light transmission region on the peripheral surface, and is held between the left and right side plates 615 and 616 as shown in FIG. The number and arrangement of the protective tubes 613 (ultraviolet lamps 612) are appropriately set according to the processing capacity of the ballast water (W2, W3). In the present embodiment, as shown in FIG. 2, eight protective tubes 613 are arranged in a staggered manner.

Between the left and right side plates 615 and 616, the slide plate 617 through which the protective tube 613 penetrates is spaced apart from the left side plate 615 and the right side plate 616 between the left and right side plates 615 and 616 (FIG. 3). Left and right direction).
In the slide plate 617, a protective tube cleaning material 618 is provided in a through hole through which the protective tube 613 as a housing member passes. A case cleaning material 619 is provided on the outer periphery of the slide plate 617. In addition, an opening (not shown) is formed in the slide plate 617 so that the slide plate 617 can be moved left and right in a state where the ballast water (W2, W3) exists in the case 611.

  The protective tube cleaning material 618 and the case cleaning material 619 as cleaning members are configured by brushes, scrapers, or the like, and in the present embodiment, are configured by brushes (for example, brushes made of stainless steel wire). Specifically, the protective tube cleaning material 618 is provided in the through hole of the slide plate 617 so as to protrude inward of the through hole. The case cleaning material 619 is provided so as to protrude outward from the outer periphery of the slide plate 617.

  As the slide plate 617 moves, the protective tube cleaning material 618 moves while contacting the outer surface of the protective tube 613, and the case cleaning material 619 moves while contacting the inner surface of the main body case 614 of the case 611. Thereby, the organic substance adhering to the permeation | transmission area | region of the surrounding surface of the protective tube 613 and the inner surface of the main body case 614 is wiped off and cleaned.

  The ultraviolet illuminance sensor 641 is disposed in the flow path of the filtered treated water W2 inside the main body case 614. The ultraviolet illuminance sensor 641 measures the illuminance of ultraviolet light emitted from the ultraviolet lamp 612 and transmitted through the transmission region of the protective tube 613.

Next, main operations of the ballast water treatment apparatus 1 of the present embodiment will be briefly described.
(1) Filtration treatment of treated 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 pumping pump P1 is driven. Thereby, the to-be-processed water W1 which flowed in from the one end part of the to-be-processed water introduction line L1 distribute | circulates the to-be-processed water introduction line L1. The treated water W1 introduced from the treated water introduction port 20 is filtered by the filter 52 and discharged from the treated water outlet 26 as filtered treated water W2. The filtered treated water W2 flows through the treated water line L11, is subjected to ultraviolet treatment by the ultraviolet reactor 61, and is stored in the ballast tank 62 as stored treated water W3.

(2) Back washing treatment of the filter 52 by the back washing water jet nozzle 6 (back washing during the 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 so that the filtered treated water W2 (backwash water W2) flows toward the backwash water injection nozzle 6. And suction of backwash water pressurization pump P21 and suction nozzle 4 is operated in the state where ballast water (W2, W1) existed inside casing 51 and filter 52. Thereby, the backwash water (filtered water) W2 from the backwash water jet nozzle 6 is jetted toward the filter 52, and backwashing is performed.

(3) Waste water treatment of the stored treated water W3 from the ballast tank 62 to the outside The valve V12 and the valve V13 are opened, and the valve V11 is closed. In this state, the stored treated water discharge pump P11 provided in the stored treated water discharge line L12 is operated. Thereby, the stored treated water W3 stored in the ballast tank 62 is subjected to ultraviolet treatment by the ultraviolet reactor 61 and discharged to the outside via the treated water line L11 and the stored treated water discharge line L12.

Next, the operation of switching the supply destination (distribution destination) of the ballast water W2 when supplying the ballast water W2 to the ballast tank 62 will be described.
First, when an operator operates a ballast water supply start switch (not shown), the control unit 9 opens the valve V1, the valve V11, and the switching valve V121, and opens the valve V2, the valve V13, the valve V21, and the valve V31. Then, control is performed so as to close the valve V32, the switching valve V122, and the switching valve V123. In this state, the control unit 9 performs control to drive the pumping pump P1. Thus, the treated water W1 flowing from one end of the treated water introduction line L1 is filtered by the filter 52, flows through the treated water line L11 as filtered treated water W2, and is subjected to ultraviolet treatment by the ultraviolet reactor 61, and ballast It is supplied to the tank 621 as ballast water W2.

  When the water level detection means 42 detects that the water level of the ballast tank 621 has reached the first specific water level as a result of the supply of the ballast water W2 to the ballast tank 621, the control unit 9 notifies the notification device ( Control (not shown) is made to notify that effect. The operator recognizes that the water level of the ballast tank 621 has reached the first specific water level, and operates an operation switch for switching the distribution destination of the ballast water W2 from the ballast tank 621 to the ballast tank 622. . Then, a switching signal is output from the operation switch (not shown) to the control unit 9.

Based on the switching signal, the control unit 9 adjusts the pump P1 and the valves V1 and V11 to reduce the flow rate of the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61. Thereby, the resistance when the ballast water (filtered water) W2 flows into the ballast tank 62-1 that is almost filled with the ballast water (filtered water) W2 flows to the empty ballast tank 62-2. By switching the tip, it rapidly decreases, and it becomes possible to prevent a rapid change in the flow rate of the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61. Therefore, ballast water (filtered water) W2 having an appropriate flow rate flows into the ultraviolet reactor 61, and the ballast water (filtered water) W2 sufficiently irradiated with ultraviolet rays can flow into the ballast tank 622 by the ultraviolet reactor 61. It becomes a state.
The flow rate of the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61 may be adjusted by any one of the pump P1, the valve V1, and the valve V11. You may adjust in combination.

  In this state, the control unit 9 controls the switching valves V121 and V122 to close the switching valve V121 and open the switching valve V122. As a result, the supply of water (filtered water) W2 to the ballast tank 621 is stopped, and the ballast water (filtered water) W2 sufficiently irradiated with ultraviolet rays by the ultraviolet reactor 61 is supplied to the ballast tank 622. Start to be.

Next, the operation of switching the drainage source (distribution destination) of the ballast water W2 when draining the ballast water W2 from the ballast tank 62 will be described.
First, under the control of the control unit 9, the switching valve V121 and the valve V13 are opened, and the other valves (valve V11 and the like) are closed. In this state, the control unit 9 performs control to operate the stored treated water discharge pump P11 provided in the stored treated water discharge line L12. Thereby, the stored treated water W3 discharged from the ballast tank 621 is subjected to ultraviolet treatment by the ultraviolet reactor 61 and discharged to the outside via the treated water line L11 and the stored treated water discharge line L12.

  Next, when it is detected that the water level of the ballast tank 621 detected by the water level detection means 42 has reached the second specific water level, the control unit 9 controls the notification device (not shown) to The effect is notified. The operator recognizes that the water level of the ballast tank 621 has reached the second specific water level, and switches the discharge source (distribution destination) of the stored treated water W3 from the ballast tank 621 to the ballast tank 622. Operate the operation switch. Then, a switching signal is output from the operation switch to the control unit 9.

Based on the switching signal, the control unit 9 adjusts the stored treated water discharge pump P11 and the valve V13 to reduce the flow rate of the stored treated water W3 flowing through the ultraviolet reactor 61. As a result, the discharge source (distribution) from the ballast tank 62-1 in which the ballast water (filtered water) W2 is substantially empty to the ballast tank 62-2 in which the ballast water (filtered water) W2 is substantially filled. By switching the first), it is possible to prevent a rapid change in the flow rate of the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61. For this reason, the stored treated water W3 having an appropriate flow rate flows into the ultraviolet reactor 61, and the ultraviolet reactor 61 makes it possible to discharge the stored treated water W3 that has been sufficiently irradiated with ultraviolet rays from the ballast tank 622.
In addition, about the flow volume of the storage treated water W3 which distribute | circulates to the ultraviolet reactor 61, you may adjust by any one of the storage treated water discharge pump P11 and the valve | bulb V13, and you may adjust combining both. .

  In this state, the control unit 9 controls the switching valve V121 and the switching valve V122 to close the switching valve V121 and open the switching valve V122. As a result, the stored treated water W <b> 3 is stopped from being discharged from the ballast tank 621, starts being discharged from the ballast tank 622, and flows into the ultraviolet reactor 61. Then, the stored treated water W3 that has been sufficiently UV-irradiated by the ultraviolet reactor 61 is discharged to the outside through the treated water line L11 and the stored treated water discharge line L12.

Next, the operation of maintaining the output of the ultraviolet lamp 612 when the ultraviolet lamp 612 is cleaned by the protective tube cleaning material 618 will be described.
When the ultraviolet lamp 612 irradiates the ballast water (filtered treated water W2, stored treated water W3), the ultraviolet illuminance sensor 641 measures the illuminance of the ultraviolet light. The controller 9 detects the amount of ultraviolet rays from the ultraviolet lamp 612 so that the ultraviolet illuminance sensor 641 can obtain an appropriate illuminance with respect to the flow rates of the ballast water W2 and W3 flowing through the treated water line L11 detected by the flow meter 43. The controller 9 controls the output of the ultraviolet lamp 612 with respect to the ultraviolet lamp 612 so as to perform irradiation.

  Accordingly, when the control unit 9 determines that the illuminance detected by the ultraviolet illuminance sensor 641 is low with respect to the flow rate of the ballast water (the filtered treated water W2 and the stored treated water W3), the control unit 9 causes the ultraviolet lamp 612 to increase the illuminance. On the other hand, control for increasing the output of the ultraviolet lamp 612 is performed. Conversely, if the control unit 9 determines that the illuminance detected by the ultraviolet illuminance sensor 641 is higher than the flow rates of the ballast waters W2 and W3, the control unit 9 causes the ultraviolet lamp 612 to reduce the illuminance. Control to reduce the output.

  When a predetermined time elapses when the ultraviolet lamp 612 is irradiated with ultraviolet rays, the slide plate 617 starts to move under the control of the control unit 9 and the permeation region on the peripheral surface of the protective tube 613 of the ultraviolet lamp 612 is cleaned. . At this time, since the slide plate 617 moves between the ultraviolet lamp 612 and the ultraviolet illuminance sensor 641, part of the ultraviolet light from the ultraviolet lamp 612 is temporarily blocked by the protective tube cleaning material 618, and the ultraviolet illuminance sensor 641. The illuminance of the ultraviolet rays detected by this temporarily decreases. As a result, the control unit 9 determines that the illuminance has decreased and increases the output of the ultraviolet lamp 612. However, when the temporary ultraviolet block is eliminated, the control unit 9 determines that the illuminance has increased. Thus, the output of the ultraviolet lamp 612 is decreased. As a result, an unnecessary increase / decrease occurs in the output of the ultraviolet lamp 612, and there is a risk that the sterilization treatment with the ultraviolet rays for the ballast water (filtered water W2, stored water W3) may become unstable. Thus, while the slide plate 617 is moving, the control unit 9 maintains the output of the ultraviolet lamp 612 with respect to the ultraviolet lamp 612 regardless of the illuminance value detected by the ultraviolet illuminance sensor 641. Take control. The output maintained in this way is the same output as the one-minute output immediately before this maintenance is started.

According to the ballast water treatment device 1 of the first embodiment, for example, the following effects are provided.
The ballast water treatment apparatus 1 includes a filter 52 for filtering the ballast water W1 as the treated water to obtain filtered treated water W2, a treated water introduction line L1 through which the treated water W1 flows toward the filter 52, a filter The filtered treated water W2 filtered at 52 is selectively distributed toward the plurality of ballast tanks 62-1, 62-2, 62-3 storing the filtered treated water W2 as the stored treated water W3, or Based on the treated water line L11 through which the ballast water (reserved treated water W3) selectively discharged from the plurality of ballast tanks 62-1, 62-2, 62-3 circulates, and the switching signal, the ballast tank at the distribution destination Switching valves V121, V122, V123 as distribution destination switching means for switching 62, and an ultraviolet irradiation unit that irradiates the filtered treated water W2 and / or the stored treated water W3 with ultraviolet rays UV reactor 61, UV irradiation unit passage flow rate adjusting means (pump P 1, valves V 1, V 11) for adjusting the flow rates of ballast water W 2 and W 3 passing through UV reactor 61, and UV reactor 61 based on the switching signal And a control unit 9 as a flow rate control unit that controls the ultraviolet ray irradiation unit passing flow rate adjusting unit so as to reduce the flow rate of the ballast water W2 and W3 passing through the unit.

  Therefore, the control unit 9 can adjust the flow rates of the ballast waters W2 and W3 that pass through the ultraviolet reactor 61 based on the switching signal. For this reason, when the supply destination of the ballast water (filtered water) W2 is switched from the ballast tank 621 to the ballast tank 622, the flow rate of the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61 changes rapidly. Can be prevented. As a result, the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61 can be sufficiently irradiated with ultraviolet rays, and the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61 can be sufficiently sterilized. Can be done.

  Similarly, when the discharge source of the stored treated water W3 is switched from the ballast tank 621 to the ballast tank 622, it is possible to prevent the flow rate of the stored treated water W3 discharged from the ultraviolet reactor 61 from changing suddenly. it can. As a result, the stored treated water W3 flowing through the ultraviolet reactor 61 can be sufficiently irradiated with ultraviolet rays, and the stored treated water W3 flowing through the ultraviolet reactor 61 can be sufficiently sterilized.

  The ballast water treatment apparatus 1 further includes a switching operation unit that receives a switching operation of the switching valves V121, 122, and 123 serving as a distribution destination switching unit. The switching operation unit is configured to output a switching signal when a switching operation of the switching valves V121, 122, 123 is accepted.

  For this reason, when the distribution destination of the ballast water (filtered water) W2 is switched from the ballast tank 621 to the ballast tank 622 by the operator operating the changeover switch, it is automatically distributed to the ultraviolet reactor 61. Rapid changes in the flow rates of the ballast water (filtered water) W2 and the stored treated water W3 are prevented.

  The ultraviolet reactor 61 as an ultraviolet irradiation unit includes an ultraviolet lamp 612, a protective tube 613 that directly accommodates the ultraviolet lamp 612 and has a transmission region through which ultraviolet rays from the ultraviolet lamp 612 are transmitted, And a protective tube cleaning material 618 as a cleaning member that moves while contacting the tube 613 and cleans the permeation region of the protective tube 613. The ballast water treatment apparatus 1 includes an ultraviolet illuminance sensor 641 that measures the illuminance of ultraviolet light emitted from the ultraviolet lamp 612 and transmitted through the transmission region, and a timing at which the protective tube cleaning material 618 blocks the transmission region. And a control unit 9 as irradiation unit control means for controlling the ultraviolet lamp 612 so as to maintain the output.

  Therefore, when the control unit 9 controls the output of the ultraviolet lamp 612 based on the illuminance value detected by the ultraviolet illuminance sensor 641 as in the prior art, the slide plate 617 includes the ultraviolet lamp 612 and the ultraviolet illuminance. By moving between the sensors 641, the illuminance detected by the ultraviolet illuminance sensor 641 is reduced and the output of the ultraviolet lamp 612 is increased, and when the movement of the slide plate 617 is completed, the ultraviolet illuminance is reached. Control is performed to increase the illuminance detected by the sensor 641 and reduce the output of the ultraviolet lamp 612, and the irradiation of ultraviolet rays by the ultraviolet lamp 612 is stable with respect to the ballast water (filtered water) W2 and the stored treated water W3. May not be done. The present embodiment can solve such problems and can stably irradiate the ballast water (filtered water) W2 and the stored treated water W3 with ultraviolet rays.

[Second Embodiment]
Next, a second embodiment of the present invention will be described with reference to FIGS.
FIG. 4 is a flowchart showing control of supply of the ballast water W2 to the ballast tank 62 in the control unit 9 of the ballast water treatment apparatus 1 according to the second embodiment of the present invention. FIG. 5 is a flowchart showing control of discharge of the ballast water W3 from the ballast tank 62 in the control unit 9 of the ballast water treatment apparatus 1 according to the second embodiment of the present invention.

  In the second embodiment, differences from the first embodiment will be mainly described. For this reason, the same code | symbol is attached | subjected about the same (or equivalent) structure as 1st Embodiment, and detailed description is abbreviate | omitted. The description of the first embodiment is appropriately applied to points that are not particularly described in the second embodiment.

In the first embodiment, an operation switch (not shown) is operated by an operator, so that a switching signal is output to the control unit 9. On the other hand, in the second embodiment, the first specific water level and the second specific water level by the water level detection means 42 of the ballast tank 62 are based on the storage amount of the stored treated water W3 in the ballast tank 62. Based on the detection of the water level, the water level detection means 42 outputs a switching signal to the control unit 9.
In the second embodiment, the same effect as that of the first embodiment is achieved.

The operation of switching the supply destination (distribution destination) of the ballast water W2 when supplying the ballast water W2 to the ballast tank 62 will be described with reference to FIG.
First, as described above, when filtration of the treated water W1 (ballast water treatment operation) by the ballast water filtration device 2 is started by an operation by an operator, in step S11, the flow rate control process by the control unit 9 is performed. Be started. And the process by the control part 9 progresses to step S12.

  In step S12, the control unit 9 performs control to open the valve V1, the valve V11, and the switching valve V121 and close the valve V2, the valve V13, the valve V21, the valve V31, and the valve V32. In this state, the control unit 9 performs control to drive the pumping pump P1. Thus, the treated water W1 flowing from one end of the treated water introduction line L1 is filtered by the filter 52, flows through the treated water line L11 as filtered treated water W2, and is subjected to ultraviolet treatment by the ultraviolet reactor 61, and ballast It is supplied to the tank 621 as the stored treated water W3. And the process by the control part 9 progresses to step S13.

  Next, in step S13, the control unit 9 determines whether or not it has been detected that the water level of the ballast tank 621 detected by the water level detection means 42 has reached the first specific water level. When the control unit 9 determines that the water level of the ballast tank 621 has reached the first specific water level (YES), the process by the control unit 9 proceeds to step S14. If the control unit 9 determines that the water level of the ballast tank 621 has not reached a specific water level (NO), the processing by the control unit 9 returns to step S12.

  Next, in step S <b> 14, the water level detection means 42 outputs a switching signal to the control unit 9. And the process by the control part 9 progresses to step S15.

Next, in step S15, the control unit 9 adjusts the pump P1, valves V1, and V11 based on the switching signal, and performs control to reduce the flow rate of the ballast water (filtered water) W2 supplied to the ultraviolet reactor 61. Do. Thereby, the resistance when the ballast water (filtered water) W2 flows into the ballast tank 62-1 that is almost filled with the ballast water (filtered water) W2 flows to the empty ballast tank 62-2. By switching the tip, it rapidly decreases, and it becomes possible to prevent a rapid change in the flow rate of the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61. Therefore, ballast water (filtered water) W2 having an appropriate flow rate flows into the ultraviolet reactor 61, and the ballast water (filtered water) W2 sufficiently irradiated with ultraviolet rays can flow into the ballast tank 622 by the ultraviolet reactor 61. It becomes a state. And the process by the control part 9 progresses to step S16.
The flow rate of the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61 may be adjusted by any one of the pump P1, the valve V1, and the valve V11. You may adjust in combination.

  Next, in step S <b> 16, the controller 9 controls the switching valves V <b> 121 and V <b> 122 to close the switching valve V <b> 121 and open the switching valve V <b> 122. Thereby, the supply of the ballast water (filtered water) W2 to the ballast tank 621 is stopped, and the ballast water (filtered water) W2 sufficiently irradiated with ultraviolet rays by the ultraviolet reactor 61 is supplied to the ballast tank 622. Start to be supplied.

Next, the operation of switching the drainage source (distribution destination) of the ballast water W2 when draining the ballast water W2 from the ballast tank 62 will be described with reference to FIG.
First, as described above, when the drainage treatment of the stored treated water W3 by the ballast water filtration device 2 is started by the operation by the operator, the flow rate control processing by the control unit 9 is started in Step S21. And the process by the control part 9 progresses to step S22.

  In step S22, the valves V12 and V13 are opened and the other valves (valve V11 and the like) are closed under the control of the control unit 9. In this state, the control unit 9 performs control to operate the stored treated water discharge pump P11 provided in the stored treated water discharge line L12. Thereby, the stored treated water W3 discharged from the ballast tank 621 is subjected to ultraviolet treatment by the ultraviolet reactor 61 and discharged to the outside via the treated water line L11 and the stored treated water discharge line L12. And the process by the control part 9 progresses to step S23.

  In step S23, the control unit 9 determines whether or not it has been detected that the water level of the ballast tank 621 detected by the water level detecting means 42 has reached the second specific water level. When the control unit 9 determines that the water level of the ballast tank 621 has reached the second specific water level (YES), the processing by the control unit 9 proceeds to step S24. When the control unit 9 determines that the water level of the ballast tank 621 has not reached the second specific water level (NO), the process by the control unit 9 returns to step S22.

  Next, in step S <b> 24, the water level detection means 42 outputs a switching signal to the control unit 9. And the process by the control part 9 progresses to step S15.

Next, in step S <b> 25, the control unit 9 adjusts the stored treated water discharge pump P <b> 11 and the valve V <b> 13 based on the switching signal, and decreases the flow rate of the stored treated water W <b> 3 flowing through the ultraviolet reactor 61. As a result, the discharge source (distribution) from the ballast tank 62-1 in which the ballast water (filtered water) W2 is substantially empty to the ballast tank 62-2 in which the ballast water (filtered water) W2 is substantially filled. By switching the first), it is possible to prevent a rapid change in the flow rate of the ballast water (filtered water) W2 flowing through the ultraviolet reactor 61. For this reason, the stored treated water W3 having an appropriate flow rate flows into the ultraviolet reactor 61, and the ultraviolet reactor 61 makes it possible to discharge the stored treated water W3 that has been sufficiently irradiated with ultraviolet rays from the ballast tank 622. And the process by the control part 9 progresses to step S26.
In addition, about the flow volume of the storage treated water W3 which distribute | circulates to the ultraviolet reactor 61, you may adjust by any one of the storage treated water discharge pump P11 and the valve | bulb V13, and you may adjust combining both. .

  Next, in step S26, the control unit 9 performs control for the switching valves V121 and V122 to close the switching valve V121 and open the switching valve V122. As a result, the stored treated water W <b> 3 is stopped from being discharged from the ballast tank 621, starts being discharged from the ballast tank 622, and flows into the ultraviolet reactor 61. Then, the stored treated water W3 that has been sufficiently UV-irradiated by the ultraviolet reactor 61 is discharged to the outside through the treated water line L11 and the stored treated water discharge line L12.

The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and can be implemented in various forms.
For example, in this embodiment, while the slide plate 617 is moving, the control unit 9 outputs the ultraviolet lamp 612 to the ultraviolet lamp 612 regardless of the illuminance value detected by the ultraviolet illuminance sensor 641. However, the present invention is not limited to this control. For example, while the slide plate 617 is moving, the control unit 9 increases the output of the ultraviolet lamp 612 to the maximum regardless of the illuminance value detected by the ultraviolet illuminance sensor 641. Control may be performed as follows.

  Further, in the present embodiment, each ultraviolet lamp 612 is directly liquid-tightly accommodated in the protective tube 613, but is not limited to this configuration. For example, each ultraviolet lamp 612 may be indirectly stored in a storage container. Moreover, the structure of each part of a ballast water treatment apparatus is not limited to the structure of each part of the ballast water treatment apparatus 1 in this embodiment. For example, the number of ballast tanks is not limited to the number of ballast tanks 62 in the present embodiment.

1 Ballast Water Treatment Device 9 Control Unit (Flow Control Unit, Irradiation Unit Control Unit)
42 Water level detection means (storage amount measurement means)
52 Filter 61 UV reactor (UV irradiation unit)
62 Ballast tank 612 UV lamp 613 Protective tube (accommodating member)
618 Protective tube cleaning material (cleaning member)
641 UV illuminance sensor L1 treated water introduction line L11 treated water line V1, V11 valve (ultraviolet irradiation part passage flow rate adjusting means)
V121, V122, V123 switching valve (distribution destination switching means)
W1 treated water W2 filtered treated water W3 stored treated water

Claims (4)

A filter for obtaining filtered water by filtering ballast water as water to be treated;
A treated water introduction line through which the treated water circulates toward the filter,
The filtered water filtered by the filter selectively circulates toward a plurality of ballast tanks that store the filtered treated water as a stored treated water, or is selectively discharged from the plurality of ballast tanks. A treated water line through which water flows,
Distribution destination switching means for switching the ballast tank of the distribution destination based on the switching signal;
An ultraviolet irradiation unit that irradiates the filtered treated water and / or the stored treated water with ultraviolet rays;
Ultraviolet irradiation unit passage flow rate adjusting means for adjusting the flow rate of water passing through the ultraviolet irradiation unit,
A ballast water treatment apparatus comprising: a flow rate control unit that controls the ultraviolet ray irradiation unit passage flow rate adjusting unit so as to reduce the flow rate of water passing through the ultraviolet ray irradiation unit based on the switching signal. A switching operation section for receiving a switching operation of the distribution destination switching means;
The switching operation unit is configured to output the switching signal when receiving a switching operation of the distribution destination switching unit.
The ballast water treatment apparatus according to claim 1. A storage amount measuring means for measuring the storage amount of the stored treated water;
The storage amount measuring means is configured to output the switching signal based on the storage amount of the stored treated water measured by the storage amount measuring means.
The ballast water treatment apparatus according to claim 1. The ultraviolet irradiating unit moves while contacting the housing member, a housing member having a UV lamp, a housing member that houses the UV lamp directly or indirectly, and that transmits a UV light from the UV lamp. And a cleaning member for cleaning the transmission region of the housing member.
Ballast water treatment equipment
An ultraviolet illuminance sensor that measures the illuminance of ultraviolet light emitted from the ultraviolet lamp and transmitted through the transmission region;
Irradiation unit control means for controlling the ultraviolet irradiation unit to maintain or increase the output of the ultraviolet lamp based on the timing when the cleaning member blocks the transmission region,
The ballast water treatment apparatus according to any one of claims 1 to 3.

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