KR20120100587A - Sampling device of ballast water for a ship - Google Patents

Abstract

PURPOSE: An apparatus for sampling water containing microorganisms is provided to detach microorganisms attached on the surface of the inside of a filter and to enable desired sampling. CONSTITUTION: An apparatus for sampling ballast water for a ship comprises: an inlet tube(12) of ballast water and an outlet tube(13) of filtered water at the bottom of the cover plate(1b) of a sampling tank(1); a filter(2) for filtering microorganisms in the ballast water; and a storage container for storing extracted water containing microorganisms at the lower side of the sampling tank.

Description

Sampling device of ballast water for ship

The present invention is installed by inserting a conical filter to filter the microorganisms contained in the ballast water into the sampling tank, the lower side of the sampling tank is installed a storage container for storing the extract water concentrated microorganisms through the filter, the filter By installing a washing nozzle for rinsing the filter outside the filter and installing an overflow tank of lower height than the filter between the sampling tank and the filter, it prevents the filter from clogging and rinsing the filter and based on the filter. It is possible to perform the extraction operation of the extract water more quickly and efficiently, and to completely block the flow back of the filtered water back to the inside of the filter by the ballast water that is excessively supplied to the sampling tank. The present invention relates to a sampling device for ballast water for ships.

In general, ballast water is installed on both sides of the bottom of the ship to prevent the ship from being unbalanced when the ship is operated when the ship is unloaded from the ship or when the amount of cargo loaded on the ship is very small. It refers to the buoyancy adjustment freshwater or seawater filled inside the ballast tank.

Such ballast water contains various microorganisms such as pathogenic bacteria and plankton contained in freshwater or seawater filled with ballast water. Therefore, if it is discharged into the water of another region without any treatment, serious marine pollution And the destruction of ecosystems.

Based on this situation, in 1996, in the United States, the national invasive species law was enacted, requiring the management and control of the ballast water by stipulating the exotic species as the intruder. In Australia, the quarantine law was amended to import the ballast water As well as direct quarantine.

On the other hand, the International Maritime Organization (IMO) concluded an international agreement in February 2004, and from 2009, the ship was required to install the necessary equipment for the sterilization and purification treatment of ballast water sequentially. In case of violation, Of the total number of vessels.

Accordingly, various techniques for treating ship ballast water have recently been developed, and a representative example thereof is sterilization and purification treatment of ballast water using ozone (O ₃ : 0 ₃ ). In addition, Ballast water purifiers have been developed or are under development.

The ballast water purification device mounted on the ship as described above, after receiving the certificate through the land test and the shipboard test in accordance with the International Maritime Organization (IMO) standards, and then the certificate is installed on the ship, the ballast water purification device In order to measure whether the ballast water treated in accordance with the above standards meets the emission standards prescribed by the International Maritime Organization, a sampling apparatus is used to collect the extract water for the sample enriched in microorganisms from the ballast water.

As a representative example of such a ballast water sampling device for ships, as described in Republic of Korea Patent Publication No. 2010-103487 (published: September 27, 2010), a conical filter for filtering microorganisms contained in the ballast water Is installed inside the sampling tank, and a sampling system provided with a storage container for storing the extract water in which the microorganisms are concentrated through a filter at the lower side of the sampling tank.

According to the conventional sampling system as described above, the microorganisms are trapped on the inner surface of the filter in the process of introducing and discharging the ballast water through the sampling tank, and thus by rinsing to wash off the microorganisms trapped on the inner surface of the filter. The extract water for the sample is stored in the storage container, and the above operation is repeated several times to obtain the required amount of extract water, and then the storage container is separated from the sampling tank to measure the distribution or population of microorganisms contained in the extract water. You can do it.

However, the conventional sampling system as described above, by using the ballast water inlet pipe provided in the upper portion of the filter to perform a rinsing operation to wash the microorganisms trapped in the inner surface of the filter to the storage container side, even in the process of rinsing operation Microorganisms are continuously attached to the inner surface of the filter, and thus, the rinsing operation of the filter is not smoothly performed, and there is a problem that the clogging of the filter occurs frequently.

In addition, during the course of the rinsing operation, the microorganisms attached to the inner surface of the filter may be present in the filtering hole due to the jetting pressure of the washing water, or may escape through the filtering hole. This results in a relatively large error in the measurement data such as the distribution of microorganisms and the number of individuals contained in the extracted water for the sample.

In particular, the microorganisms attached to the surface of the filter due to the injection pressure of the washing water may rub against the surface of the filter somewhat more strongly, and the probability of the microorganisms being killed in this process also increases, so that the microorganisms contained in the sample extract water are killed. There is a problem that it is unclear whether the microorganism is due to the ballast water purification device or the injection pressure of the washing water.

It is difficult to precisely determine whether the ballast water purifier installed on the ship operates at a level suitable to the emission standard or not through the measurement result of the extracted water for the sample so that the feedback control of the ballast water purifier There was a difficult problem.

Meanwhile, in the conventional sampling system, a drain pipe is applied to discharge the ballast water excessively supplied into the sampling tank to the outside, but the flow rate of the ballast water supplied into the sampling tank is discharged through the drain pipe. Since the flow rate is greater than that of the ballast water, the discharge of the filtered water by the drain pipe may not occur quickly and smoothly when the excess supply of the ballast water occurs, and a situation in which the filtered water flows back into the filter frequently occurs.

In other words, a relatively large difference occurs between the flow rate of the ballast water forced to the sampling tank by the pumping operation and the flow rate of the filtered water discharged to the outside of the sampling tank by the natural dropping method. Since no means can be provided, if the ballast water is excessively supplied into the sampling tank within a short time due to a malfunction of the device, the filtered water passing through the filter cannot be discharged normally to the outside of the sampling tank, and the filter is over the top of the filter. Will flow back into the interior.

As described above, when the filtered water from which the microorganisms have been removed through the filter flows back into the filter, the filtered water is mixed with the ballast water, resulting in dilution of the ballast water. By providing another error in the measurement data such as the distribution or the number of individuals, a problem occurs that greatly lowers the reliability of the measured data.

In addition, in the conventional sampling system, only a filter having a specific dimension or processing capacity may be limitedly applied in one sampling tank, and it is difficult to replace and use a filter having a different dimension or processing capacity as necessary. There was a problem in that the economic burden on the user because a plurality of sampling devices are required according to the size or processing capacity of the filter.

In addition, the conventional sampling system separates the storage container in which the sample extract water is stored from the sampling tank and transports the storage container to the laboratory equipped with the measuring equipment, and then distributes, populations, and kills of microorganisms contained in the sample extract water. By measuring in the laboratory, there was a problem in that unnecessary time and manpower was wasted in measuring the ballast water.

In particular, during the time that the sample extract is stored in the storage container through several iterations, the distribution or population of microorganisms contained in the extract cannot be measured in real time. Also, whether or not the killing of microorganisms generated at the same time can not be accurately determined, and thus, there is a problem of further lowering the reliability of the measured data based on the sample extract water.

In addition, if a conventional sampling system is used to obtain the required amount of sample water, and then a new sampling operation is to be performed again, a cleaning operation for removing the microorganisms remaining in the surface of the filter and the storage container may be performed. Although necessary, such a cleaning operation was not included in the sampling system, so it was cumbersome to remove the filter from the sampling tank and manually clean the inside of the sampling tank.

The present invention has been made to solve the above-mentioned conventional problems, the marine ballast water sampling device according to the present invention, by installing a washing nozzle for the rinsing operation of the filter on the outside of the filter, from the outside of the filter By spraying the washing water toward the inside of the filter, it is possible to prevent clogging of the filter and to perform the rinsing operation of the filter and the extraction of the extracted water based on the filter more quickly and efficiently. When the work is completed, the first technical task is to connect the supply line of steam or sterilizing water to the cleaning nozzle to enable the cleaning of the sampling tank.

In addition, the present invention is to install an overflow tank of a lower height than the filter between the sampling tank and the filter, so that the space between the sampling tank and the overflow tank is a buffer space to temporarily store the excess ballast water through the filter. By connecting the drain pipe to the bottom of the buffer space, it is possible to more completely block the flow back of the filtered water to the inside of the filter by the ballast water over-supplied to the sampling tank. It is a technical problem.

In addition, the present invention by installing a height adjusting device of the lifting and lowering screw type inside the sampling tank, and by providing a mounting structure of the filter and the washing nozzle to the height adjuster, by using a height adjuster having a filter having a variety of dimensions and processing capacity The third technical task is to replace and use it whenever necessary, thereby improving the compatibility and economical efficiency of the use of the sampling tank.

On the other hand, the present invention by installing a microorganism detector on the lower side of the storage container of the sample extract water, and by allowing the microorganism detector is connected to the detection monitor of the monitor room, the microorganism distribution of the extract water discharged to the storage container through the filter The fourth technical task is to enable accurate measurement in real time in the monitor room.

In addition, the present invention is to form the storage container in a conical container, while by installing the microorganism detector at the lower end of the conical storage container, to ensure the maximum detection range and detection performance by the microbial detector Therefore, the fifth technical problem is to make it possible to further improve the reliability of the data measured from the sample extract water.

The present invention as a means for solving the above technical problem, the cover plate and the bottom surface of the sampling tank is connected to the inlet pipe of the ballast water and the discharge pipe of the filtered water, respectively, and inside the sampling tank to filter the microorganisms in the ballast water A conical filter for inserting is inserted and installed, and a storage container for storing extract water containing microorganisms is installed at a lower side of the sampling tank, and the storage container is a lower collecting part of the filter by a water collection tube having an opening / closing valve. In the sampling apparatus of the ballast water for ships installed in connection with the plurality of sampling nozzles, a plurality of washing nozzles are installed between the sampling tank and the filter to face the outer surface of the filter at regular intervals, each washing nozzle is rinsed by a nozzle pipe Installed in connection with the pipe, the rinsing pipe passes through the bottom surface of the sampling tank It is characterized in that the extension is installed to the outside.

In addition, an overflow tank is inserted and installed between the sampling tank and the filter, and the washing nozzle, the nozzle pipe, and the rinsing pipe are installed to be positioned between the overflow tank and the filter, and the lower end of the overflow tank is a sampling tank. It is assembled with the bottom surface of the, the upper end of the overflow tank is located at a lower level than the filter, the discharge pipe of the filtered water is installed in connection with the bottom surface of the sampling tank at a position corresponding between the overflow tank and the filter, A drain pipe is connected to the bottom surface of the sampling tank corresponding to the sampling tank and the overflow tank, and the top surface of the overflow tank is characterized by being formed with a toothed portion.

In addition, the filter and the washing nozzle is installed in the interior of the sampling tank or the overflow tank with a height adjuster, the height adjuster, a plurality of nut rods fixed in the vertical direction to the bottom surface of the sampling tank, the nut rod Rod bolt inserted in the vertical direction along the nut rod and fastened to the assembly, a rotary knob provided on the upper end of the rod bolt, the upper end of the ring-shaped connected to the upper end of the rod bolt and mounted on the upper end of the filter And, the lower end of the pipe shape is connected to the lower end of the nut rod and the lower end of the filter is mounted, and is installed in a way that is suspended in the upper end and the nozzle frame for supporting the nozzle pipe of the cleaning nozzle, the rinse pipe It becomes a rinsing hose made of flexible material, and the water collection pipe passes through the lower collecting part to the lower end of the height adjuster. Be in communication with the large features to be installed.

Finally, the microorganism detector for measuring the microorganisms contained in the extraction water in the storage vessel is installed at the lower end of the storage container, the microorganism detector is connected to the detection monitor of the ship monitor room by a cable, characterized in that the storage The container is formed as a conical container, characterized in that the microbial detector is installed at the bottom vertex portion of the conical storage container.

According to the present invention as described above, by installing the washing nozzle on the outside of the filter so that the washing water injection and rinsing operation from the outer side of the filter to the inner side is performed, the washing water sprayed from the washing nozzle is attached to the inner surface of the filter While the microorganisms are eliminated from the surface, it is possible to perform an ideal sampling operation such that the microorganisms thus dropped are collected along the inner space of the filter to the lower collecting section.

In addition, by allowing the filtered water discharged from the sampling tank via the filter to be used for rinsing, the rinsing of the filter can be performed more quickly and efficiently without affecting the data error at all. In addition, by connecting the rinsing pipe for the cleaning nozzle to the steam generator or the sterilizing water tank after the extraction of the sample is completed, the sampling tank and the filter can be cleaned more smoothly, thus preserving the sampling tank when not in use. And, in the new process, there is an effect that can control the error due to the microorganisms remaining in the previous process.

In particular, during the rinsing operation of the filter, almost all of the microorganisms are filtered from the inner surface of the filter without being stuck in the filtering hole, exiting the outside of the filter through the filtering hole, or being killed by friction with the filter surface. The microorganisms are included in the sample extract water and stored in the storage container, thereby improving the reliability of the measurement data by minimizing errors in the measured data based on the sample extract water. There is.

In addition, as the filtered water passed through the filter back to the inside of the filter, the overflow tank dilutes the situation in which the ballast water is more effectively blocked, thereby distributing the microorganisms contained in the sample extract water. By excluding another factor that provides an error in the measurement data such as the number of individuals, there is an effect of further improving the reliability of the measured data.

In addition, in the case where the height adjuster is installed and used inside the sampling tank, the height of the upper cradle and the washing nozzle can be arbitrarily adjusted by rotating and lifting the rod bolt by using the rotary knob. Due to this, the filter having various dimensions and processing capacities can be easily replaced and used as necessary, thereby improving the compatibility and economical efficiency of the sampling apparatus.

On the other hand, when the microbial detector is installed at the bottom of the storage container of the sample extract water concentrated microorganisms, and the microbial detector is connected to the detection monitor of the monitor room, the sample extract water is stored in the storage container When placed, it has the effect of accurately measuring the distribution, population, and death of microorganisms contained in the extract water in real time.

This eliminates the cumbersome task of transporting the storage container to a laboratory equipped with measuring equipment by separating the storage container containing the sample extract water from the sampling tank, thereby minimizing the time and cost of measuring the sample extract water. Of course, it has the effect of providing more reliable data by checking the status of the microorganisms from time to time in each time the extract water is introduced into the storage container.

In addition, it is possible to more reliably identify whether the microorganisms killed in the measurement process are caused by the purification device or other external factors by real-time monitoring, so that the ballast water purification device mounted on the vessel is suitable for the emission standard. It is also possible to determine with certainty whether or not it is operating at the level, thereby having a very useful effect such as enabling efficient feedback control of the ballast water purifier.

1 is an exploded perspective view of a sampling apparatus according to a first embodiment of the present invention.
2 is a cross-sectional view of the combined state of FIG.
3 is a perspective view showing a filtration and sampling unit of a microorganism;
4 is an enlarged perspective view of main parts of FIG. 3;
5 is a cross-sectional view of a sampling apparatus according to a second embodiment of the present invention.
Figure 6 is an external perspective view of the height adjuster shown in FIG.
Figure 7 (a) and (b) is a cross-sectional view showing the installation state of the storage container by type.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Also in the sampling apparatus for ship ballast water according to the present invention, as shown in Figures 1 and 2, a conical filter (2) for filtering microorganisms contained in the ballast water is inserted into the sampling tank (1) On the lower side of the sampling tank (1), it is made on the basis of the configuration in which a storage container (8) for storing the extract water in which the microorganisms are concentrated via the filter (2) is installed.

Usually, the upper inlet side of the strainer 2 is mounted on the support 1c provided on the inner wall of the sampling tank 1, while the lower outlet side of the strainer 2 uses the flange-shaped mounting mechanism 2a for the sampling tank. Although the bottom surface of (1) is assembled and provided so that it can be watertight, it is a matter of course that the filter 2 can be installed inside the sampling tank 1 using other various methods.

The filter 2 is usually a fabric (cloth) or a non-woven filter cloth is used, but in some cases may be used to form a metal mesh of stainless steel in a conical shape, the size of the microorganism filtered by the filter (2) (Mu m) depends on the size of the filtration holes provided in the filter 2 (Mesh).

The sampling tank 1 is generally a cylindrical tank using stainless steel, the cover plate (1b) is detachably assembled to the top surface of the sampling tank (1), the ballast water on the center side of the cover plate (1b) The inlet pipe 12 of the through and the bottom side of the sampling tank 1 is connected to the discharge pipe 13 of the filtered water, the inlet pipe 12 and the discharge pipe 13 is introduced into the ballast water And a valve mechanism, not shown, is provided to adjust the discharge of the filtered water.

The inlet pipe 12 is branched from a ballast water pipe not shown to supply ballast water to a ballast tank for ships through a ballast water purification device, but is required for the purpose of collecting a sample of a control group (microbial group before purification treatment). Can also be connected to the ballast water pipe side corresponding to the city ballast water purification device, the amount of ballast water supplied into the sampling tank (1) by the valve mechanism and flow meter (not shown) installed in the inlet pipe (12) It is desirable to be controlled.

In other words, when the flowmeter checks the amount of ballast water flowing into the sampling tank 1 from the ballast water pipe through the inlet pipe 12 and the proper amount of ballast water flows into the sampling tank 1, the flow meter Is to close the valve mechanism installed in the inlet pipe 12, for this purpose, the valve mechanism of the inlet pipe 12 is preferably an automatic control solenoid valve.

If necessary, by installing a level gauge on the upper part of the filter (2), by detecting the level of backflow due to clogging of the filter network with a level gauge to control the valve mechanism of the inlet pipe (12), sampling before the backflow occurs The inflow of ballast water through the tank (1) may be automatically cut off, and in order to precisely control the flowmeter, the inlet pipe 12 should be vertically installed, but the straight pipes of the inflow and outflow lines connected to the flowmeter may be used. It is desirable to secure at regular intervals.

On the other hand, it is preferable to secure the installation space of the storage container 8 at the lower side of the sampling tank 1, and to install a support leg 1a for discharging the filtered water using a free fall. Although the support legs 1a are illustrated as being installed, the number and shape of the support legs 1a may be arbitrarily changed.

2 to 4, the storage container 8 is filtered by a water collecting pipe 7 having an opening / closing valve 15 in a state located in the center of the lower side of the sampling tank 1, as shown in FIGS. (2) is connected to the bottom side, the bottom side of the filter (2) to which the water collection pipe (7) is connected is formed as a pipe-shaped bottom collecting portion (3) for the convenience of piping connection and the primary collection of the extraction water do.

The lower collecting part 3 is most preferably installed in the bottom side of the sampling tank 1 so as to communicate with the lower outlet of the filter 2, but the lower end of the pipe shape at the lower end of the filter 2. In a state in which the collecting part 3 is integrally formed, the lower collecting part 3 may be installed to penetrate the bottom surface of the sampling tank 1, and the inner bottom surface of the lower collecting part 3 is an open / close valve. The bottom surface configuration of the funnel shape which is inclined downward in a diagonal direction is preferable so that extraction water does not remain at the time of opening (15). (Refer FIG. 7).

Although the drain pipe 17 is provided with a drain valve 17a for discharging the filtrate in the lower collecting part 3 in the drawing, even if the drain pipe 17 is not installed, the storage container 8 opens and closes the valve. The filtrate can be discharged in the process of separating from the collection pipe (7) together with (15), and the storage container (8) is also preferably a stainless steel container, but other corrosion-resistant materials may be applied. Of course.

Components corresponding to the first essential part of the present invention are shown in Figures 1 and 2, a plurality of washing nozzles (4) at regular intervals between the sampling tank (1) and the filter (2) It is installed to face the outer surface of the filter (2), each washing nozzle (4) is connected to the rinsing pipe (6) by the nozzle pipe (5), the rinsing pipe (6) is a sampling tank (1) It extends to the outside through the bottom surface of).

In the drawing, the rinsing pipe 6 is installed in an arc shape on the bottom surface of the sampling tank 1 so as to perform the distribution pipe function of the washing water, and the interval of about 90 degrees along the rinsing pipe 6 is provided. Four nozzle pipes 5 are installed in the vertical direction, but the number and arrangement of the cleaning nozzles 4 and the nozzle pipes 5, the installation state of the rinsing pipe 6 and the nozzle pipes 5, etc. It is to be noted that it can be arbitrarily changed according to the shape of the filter 2 or the internal structure of the sampling tank 1.

In addition, the wash water supplied through the rinsing pipe 6 and the washing nozzle 4 uses the filtered water discharged through the discharge pipe 13, and separates the filtered water discharged through the filter 2 into the discharge pipe 13. It is most preferable to store the wastewater in the rinse pipe 6 and use it for the rinsing operation of the filter 2, and then finally drain the filtrate used in the rinsing operation.

The rinsing operation is to perform the washing operation of the filter (2) and the concentration of microorganisms through the bottom collecting section (3), the ballast water inflow into the sampling tank (1) → microbial filtration and filtering of the filtered water in the filter (2) Drain → filter water storage → rinsing (2 ~ 3 times) of filter (2) using filter water and storage of extract water to storage container (8) → final drainage of the filter water constitutes one cycle, and such cycle is several times It is done repeatedly.

When the washing nozzle 4 is installed on the outside of the filter 2 as described above to perform washing and spraying of the washing water from the outside of the filter 2 toward the inside thereof, the washing water sprayed from the washing nozzle 4 is performed. The microorganisms attached to the inner surface of the filter 2 are eliminated from the surface, while the ideal microbial sampling is performed such that the microorganisms thus dropped are collected along the inner space of the filter 2 to the lower collecting section 3. do.

In addition, by allowing the filtered water discharged from the sampling tank 1 through the filter 2 to be used for the rinsing operation, the rinsing operation of the filter 2 can be performed more quickly and efficiently without affecting any data errors. In addition, by connecting the rinse pipe (6) for the washing nozzle (4) with the steam generator or the sterilization water tank after the extraction of the sample is completed, the sampling tank (1) and the filter (2) of the The cleaning operation can be performed more smoothly.

If necessary, the sterilizing water for washing may be stored in a tank for storing the filtered water, and may be directly pumped into the washing nozzle 4 for use in a cleaning operation. According to the application of the cleaning method, the sampling apparatus 10 may be used. When not in use, the sampling tank 1 is preserved, while in the new sampling process, errors due to microorganisms remaining in the previous process can be controlled.

In particular, in the rinsing operation of the filter 2, the microorganisms are stuck in the filtration hole, exit out of the filter 2 through the filtration hole, or are killed by friction with the surface of the filter 2. Since almost all of the microorganisms filtered from the inner side of the filter 2 are stored in the storage container 8 while being included in the sample extract water, there is almost no error in the measured data based on the sample extract water. Since it does not occur, the reliability of the measurement data can be improved.

1 and 2, an overflow tank 11 is inserted between the sampling tank 1 and the filter 2, and the component corresponding to the second main part of the present invention is installed. The cleaning nozzle 4, the nozzle pipe 5, and the rinsing pipe 6 are installed to be located between the overflow tank 11 and the filter 2, and the lower end of the overflow tank 11 has a sampling tank ( It is assembled with the bottom surface of 1), and the open upper end of the overflow tank 11 is to be located at a lower level than the filter (2).

According to the application of the overflow tank 11 as described above, the discharge pipe 13 of the filtered water is installed in connection with the bottom surface of the sampling tank 1 at a position corresponding between the overflow tank 11 and the filter (2) The drain pipe 14 for discharging the overflowed filtrate is additionally installed at the bottom surface of the sampling tank 1 corresponding to the sampling tank 1 and the overflow tank 11.

When the overflow tank 11 having a lower height than the filter 2 is opened between the sampling tank 1 and the filter 2 as described above, the ballast water is forced by the pumping operation. Even if a slight difference occurs in the natural flow rate of the filtered water through the supply flow rate and the drain pipe 14, the space between the sampling tank 1 and the overflow tank 11 can buffer the difference in flow rate. To provide space.

Therefore, even if a large amount of ballast water is introduced or a ballast water above the reference value (content of the overflow tank) is excessively supplied to the sampling tank 1 in a short time due to a malfunction of a flow meter or the like installed in the inlet pipe 12, Since the filtered water passing through the filter 2 is first introduced into the buffer space through the overflow tank 11 and then discharged through the drain pipe 14, a large amount of ballast water exceeding the total volume of the buffer space is supplied excessively. If not, the filtered water passing through the filter 2 will not flow back to the inside of the filter 2.

As described above, since the filtered water passing through the filter 2 flows back to the inside of the filter 2, the situation of diluting the ballast water can be effectively blocked by the overflow tank 11, The reliability of the measured data can be further improved by excluding another factor that gives an error to the measurement data such as the distribution or the number of the microorganisms involved.

The overflow tank 11 is preferably made of stainless steel in the same manner as the sampling tank 1, and the resistance according to the surface tension is minimized so that filtered water as much as the excessively supplied ballast water flow rate can be quickly discharged to the buffer space The height of the overflow tank 11 is preferably about 4/5 of the height of the strainer 2. The height of the overflow tank 11 is preferably about 4/5 of the height of the strainer 2,

In addition, the drain pipe 14 may be provided with a valve mechanism if necessary, since the valve mechanism of the drain pipe 14 is always kept open except in a specific case, so it is a manual ball rather than an automatic solenoid valve. The valve is advantageous, and the method of installing the overflow tank 11 on the bottom surface of the sampling tank 1 may also be applied to any method of fixing by welding or detachable assembling method.

However, in view of the case where the height adjuster 20, which is the third main part of the present invention, which will be described later, is installed, the overflow tank 11 is detachably assembled with the bottom surface of the sampling tank 1 by It is most preferable to replace the overflow tank 11 in accordance with the height of the filter (2), for this purpose in Figure 5 fitting assembly (11b) as an example for the removable assembly of the overflow tank (11) Is shown.

The height adjuster 20, which is a component corresponding to the third essential part of the present invention, has the interior of the overflow tank 11 together with the filter 2 and the cleaning nozzle 4, as shown in FIGS. As inserted into the installation, including the frame structure for mounting the filter 2 and the washing nozzle (4), the sampling device 10 of the type that does not have the overflow tank 11, based on Figure 5 also Of course, it is included in the technical idea of the invention.

 The height adjuster 20 is a plurality of nut rods 18 fixed to the bottom surface of the sampling tank 1 in the vertical direction, and inserted into the vertical direction along the nut rod 18 and the nut rod 18 It is made on the basis of the rod bolt 19 and the rotary knob (19a) provided on the upper end of the rod bolt 19, the three nut rods 18 in the drawing at an angle of 180 degrees Although installed, the number of installation of the nut rod 18 may be two or four, the installation of five or more nut rods 18 is unreasonable in view of the convenience of operation.

On the other hand, as a frame structure for mounting the filter 2 and the washing nozzle (4), the upper end of the ring-shaped upper mounting bracket 21 is mounted on the upper end side of the rod bolt 19, the connecting table 21a It is connected by the installation, the lower end of the nut rod 18, the pipe-shaped lower end 24 is installed by the lower end of the filter unit 2 is mounted by the support 24a, the upper end 21 At the bottom of the nozzle nozzle 23, which supports the nozzle pipe 5 of the washing nozzle 4, is installed in such a way as to hang on the upper base 21.

While the threaded portion is not formed at the upper end side of the rod bolt 19, the groove portion to which the connecting rod 21a for the upper holder 21 is assembled is formed (see FIG. 5), so that the rotation operation of the rod bolt 19 is connected to the connecting rod. Without being restricted by 21a, the upper cradle 21 is made to move up and down with the rod bolt 19, and the support 24a for the lower cradle 24 may be directly connected to the nut rod 18. (See FIG. 5), it may be connected to the lower frame 22 of the nut rod 18 (see FIG. 6).

In addition, the nozzle frame 23 is composed of three vertical frames 23a and two ring frames 23b in the drawing, and the nozzle pipe 5 for the cleaning nozzle 4 also has a shape of the nozzle frame 23. It consists of a pipe in the vertical direction and a ring-shaped pipe, the washing nozzle (4) is arranged in two rows up and down along the nozzle pipe (5) in the vertical direction.

However, the height adjuster 20 illustrated in FIGS. 5 and 6 shows one representative example that may be applied to the present invention, and the height adjuster 20 applied to the present invention is illustrated in FIGS. 5 and 6. The shape of the frame structure and the nozzle pipe 5 for mounting the filter 2 and the cleaning nozzle 4 on the basis of the nut rod 18 and the rod bolt 19 are not limited thereto. It is to be understood that various modifications are possible.

When the height adjuster 20 as described above is installed and used inside the sampling tank 1, as the rod bolt 19 is rotated and raised and lowered using the rotary knob 19a, the upper stage 21 is used. And the height of the washing nozzle 4 can be adjusted arbitrarily, and thus, the filter 2 having various dimensions and processing capacities can be easily replaced and used as necessary, thereby providing compatibility and economical efficiency of the sampling apparatus 10. It will be possible to improve.

On the other hand, since the nozzle pipe 5 for the washing nozzle (4) is also raised and lowered together with the nozzle frame (23) and the upper base (21), the rinsing pipe (6) is to be a rinsing hose (16) of a flexible material. Preferably, for this purpose, the rinsing hose 16 is connected to the hose connector 5a provided on the lower side of the nozzle pipe 5 through the hose insertion pipe 16a provided on the bottom surface of the sampling tank 1. , The water collection pipe 7 is installed to communicate with the discharge hole 25 provided in the lower stage 24 of the height adjuster 20.

Mounting the upper end of the filter 2 to the upper end 21 of the height adjuster 20, depending on the material of the filter 2, there are a wide variety of methods, such as clamping method, screwing method or adhesive method or simple mounting method Although it may be applied, the bottom holder 24 is necessary to prevent the extraction water and the filtered water from being mixed with each other inside and outside of the filter 2, so that a means such as a flange may be used on the upper surface of the lower holder 24. The fastening hole 24b is provided so that the lower end part of the filter 2 may be firmly mounted in a watertight manner.

In addition, when the height adjuster 20 is installed, it is preferable that the bottom catcher 3 for the filter 2 is assembled with the bottom mount 24 of the height adjuster 20, but if necessary, the height adjuster The lower stage 24 of the 20 passes through the bottom surface of the sampling tank 1 and extends downwardly by a predetermined length, so that the lower stage 24 itself serves as the lower catchment 3. It is also possible to do that.

Components corresponding to the fourth essential part of the present invention, as shown in Figures 2 to 5, respectively, at the bottom of the storage container (8) microorganism detector for measuring the microorganisms contained in the extraction water in the storage container ( 9) is installed, and the microbial detector 9 is connected to the detection monitor of the monitor room with a cable 9a.

The microbial detector 9 may be used to install any kind of microorganisms included in the extract water, as long as it can confirm the distribution, population, and death of the microorganisms, but FACS (Fluorescence-activated cell sorting) capable of continuous real-time monitoring Module) or a DLS (Dynamic light scattering) Sensor or a light emitting diode (LED) / PD (Photodiode) type optical detector is most preferable, and the monitor room may be applied to various spaces such as an engine room of a ship, a steering room or a laboratory. .

In addition, a method of outputting the data measured by the microorganism detector 9 to the detection monitor of the monitor room can be applied in a wide variety of ways. For example, size filtering, object extraction, It is used for object measurement, pattern matching, pattern recognition, sensor data monitoring, log data recording, calibration method, data conversion Conversion) can be included.

If the microorganism detector 9 is installed at the lower end of the storage container 8 of the sample extract water in which the microorganisms are concentrated as described above, the microorganism detector 9 is connected to the detection monitor of the monitor room. With the extraction water for the sample stored in), it is possible to accurately measure the distribution, population and death of microorganisms included in the extraction water in real time.

This eliminates the cumbersome work of separating the storage container 8 storing the sample extract water from the sampling tank 1 and transporting the storage container 8 to a laboratory equipped with measuring equipment. Of course, the required time and cost can be minimized, and the state of the microorganisms can be checked from time to time at each time the extract water is introduced into the storage container 8 to provide more reliable data.

In addition, it is possible to more reliably identify whether the microorganisms killed in the measurement process are caused by the purification device or other external factors by real-time monitoring, so that the ballast water purification device mounted on the vessel is suitable for the emission standard. It is also possible to reliably determine whether or not it is operating at the level, which enables efficient feedback control of the ballast water purifier.

In addition, as shown more clearly in FIG. 7A, the storage container 8 is formed into a conical container, while the microbe detector 9 is a lower vertex portion of the conical storage container 8. When installed in the storage container 8, the detection performance of the extraction water by the microorganism detector 9 can be secured to the maximum from the lower end side to the upper end side of the storage container 8.

In other words, when the microorganism detector 9 is installed at the lower end portion of the storage container 8 in a state in which the storage container 8 is formed in a conical shape, the entire internal area of the storage container 8 is the microorganism detector 9. It is included in the detection range by, while the blind spot not included in the detection range does not occur, most preferably the microorganism detector (9) is stored in a state of sealing through a watertight sealing ring or the like. The lower end of the container (8) is to be assembled in a fastening manner.

In FIG. 7B, the conical storage container 8 is installed at an angle to the condensate storage container 8 by a predetermined angle, while the storage container 8 is rotated around the collection pipe 7 as an axis. (Self) is possible, and it is preferable to selectively apply it only when a large amount of foreign matter is included in the ballast water.

When the storage container 8 is installed in the same manner as described above, the storage container 8 can be rotated in an inclined state with the water pipe 7 as an axis, so that the microorganism detector 9 is installed. While foreign matters are prevented from accumulating at the lower end of the), accurate measurement by the microbial detector 9 is possible even when a large amount of foreign matter is included in the sample extract water.

As described above, the technical configuration for rotating the storage container 8 can be applied in a wide variety of forms, for example, by installing a driven sprocket or driven gear on the outer peripheral surface of the storage container 8, the driven sprocket or driven gear Is connected to a drive sprocket or drive gear mounted to the drive motor, while a bearing, which is a rotation support means, is installed at the connection portion of the storage container 8 and the water collection pipe 7, and the microbial detector 9 and the cable 9a. At the connection part of the), a slip ring, which is a rotary electrical connecting means, is installed.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It is therefore to be understood that within the scope of the appended claims, It will be understood by those of ordinary skill in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

For example, for automatic control of the sampling device 10 according to the present invention, while installing a sensor on the inside of the sampling tank 1 and on each pipe, the data input from each sensor is not shown. The controller performs arithmetic processing to automatically control the operation state of the sampling device 10, that is, valve mechanism or pump mechanism for inflow of ballast water, discharge of filtered water, rinsing and cleaning operations.

1 Sampling tank 1a Supporting leg 1b Cover plate
1c: support 2: filter 3: lower collecting part
4: Cleaning nozzle 5: Nozzle pipe 5a: Hose connector
6: rinsing pipe 7: water pipe 8: storage container
9: Microbe detector 9a: Cable 10: Sampling device
11 overflow tank 11a tooth 11b fitting assembly
12: inlet pipe 13: discharge pipe 14, 17: drain pipe
15: on-off valve 16: rinsing hose 16a: hose insertion pipe
17a: drain valve 18: nut rod 19: rod bolt
19a: rotation handle 20: height adjuster 21: the upper stage
21a: connecting rod 22: lower frame 23: nozzle frame
23a: vertical frame 23b: ring frame 24: lower stage
24a: support 24b: fastening hole 25: discharge hole

Claims (7)

The cover plate 1b and the bottom surface of the sampling tank 1 are connected to the inlet pipe 12 of the ballast water and the discharge pipe 13 of the filtered water, respectively, and the microorganisms in the ballast water are installed inside the sampling tank 1. A conical filter 2 for filtering is inserted and installed in the lower side of the sampling tank 1, and a storage container 8 for storing extract water containing microorganisms is installed, and the storage container 8 is opened and closed. In the sampling apparatus 10 of the ship ballast water for ships connected with the lower end collection part 3 of the filter 2 by the water collection pipe 7 provided with the valve 15,
Between the sampling tank 1 and the filter 2, a plurality of washing nozzles 4 are installed to face the outer surface of the filter 2 at regular intervals,
Each of the cleaning nozzles 4 is connected to the rinsing pipe 6 by the nozzle pipe 5,
The rinsing pipe (6) is a sampling device of the ballast water for ships, characterized in that extending through the bottom surface of the sampling tank (1) is installed to the outside. An overflow tank (11) is inserted between the sampling tank (1) and the filter (2), and the cleaning nozzle (4), the nozzle pipe (5) and the rinsing pipe (6) are It is installed to be located between the overflow tank 11 and the filter (2),
The lower end of the overflow tank 11 is assembled with the bottom surface of the sampling tank 1, the upper end of the overflow tank 11 is located at a lower level than the filter 2,
The discharge pipe 13 of the filtered water is connected to the bottom surface of the sampling tank 1 at a position corresponding to the overflow tank 11 and the filter (2),
A drain pipe 14 is sampling device for the ship's ballast water, characterized in that the drain pipe 14 is connected to the bottom surface of the sampling tank (1) corresponding to the sampling tank (1) and the overflow tank (11). 3. An apparatus for sampling ballast water for ships according to claim 2, wherein the upper end surface of the overflow tank (11) is formed with a tooth portion (11a). According to claim 1, wherein the filter (2) and the washing nozzle (4) is installed in the interior of the sampling tank (1) together with the height adjuster (20),
The height adjuster 20 is a plurality of nut rods 18 fixed to the bottom surface of the sampling tank 1 in the vertical direction, and inserted into the vertical direction along the nut rod 18 and the nut rod 18 Rod bolts 19 assembled in a fastening manner, a rotary knob 19a provided at an upper end of the rod bolts 19, and connected to an upper end side of the rod bolts 19, and an upper end of the filter 2 On the ring-shaped upper end 21, the pipe-shaped lower end 24 is connected to the lower end of the nut rod 18, the lower end of the filter 2 is mounted, and the upper end 21 It is installed in a hanging manner consists of a nozzle frame 23 for supporting the nozzle pipe (5) of the washing nozzle (4),
The rinsing pipe (6) is a rinsing hose (16) made of a flexible material, the water collection pipe (7) is installed in communication with the bottom mounting base 24 of the height adjuster (20) via the lower collecting section (3). A sampling apparatus for ship ballast water, characterized by the above-mentioned. According to claim 2, wherein the filter (2) and the washing nozzle (4) is installed in the interior of the overflow tank (11) with the height adjuster (20),
The height adjuster 20 is a plurality of nut rods 18 fixed to the bottom surface of the sampling tank 1 in the vertical direction, and inserted into the vertical direction along the nut rod 18 and the nut rod 18 Rod bolts 19 assembled in a fastening manner, a rotary knob 19a provided at an upper end of the rod bolts 19, and connected to an upper end side of the rod bolts 19, and an upper end of the filter 2 On the ring-shaped upper end 21, the pipe-shaped lower end 24 is connected to the lower end of the nut rod 18, the lower end of the filter 2 is mounted, and the upper end 21 It is installed in a hanging manner consists of a nozzle frame 23 for supporting the nozzle pipe (5) of the washing nozzle (4),
The rinsing pipe (6) is a rinsing hose (16) made of a flexible material, the water collection pipe (7) is installed in communication with the bottom mounting base 24 of the height adjuster (20) via the lower collecting section (3). A sampling apparatus for ship ballast water, characterized by the above-mentioned. The microorganism detector (9) according to any one of claims 1 to 5, wherein the microorganism detector (9) for measuring the microorganisms contained in the extract water in the storage container (8) is installed at the lower end of the storage container (8),
The microbial detector (9) is a sampling device for ship ballast water, characterized in that the cable (9a) is connected to the detection monitor of the ship monitor room. 7. The apparatus for sampling ballast water for ships according to claim 6, wherein the storage container (8) is formed of a conical container, and the microbial detector (9) is installed at a lower end of the conical storage container (8). .

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