JPH0568999A - Method and apparatus for suppressing propagation of plankton - Google Patents

Abstract

PURPOSE:To suppress the propagation of many kinds of planktons largely propagated in the surface layer part of a reservoir such as a dam. CONSTITUTION:A water sprinkler 1 and an operation ship 2 are connected by a water feed pipe 3. A pressure tank 5 having an ultraviolet irradiation device provided to the upper part thereof, a steering room 4 and a water sprinkler operation panel 6 are provided on the operation ship 2. An intake pipe 8 is provided in the vicinity of the bow of the operation ship 2 and the water containing plankton in a reservoir is taken in the pressure tank 5 from the intake pipe 8 by a pump 9. This water is held in the pressure tank 5 for a definite time in a pressurized state to be irradiated with ultraviolet rays. By this method, the propagation capacity of plankton is suppressed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for suppressing the growth of plankton which multiply in the surface layer of lakes and other predetermined water bodies.

[0002]

2. Description of the Related Art In a reservoir such as a dam that has been eutrophicated, when the water temperature rises and the amount of solar radiation increases from early summer to autumn, plankton proliferates actively in the surface layer of the luminous layer, A large number of plankton colonies such as cyanobacteria and green algae are generated. Such plankton deteriorates the appearance of the surface layer of the reservoir and deteriorates the environment of the reservoir, such as decreasing the hydrophilicity. In addition, it produces an off-flavor in tap water to deteriorate the quality of drinking water and causes problems such as clogging of water treatment equipment.

Therefore, conventionally, as a means for suppressing the growth of such plankton, a method has been adopted in which a chemical such as copper sulfate is sprayed on the water surface of the reservoir to chemically suppress the growth of the plankton. However, the plankton growth inhibiting method using such a chemical agent is not desirable because the chemical agent may remain in the reservoir and pollute the surrounding environment of the reservoir.

On the other hand, as a method for suppressing the growth of plankton without using any chemicals, a method of pumping low-temperature water from a deep-water layer and supplying it to the high-temperature surface layer and cooling it to blunt the activity of plankton ( JP-A-2-258
No. 095), a method of giving physical damage to a plankton group living body by taking out water containing plankton in the surface layer, pressurizing it, and then returning it to normal pressure (JP-A-3-862).
No. 89) is disclosed.

[0005]

However, in the method of extracting and pressurizing the water containing plankton described above,
The effect was different depending on the type of plankton. Compared with blue-green algae, the effect is remarkable in diatoms. Therefore, in a body of water containing many types of plankton,
There is a possibility that the method of suppressing the proliferation of plankton can be further enhanced by combining such a method using pressurization with another method.

The present invention is intended to more effectively suppress the growth of plankton, and an object of the present invention is to provide a method and an apparatus for effectively suppressing the growth of many types of plankton.

[0007]

In order to achieve the above object, the plankton growth inhibiting method of the present invention is directed to water containing plankton in a lake or other predetermined water area.
It is characterized by applying pressure and irradiating ultraviolet rays.
Further, the plankton growth inhibitor of the present invention is a water intake mechanism for taking in water containing plankton in a lake or other predetermined water area, a pressurizing device and an ultraviolet irradiation device for the water containing the introduced plankton, and after applying pressure and ultraviolet irradiation. And a drainage mechanism for discharging the above water to the water area.

[0008]

In the method according to the present invention, the irradiated ultraviolet light penetrates the cell membrane of plankton contained in water and enters the cell, which directly damages the deoxyribonucleic acid (DNA) which is the main body of the plankton gene. And suppress its proliferative capacity. Further, the plankton contained therein is physically damaged by the pressurization of the water containing plankton, which suppresses the growth ability of the plankton. As described above, this method suppresses the growth of plankton by the combined use of ultraviolet irradiation and pressurization.

In the apparatus according to the present invention, the water containing the plankton taken in from the water intake mechanism is pressurized by the pressurizing device, and the water is irradiated with ultraviolet rays by the ultraviolet ray irradiating device. As a result, the method according to the present invention is embodied to produce the above-mentioned effects, and suppress the plankton growth ability. Then, the water in which the increase in the number of plankton cells contained is suppressed is discharged to a predetermined water area by the drainage mechanism.

[0010]

EXAMPLES The present invention will be described in detail below with reference to examples. FIG. 1 is a schematic diagram showing an embodiment of the plankton growth inhibitor of the present invention. In this example, the water sprinkler 1 is used as the drainage mechanism in the present invention, and other configurations are used.
It is provided on an operation ship 2 connected to the water sprinkler 1 by a water supply pipe 3 and the like.

The water sprinkler 1 has a water spray nozzle 12 on a hull 11.
And a lighting device 13, and inside the hull 11, a pipe 14 connected to the water supply pipe 3 and a water distribution pipe 15 for distributing water to the water spray nozzle 12 from here. Hull 11 of this sprinkler 1
In addition to the water supply pipe 3, a wire rope 16 for towing is connected between the operation ship 2 and the operation ship 2, and, if necessary, further connected by a power cable and a control cable (not shown). Further, the water supply pipe 3 has a structure in which some flexible pipes are inserted in the middle part and suspended on the float 17, so that it is not subjected to excessive stress.

A steering room 4, a pressure tank 5, and a sprinkler operation panel 6 are provided on the operation boat 2, and in the pressure tank 5, an intake pipe 8 arranged near the bow of the operation boat 2 Water containing plankton in waters such as lakes is introduced by the pump 9. The operating ship 2 has a structure in which it can be moved by itself while towing the water sprinkler 1 in a water area such as a lake by a power unit and a steering device (not shown). In dam reservoirs, etc. that perform small hydroelectric power generation, necessary power can be transmitted from land without installing a power unit onboard.

The water intake pipe 8 has a bellows pipe 8a at its lower portion, and is structured so that its length can be adjusted by a winch (not shown) on the operation ship 2. Can take water.
Further, when the operation ship 2 is moved, the entire intake pipe 8 can be stored in the side of the operation ship 2. In addition, at the tip of the water intake pipe 8, a net 8 for preventing the intake of dust and the like is provided.
Wearing b.

The pump 9 is a centrifugal pump (or a positive displacement pump such as a plunger pump or a vane pump) having a known mechanism, and the discharge side of the pump 9 is connected to a water supply pipe 5a to the pressure tank 5. .. The pump 9 is for pumping the water in the water area from the water intake pipe 8 continuously or intermittently, pressurizing the water taken into the pump 9 and sending it into the pressure tank 5, and its discharge pressure is 0. It is set to be about 1 to 1.0 MPa.

The pressure tank 5 is for retaining the water introduced by the pump 9 at the pressure for a certain period of time, and the pressure tank 5 has a residence time of 5
It has a volume of about 30 seconds. An ultraviolet irradiation device 7 is provided above the pressure tank 5 to irradiate the water containing plankton, which remains in the pressure tank 5 under pressure, with ultraviolet rays.

This ultraviolet irradiation device 7 has a wavelength of 25.
A medium-pressure mercury lamp, which mainly emits ultraviolet rays of 0 to 260 nm, was used. Depending on the UV intensity of this lamp and the above-mentioned residence time, the irradiation dose is 10 to 150 mw · sec / cm ²
So that Then, the pipe 5b connected to the drainage port of the pressure tank 5 is connected to the water supply pipe 3, and the water after pressurization / ultraviolet irradiation is directed to the sprinkler 1.

FIG. 3 shows the results of an experiment in which the effect of suppressing the growth of plankton by irradiating water containing various plankton with ultraviolet rays is shown. The blue-green alga Microcystis aeruginosa and the green alga Pandrina morum, which cause the so-called flowering phenomenon of water, and the blue-green alga Phormidium tenue, which causes the off-flavor of the waterworks.
ue) and each culture solution of diatom Melosira (Melosira) are divided into a test section and a control section with the same number of cells, and the test section is irradiated with ultraviolet rays by the medium pressure mercury lamp. Then, the number of cells in each section was counted after leaving the other conditions the same for a certain period of time. And the number of cells in the control area is 1
The ratio of the number of cells in the test plot when 00 was calculated as the residual rate. If the value of this residual rate is low, it means that the irradiation of ultraviolet rays effectively suppressed the growth of plankton. FIG. 3 is a graph showing the residual rate at each ultraviolet irradiation amount.

As can be seen from this graph, in the blue-green algae Microcystis aeruginosa and Formidinium tenue, a remarkable effect was observed on the inhibition of plankton growth by UV irradiation. That is, in the case of Microcystis aeruginosa, the UV irradiation dose is 150 mw · sec / cm.
^The residual rate of ² is about 38%, which is about 62% compared to the control area.
As much as a% reduction in plankton can be seen. In the case of Formium tenue, the amount of UV irradiation is 85 mw · sec / cm
² , the residual rate is about 37%, UV irradiation dose 150mw · sec
/ Cm ² , the residual rate is about 20%, and the growth inhibition rates are about 63% and about 80%, respectively, compared to the control group. However, for Pandrina Morm and Melocira, 150 mw · se
The survival rate at a dose of c / cm ² was as high as 70 to 75%, and the growth inhibition rate was 25 to 30% compared to the control group.

On the other hand, FIG. 4 shows the results of an experiment in which the effect of suppressing the growth of plankton by pressurizing water containing plankton was investigated. Blue-green alga Microcystis aeruginosa,
Each of the culture solutions of the green alga Pandolina molm and the blue-green alga Formidinium tenue was divided into a test section and a control section in the same manner as in the above-mentioned experiment, and the culture solution of the test section was kept under each pressure for each time and then brought to normal pressure. After returning, the other conditions were kept the same for a certain period of time, the number of cells in each section was counted, and the survival rate was calculated in the same manner as in the above-mentioned experiment. Fig. 4 (a) shows the results of Microcystis aeruginosa, Fig. 4 (b) shows the results of Pandrina morphum, and Fig. 4 (c) shows the results of Formium tenue.

In the case of the pandolinomarum of FIG. 4 (b), 0.3
Pressurization with MPa for 5 seconds resulted in a residual rate of about 3% (that is, a growth inhibition rate of 97% compared to the control group), and a considerable effect was obtained. In Microcystis aeruginosa of Fig. 4 (a) and Formidien tenue of Fig. 4 (c),
Even after pressurizing with 0.5 MPa for 60 seconds, the residual rate was about 40% (that is, the growth inhibition rate as compared with the control group was about 60%).

As described above, the effect of the pressure treatment on the water containing plankton and the ultraviolet treatment differ depending on the type of plankton. Therefore, if the method of the present invention is used in combination with pressurization and ultraviolet irradiation, it can be expected to effectively suppress proliferation of many types of plankton. The operation boat 2 is steered to move to the water area where a large number of plankton are in clusters, the intake pipe 8 is removed from the vessel and put in water, and its length is adjusted by the winch so that the tip reaches an appropriate water depth. To do. Then, while the pump 9 is started and the ultraviolet irradiation device 7 is turned on to generate ultraviolet rays, this water area is slowly circulated while taking in water containing many plankton from the intake pipe 8.

The water taken in from the intake pipe 8 is pumped by the pump 9.
After entering the inside, it is pressurized to about 0.1 to 1.0 MPa and introduced into the pressure tank 5 through the pipe 5a.
Stay within 5 to 30 seconds. Here, plankton contained in water is physically damaged by pressurization and DNA is damaged by ultraviolet rays penetrating from the cell membrane, and its proliferation ability is suppressed.

The water discharged from the pressure tank 5 passes from the pipe 5b through the water pipe 3 to the pipe 14 inside the hull 11 on which the sprinkler 1 is mounted, and is distributed from the water pipe 15 to the fountain nozzle 13 and discharged from there. To be done. Here, the proliferative ability of plankton contained at the time of water intake is remarkably reduced as compared with the untreated one. In this example, since the water sprinkler 1 is applied as the drainage mechanism, the water spray forms a shade to cover a predetermined area, lower the temperature of the water surface, and reduce the solar radiation reaching the water surface. It also exerts the effect of suppressing the growth of plankton.

In this embodiment, the pressure tank 5 is provided and the water containing plankton is retained in the pressurized tank for a certain period of time. However, such a pressure tank 5 is not provided, but the downstream side of the pump 9 is provided. The pressure may be maintained in the pipe for a sufficient time. In that case, the ultraviolet irradiation device 7 is provided at a position where ultraviolet rays can be irradiated inside the pipe. Further, even when the pressure tank 5 is installed, a water passage for irradiating ultraviolet rays may be separately provided to pass water containing plankton to irradiate ultraviolet rays before and after pressurization. Further, the method of the present invention can be carried out by floating a raft-shaped hull 18 in which a UV irradiation device 7 as shown in FIG.

In this embodiment, the water sprinkler 1 is used as the drainage mechanism, but a drainage nozzle is provided at the stern and the drainage pipe 5b of the pressure tank 5 is connected to this to drain water toward the water surface. May be Further, in this embodiment, the water sprinkler 1 and the operation ship 2 are connected by the water supply pipe 3 or the like, but the devices installed on the operation ship 2 and the water sprayer operation panel 6
If the structure is a waterproof structure, the sprinkler 1 may be mounted on the operation ship 2. Furthermore, in this embodiment, the components of the present invention are placed on the hull and work is performed while moving in a predetermined water area. However, if the water area to be worked is a small-scale water tank, etc. The components may be arranged on land adjacent to this body of water without using the hull.

[0026]

As described above, according to the plankton growth suppression method of the present invention, the irradiation of ultraviolet rays and pressurization of water containing plankton suppresses the growth of various types of plankton in lakes and other predetermined water bodies. it can.
Further, this method is embodied by the plankton growth inhibitor of the present invention. As a result, it is possible to more effectively preserve the environment in lakes and other predetermined water areas.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing an embodiment of a plankton growth inhibitor of the present invention.

FIG. 2 shows a plankton growth suppression method of the present invention,
1 is a schematic diagram showing an apparatus that can be used to irradiate a predetermined water area with ultraviolet rays.

FIG. 3 is a graph showing the experimental results of investigating the plankton growth inhibitory effect of ultraviolet irradiation on water containing plankton.

FIG. 4 is a graph showing the experimental results for examining the plankton growth inhibitory effect of pressurization on water containing plankton.

[Explanation of symbols]

 1 Water sprinkler (drainage mechanism) 5 Pressure tank 7 Ultraviolet irradiation device 8 Water intake pipe 9 Pump (pressurizing device)

Front page continuation (72) Inventor Minaya Nakamura 1-6-27 Konan, Minato-ku, Tokyo Ebara Infiruco Ltd. (72) Inventor Hiroshi Taniuchi 6-6-7 Ginza, Chuo-ku, Tokyo Asahi Building Co., Ltd. Inside the EBARA CORPORATION

Claims (2)

[Claims] 1. A method for suppressing the growth of plankton, which comprises pressurizing and irradiating ultraviolet rays to water containing plankton in a lake or other predetermined water area. 2. A water intake mechanism for taking in plankton-containing water in a lake or other predetermined water area, a pressurizing device and an ultraviolet irradiation device for the taken-in plankton-containing water, and water after pressurization and ultraviolet irradiation is discharged to the water area. A plankton growth suppression device comprising: