JP2018095080A - Ballast water treatment apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ballast water treatment apparatus capable of performing appropriate ultraviolet treatment according to a navigating water area.SOLUTION: The ballast water treatment apparatus comprises: ultraviolet treatment means (3); electrical conductivity measuring means (6) for measuring the electrical conductivity of ballast water; and control means (5) for controlling the output of the ultraviolet treatment means (3) according to the electrical conductivity of the ballast water measured by the electrical conductivity measuring means (6). The control means (5) controls such that the output of the ultraviolet treatment means (3) regards as a first output value (P1) when the electrical conductivity of the ballast water is greater than or equal to a specified threshold value, and the output of the ultraviolet treatment means (3) regards as a second output value (P2) higher than the first output value (P1) when the electrical conductivity of the ballast water is below the specified threshold value.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a ballast water treatment apparatus provided with ultraviolet treatment means.

  A ship such as a tanker usually stores water called ballast water in a ballast tank in order to balance the ship in operation when navigating to a destination again after unloading crude oil or the like. 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 at a loading port in a different water area from the cargo port, microorganisms in another water area will be released to that port, which may destroy the ecosystem in that water area.

  Therefore, a ballast water treatment apparatus is used to reduce the content of microorganisms contained in the ballast water. For example, the ballast water treatment apparatus described in Patent Document 1 includes ultraviolet treatment means for irradiating ballast water with ultraviolet rays to kill microorganisms (sterilization treatment).

JP 2006-248510 A

  By the way, among the microorganisms to be killed, many microorganisms inhabiting freshwater bodies are more resistant to ultraviolet rays than microorganisms inhabiting seawater areas. Therefore, in a ship that may sail in a freshwater area, if the output of the ultraviolet ray processing means is the same as that in the seawater area, the killing process may be incomplete. In order to prevent this, if a high-power ultraviolet treatment means suitable for microorganisms that live in freshwater bodies is introduced, there is a problem that energy loss occurs in seawater and brackish waterways where navigation is frequently performed.

  This invention is made | formed in view of such a situation, and it aims at providing the ballast water treatment apparatus which can perform an ultraviolet-ray process suitable according to the water area to sail.

  According to the present invention, there is provided a ballast water treatment apparatus including an ultraviolet treatment means, the electrical conductivity measurement means for measuring the electrical conductivity of the ballast water, and the electricity of the ballast water measured by the electrical conductivity measurement means. Control means for controlling the output of the ultraviolet treatment means according to the conductivity, and the control means outputs the output of the ultraviolet treatment means as a first value when the electrical conductivity of the ballast water is equal to or higher than a predetermined threshold value. And when the electric conductivity of the ballast water falls below a predetermined threshold value, the output of the ultraviolet ray processing means is controlled to be a second output value higher than the first output value. A processing device is provided.

  According to such a configuration, when the electrical conductivity measured by the electrical conductivity measuring unit falls below a predetermined threshold, it is determined that the water is a fresh water area, and the output of the ultraviolet ray processing unit is set to be higher than the first output value. By maintaining the high second output value, it is possible to completely perform the killing process even in the fresh water area without causing an energy loss in the sea water or the brackish water area.

  Hereinafter, various embodiments of the present invention will be exemplified. The following embodiments can be combined with each other.

  Preferably, the predetermined threshold value of the electrical conductivity is set to a value in the range of 3 S / m or less.

  Further, according to the present invention, in the ballast water treatment method of irradiating ultraviolet rays by the ultraviolet treatment means, when the electric conductivity of the ballast water is not less than a predetermined threshold, the output of the ultraviolet treatment means is the first output. When the electric conductivity of the ballast water is less than a predetermined threshold value, a ballast water treatment method is provided in which the output of the ultraviolet treatment means is set to a second output value higher than the first output value. .

It is a figure which shows the outline of the ballast water treatment apparatus which concerns on embodiment of this invention. 2 is a graph showing the relationship between the electrical conductivity of ballast water and the lamp output controlled by the control means in the ballast water treatment apparatus of FIG. 1. It is a graph which shows the relationship between the electrical conductivity of a ballast water controlled by a control means, and a lamp output in the ballast water treatment apparatus which concerns on the modification of this invention.

  DESCRIPTION OF EMBODIMENTS Embodiments of a ballast water treatment apparatus according to the present invention will be described below with reference to the drawings. Various characteristic items shown in the following embodiments can be combined with each other. The invention is established independently for each feature.

<Configuration of ballast water treatment device>
FIG. 1 is a schematic diagram illustrating a configuration of a ballast water treatment apparatus according to the present embodiment. As shown in FIG. 1, the ballast water treatment apparatus of this embodiment includes a pump 1 that takes inboard water such as seawater from the sea chest SC into the ship and pumps it as ballast water, and includes a filter for filtering the ballast water. Each of a ballast water filtration device 2, a UV reactor 3 as an ultraviolet treatment means for sterilizing microorganisms by irradiating the ballast water with ultraviolet rays by an ultraviolet lamp, a ballast tank 4 for storing ballast water, and a ballast water treatment device The control means 5 which controls a process, and the electrical conductivity measurement means 6 which measures the electrical conductivity (it is also called electrical conductivity) of ballast water are provided.

  In this specification, “ballast water” is introduced (inflow) into the ballast water filtration device 2 before being introduced (inflow) into the ballast tank 4 or after being discharged (outflow) from the ballast tank 4. ) Before or after being discharged (outflow) from the ballast water filtration device 2, and further before being introduced (inflow) into the UV reactor 3 or after being discharged (outflow) from the UV reactor 3, All the water taken into the ship is expressed as “ballast water”, which includes seawater, fresh water, brackish water, and the like.

  Moreover, the ballast water treatment apparatus according to the present embodiment includes a plurality of lines L1 to L8 that circulate the respective components. The “line” is a general term for lines formed by piping and capable of flowing fluid such as flow paths, paths, and pipelines.

  Specifically, as shown in FIG. 1, the line L1 is a line connecting the sea chest SC and the pump 1, and includes an on-off valve V1. The line L2 is a line connecting the pump 1 and the ballast water filtration device 2, and the line L3 is a line connecting the ballast water filtration device 2 and the ultraviolet reactor 3. The line L4 is a line connecting the ultraviolet reactor 3 and the outboard discharge port DP for discharging the ballast water to the outside of the ship, and has the electrical conductivity measuring means 6 and the on-off valve V2 in this order from the upstream side. Note that the lines L1 to L4 are also called a main pipe connecting the sea chest SC and the outboard discharge port DP together. In this embodiment, the electrical conductivity measuring means 6 is provided on the line L4, but may be provided at any position in the main pipe.

  Next, the line L5 is a line that has one end connected to the line L2 and the other end connected to the line L3 to bypass the ballast water filtration device 2, and includes an on-off valve V3. The line L6 has one end connected to the line L4 at a position between the ultraviolet reactor 3 and the on-off valve V2, and the other end connected to the ballast tank 4 to connect the ultraviolet reactor 3 and the ballast tank 4, It has a valve V4. The line L7 has one end connected to the line L6 at a position between the on-off valve V4 and the ballast tank 4, and the other end connected to the line L1 at a position between the on-off valve V1 and the pump 1. And a line connecting the pump 1 and having an on-off valve V5.

  Moreover, in this embodiment, the ballast water filtration apparatus 2 is provided with a filter cleaning means (not shown) for cleaning the filter during the filtration process, and discharges the cleaning sewage discharged by the filter cleaning means to the outside of the ship. The line L8 to be connected is connected. The line L8 is provided with an on-off valve V6.

  The controller 5 controls the opening and closing of the pump 1 and the above-described on-off valves V1 to V6, thereby controlling the flooding (ballast operation) of the ballast water to the ballast tank 4 and the drainage (deballasting) from the ballast tank 4. Operation) Control. The control means 5 also controls the flow rate of the ballast water and the output control of the ultraviolet reactor 3.

<Operation of ballast water treatment device>
Next, operation | movement of the ballast water treatment apparatus of this embodiment comprised as mentioned above is demonstrated.

  First, during the ballast operation, the control means 5 opens the on-off valves V1, V4, V6, closes the on-off valves V2, V3, V5, starts the pump 1, and energizes the ultraviolet lamp 30. When the pump 1 is started, water outside the ship (seawater or the like) is taken from the sea chest SC and is passed through the lines L1 and L2 to the ballast water filtration device 2. The ballast water passed through the ballast water filtering device 2 is filtered by the filter and then flows to the ultraviolet reactor 3 through the line L3. Here, a part of the ballast water that has flowed into the ballast water filtration device 2 by the filter washing means of the ballast water filtration device 2 described above is discharged outside the ship through the line L8 as sewage for filter washing. The ballast water passing through the ultraviolet reactor 3 is irradiated with ultraviolet rays by an ultraviolet lamp 30 and sterilized. The sterilized ballast water passes through a part of the line L4 and the line L6 and is sent to the ballast tank 4.

  On the other hand, during the deballasting operation, the on-off valves V5, V3, V2 are opened, the on-off valves V1, V4, V6 are closed, the pump 1 is started, and the ultraviolet lamp 30 is energized. When the pump 1 is started, the water in the ballast tank 4 flows to the ultraviolet reactor 3 through the line L7, part of the line L1, part of the line L5, part of the line L3, and then through the line L4 to the outboard discharge port. It is discharged from the DP to the outside of the ship. The ballast water in the ballast tank 4 discharged out of the ship does not pass through the ballast water filtration device 2 and is bypassed by the line L5. The ballast water in the ballast tank 4 has already been filtered once during the above-described ballast treatment. It is because it is going.

  In addition, after the remaining amount of ballast water in the ballast tank 4 decreases, the on-off valve V1 is opened so that the pump 1 does not cause cavitation, and the ballast water in the ballast tank 4 is discharged together with the water taken from outside the ship. It is preferable to drain. In this case, the on-off valve V3 may be closed, the on-off valve V6 may be opened, and drainage may be performed after performing the filtration process by the ballast water filtration device 2.

  Moreover, in this embodiment, the output (electric power) P of the ultraviolet lamp 30 during the ballast operation and the deballast operation is controlled by the control means 5 according to the electric conductivity σ of the ballast water to be processed. Specifically, the control means 5 sets the output P of the ultraviolet lamp 30 to the first output value P1 when the electric conductivity σ is high, and outputs the output of the ultraviolet lamp 30 when the electric conductivity σ falls below a predetermined threshold σ1. Is controlled to be a second output value P2 higher than the first output value P1. Here, it is preferable that the threshold σ1 of the electrical conductivity σ1 with the output value as the second output value P2 is 3.0 S / m (Siemens / meter) or less. More preferably, it is 1.5 S / m or less. More preferably, it is 1 S / m or less. More preferably, it is 0.4 S / m-0.8 S / m. Specifically, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1 .5, 1.6, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.4, 2.5, 2.6, 2.7 2.8, 2.9, 3.0 S / m, and may be within a range between any two of the numerical values exemplified here.

  The threshold value σ1 of the electrical conductivity σ is a threshold value for determining whether the ballast water to be processed (that is, the water area during navigation) is seawater, brackish water, or fresh water. In other words, the control means 5 determines the output P of the ultraviolet lamp 30 if the ballast water is seawater or brackish water based on the knowledge that microorganisms that inhabit freshwater bodies are more resistant to ultraviolet rays than microorganisms that inhabit seawater or freshwater areas. If the ballast water is fresh water, the output P of the ultraviolet lamp 30 is controlled to be the second output value P2 higher than the first output value P1.

  In the present application, the control means 5 of the ballast water treatment apparatus controls the ultraviolet lamp 30 in this way, so that when the ship navigates the seawater or brackish water area, the ultraviolet lamp 30 outputs the first low output. By setting the output value P1 (a constant value) to a value, it is possible to prevent loss of energy (electric power) more than necessary. On the other hand, when the ship is navigating fresh water, the ultraviolet lamp 30 is set to a second output that has a high output. By using the output value P2, it is possible to surely perform the killing process even if the microorganisms are more resistant to ultraviolet rays than those inhabiting seawater.

  The above-mentioned “binary control” refers to a substantially constant first output value P1 corresponding to seawater / brackish water and a substantially constant second output corresponding to freshwater according to the electrical conductivity σ. This indicates control for selecting one of the two output values of the value P2. However, within the scope of the present invention, as shown in FIG. 3 (a), the output P of the ultraviolet lamp 30 continuously changes in the vicinity of the threshold value σ1 of the electrical conductivity σ, or as shown in FIG. 3 (b). In addition, it is assumed that the output P of the ultraviolet lamp 30 corresponding to the electrical conductivity σ is not a constant value of the first output value P1 or the second output value P2. That is, in the present invention, as shown in FIG. 3, the electric conductivity σ is divided into three regions: a seawater / brine water region Rh with high conductivity, a freshwater region Rl with low conductivity, and a transition region Rt in the vicinity of the threshold σ1. It can be said that the lamp output P is controlled to change rapidly in the transition region Rt. Further, more generally, in the present invention, the average change rate of the lamp output P with respect to the electrical conductivity σ in the transition region Rt is larger than the average change rate of the lamp output P in the seawater / brackish water region Rh and the freshwater region Rl. It can be said that it is characterized by being controlled. The average change rate of the lamp output P in the transition region Rt is preferably at least twice the average change rate of the lamp output P in the seawater / brackish water region Rh and the freshwater region Rl, 5 times, 10 times, It may be more than that.

<Modification>
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. In particular, a part of the order related to the upstream and downstream sides of the on-off valve and the pump may be changed within the equivalent range of the invention, or a new line, on-off valve, pump, and the like may be added.

  In the above-described embodiment, the ballast water treatment apparatus is provided with the ballast water filtration apparatus 2, but may include only the ultraviolet reactor 3 or another apparatus that purifies the ballast water.

  In the above-described embodiment, the output value of the ultraviolet lamp 30 is subjected to binary control using the electrical conductivity threshold σ1, but when the electrical conductivity σ of the ballast water is higher than σ1, It is also possible to perform multi-value control in which the output P of the ultraviolet lamp 30 is further changed in accordance with the conductivity σ and changed to three or more output values. However, since complex control is required by increasing the threshold value, it is more preferable to perform the above-described binary control as long as the eyes of the present application are achieved.

1: Pump 2: Ballast water filtration device 3: UV reactor (UV treatment means)
4: Ballast tank 5: Control means 6: Electrical conductivity measuring means 30: Ultraviolet lamp DP: Outboard discharge ports L1 to L8: Line P: Output P1 (of ultraviolet lamp) P1: First output value P2: Second Output value Rh: Seawater / brine water region Rl: Freshwater region Rt: Transition region SC: Sea chest V1-V6: Open / close valve σ: Electrical conductivity σ1: Threshold value

Claims (3)

A ballast water treatment apparatus provided with ultraviolet treatment means,
Electric conductivity measuring means for measuring the electric conductivity of the ballast water, and a control means for controlling the output of the ultraviolet treatment means according to the electric conductivity of the ballast water measured by the electric conductivity measuring means,
When the electrical conductivity of the ballast water is equal to or higher than a predetermined threshold, the control means uses the output of the ultraviolet ray processing means as a first output value, and the electrical conductivity of the ballast water falls below a predetermined threshold. A ballast water treatment apparatus that controls the output of the ultraviolet ray treatment means to be a second output value higher than the first output value.   The ballast water treatment apparatus according to claim 1, wherein the predetermined threshold value of the electrical conductivity is a value in a range of 3 S / m or less. A ballast water treatment method of irradiating ultraviolet rays with ultraviolet treatment means,
When the electric conductivity of the ballast water is equal to or higher than a predetermined threshold, the output of the ultraviolet ray processing means is set as a first output value. A ballast water treatment method, wherein the second output value is higher than the first output value.