KR20050010539A - An integrated environmental water toxicity system - Google Patents

Abstract

PURPOSE: An integrated environmental water toxicity detecting system is provided, thereby conveniently and cheaply detecting the environmental water toxicity, reducing the size of the system, and significantly reducing the amount of the medium and wastewater released. CONSTITUTION: The integrated environmental water toxicity detecting system comprises a cover(10) having a plurality of inlets containing a medium inlet(17), a sample inlet(18) and an air inlet(19); a body(14) having a channel(13) with a first reactor(11) and a second reactor(12) which have a closed top due to the cover(10), are independently formed, and are vertically located together; and a reactor housing(16) which receives the body(14), and has an optical fiber contacted with the second reactor(12) of the channel(13) in the bottom and a wastewater releasing hole in one side, wherein the body(14) has at least 4 channels(13) for detecting various toxicity of samples simultaneously.

Description

An integrated environmental water toxicity system

The present invention relates to an integrated underwater toxicity detector capable of efficiently detecting various toxicity present in the water.

In particular, by separating the reactor for culturing recombinant microorganisms sensitive to the toxicity in water and the reactor where the reaction between the microorganism and wastewater occurs, the toxicity can be continuously detected without being affected by the influx of the toxicity, and also the reactor of multiple channels. It relates to a continuous type of integrated underwater toxicity detector that can classify the toxicity in the water by using.

Recently, due to the serious pollution of the water environment, all countries in the world are developing comprehensive water pollution measurement technology to protect the water environment, and investing huge amounts of money for the treatment of waste water.

In particular, water pollution incidents that threaten ecosystems occur as harmful chemicals enter the ecosystem, ie rivers, rivers, and water sources. Proactive prevention is important.

Therefore, it is urgent to develop and install underwater toxicology measurement technology that can be early warning when toxic substances are introduced while constantly monitoring the water source, rivers and rivers, and install them in rivers or rivers.

At present, the water toxicity measurement technique using fish or daphnia has been introduced and operated in several domestic water sources as well as in Europe. However, in terms of efficiency of operation and reaction, it does not meet the simple and sensitive diagnostic requirements for toxicity.

For example, the method of observing changes in motility or fish motility and mortality takes a long time to detect toxicity, and continuous toxicity is not detected when the reaction organism dies through the influx of strong toxicity. There is a disadvantage that cannot be distinguished.

Recently, researches and efforts on methods using recombinant microorganisms that emit light in response to specific toxicity have been actively conducted.

In the case of using the above-mentioned recombinant microorganisms, the organisms used for the contamination measurement can show a lot of efficiency compared to the various methods used in the past because the organisms reduce the disadvantages and emphasize the advantages by using the genetic recombination technology, so the gene Modified luminescent microorganisms are being studied globally to be used not only for measuring water pollution but also for analyzing soil and air pollution.

In the above method, when the recombinant microorganism comes into contact with the toxicity in the water, it generates biological light in response to the toxicity, and the amount of light is changed by the toxic material. How to measure the degree.

This method leads to the development of a multi-channel continuous underwater toxicity detector in parallel with two-stage bioreactors, which classify reactors that react with the growth reactor and sample (wastewater) of the reactive microorganisms, thereby continuously classifying and detecting toxicity in water. Has developed into a device.

Although the above devices have been successful at the laboratory level, there are some disadvantages to overcome in field applications.

In experiments with recombinant microorganisms, the treatment of the waste solution containing the sample and recombinant bacteria is very important and must be isolated and sterilized.

In addition, the amount of medium used for culturing microorganisms is a factor in determining the operational time of the device.

As a result, large amounts of wastewater and rapid consumption of media are obstacles to field application in environments requiring long unmanned underwater toxicity detection.

In addition, since there are many items (pumps, discharge bins, tubes, etc.) necessary for the operation of the device, a large space is required for field application and troublesome movement occurs.

The first reactor and the second reactor are connected by tubes, and each channel is separated, so there is a possibility of the accident of a recombinant microbial spill.

This may result in contamination due to recombinant microorganisms in the field application.

Accordingly, it is an object of the present invention to provide a simple and compact integrated device, for example, integrated underwater toxicity detection device, which is easy to apply in the field and can easily and economically detect various toxicities in water.

The integrated underwater toxicity detection apparatus of the present invention for achieving the above object is a cover having a plurality of inlets for the inlet of the medium, the inlet of the sample, the air in and out, the top is closed by the cover and the upper and lower inside A reactor body having a channel in which the first reactor and the second reactor are vertically connected to each other and are formed independently of each other, and an optical fiber contacting the second reactor side of the channel is hermetically housed in the reactor body. At the same time, one side is characterized in that it comprises a reactor housing having a discharge port for the discharge of waste liquid.

In addition, the channel has a constant volume of an upper open first reactor extending from a wall at an intermediate position inside the channel, and a second reactor formed by a lower space inside the channel body is formed below the first reactor. And a medium inlet extending vertically through the upper lid toward the first reactor side, and a sample inlet and an air inlet positioned vertically through the upper lid on the second reactor side extending to the bottom of the reactor. The lower side of the second reactor is characterized in that the optical fiber of the reactor housing made of a structure in contact.

In addition, the reactor body is characterized by having at least four or more channels arranged side by side to simultaneously classify detection of the toxicity of several samples.

In addition, the reactor housing is characterized in that it further comprises a water jacket for circulating the water around the reactor body for maintaining the temperature in the channel.

1 is an exploded perspective view showing the components of the integrated underwater toxicity detection apparatus according to the present invention

Figure 2 is a cross-sectional perspective view showing the internal structure of the integrated underwater toxicity detection apparatus according to the present invention

Figure 3 is a graph showing the reaction of recombinant microorganisms DK1 and the concentration of microorganisms with time during the hydrogen peroxide test using the integrated underwater toxicity detector according to the present invention

Figure 4 is a graph showing the reaction of recombinant microorganism EBHJ2 and the concentration of microorganisms with time during the continuous paraquat test using the integrated underwater toxicity detector according to the present invention

<Explanation of symbols for main parts of drawing>

10 cover 11 first reactor

12: second reactor 13: channel

14 reactor body 15 optical fiber

16 reactor housing 17 medium inlet

18: sample inlet 19: air inlet

20: water jacket 21: air outlet

22: waste liquid outlet 23: support

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

As shown in FIG. 1, the apparatus of the present invention has a structure in which the reactor body 14 is assembled in the reactor housing 16 and the cover 10 is finished thereon, and in use, the cover 10 and the reactor body ( The entire reactor housing 16 including 14 may be used in a state supported by a separate support 23.

The reactor body 14 and the cover 10 can be maintained in an airtight state by mounting the O-ring and the like on the coupling surface during assembly.

Inside the reactor body 14 having a cylindrical body, a first reactor 11 for culturing microorganisms having a small volume of 1 ml and 2 ml, respectively, and a second reactor 12 for reaction with a sample are formed. .

The two reactors 11 and 12 which have been miniaturized in this way are vertically connected to each other while being formed at the top and the bottom thereof to form one channel 13.

The reaction microorganism may be moved from the first reactor 11 to the second reactor 12 by using gravity generated due to the vertical connection of the reactors 11 and 12.

A medium inlet 17 penetrating the cover 10 is installed to the first reactor 11 side to allow continuous supply of a medium for culturing microorganisms, and the cover 10 to the second reactor 12 side. The sample inlet 18 and the air inlet 19 extending vertically through the () are positioned to the bottom, respectively, so that the sample (waste water) supply for the experiment and the inflow of external air are possible.

An air outlet 21 is installed at the cover 10 side for discharging the air in the channel 13, and a waste liquid outlet 22 is installed at the lower side of the channel 13 to discharge the waste liquid after the reaction.

At this time, the waste liquid outlet 20 is preferably a structure in which a pipe or the like is installed from the outer side of the reactor housing 16 to the channel 13 side of the reactor body 14.

As a preferred embodiment provided by the present invention, after having a plurality of channels 13 having the structure as described above arranged in one body, that is, side by side in one reactor body 14 a set of integrated underwater toxicity detection device Configure.

Each channel 13 is configured independently so that when the recombinant microorganisms of different properties are incubated in a reactor, they operate independently without affecting each other, thereby classifying and detecting the toxicity of the sample.

The optical fiber 15 for light measurement was installed at the bottom of the reactor housing 16 to be in contact with the region of the second reactor 11 of each channel 13.

In the case of using the support 23, it is preferable to form a hole in a position corresponding to each optical fiber 15 on the support surface of the support to secure the space for attaching the optical fiber.

The medium for the microbial culture, the toxic sample, and the air are supplied through a pipe inlet attached to the cover 10 of the channel 13.

In the periphery of the reactor body 14 including the channel 13, a space through which water for maintaining the temperature inside the reactor flows, that is, a water jacket 20, is provided. Bonding of the cover prevents it from flowing into the reactor.

The water jacket 20 includes a structure capable of supplying and discharging water from the outside.

Integrated underwater toxicity detection device of the present invention as described above has the feature that can continuously detect the toxic substances in the water flowing into the plant wastewater, inflow and discharge water, streams, water supplies, etc. of the plant wastewater, wastewater treatment plant.

For example, in the case of the first reactor, the nutrient medium necessary for the growth of microorganisms is introduced into the first reactor by using a smaller operating volume than the second reactor, and the microorganisms using the medium continue to grow.

Microorganisms which are constantly grown without contact with toxic substances in the first reactor are directly introduced into the second reactor by free fall due to gravity.

The microorganism introduced from the first reactor to the second reactor is mixed with the sample flowing into the second reactor, for example, wastewater treatment plant, influent and discharged water, rivers, and water.

When the introduced microorganism is a luminescent microorganism genetically modified to emit light according to the type of the toxic substance, the intensity of light emission may change according to the type of the toxic substance introduced into the second reactor.

The change of light emitted by the microorganisms in the second reactor is transmitted to the light measuring device through the optical fiber attached to the second reactor side, and the amount of light change is continuously measured, and the influx of toxic substances through the change of light with time. The presence and intensity of toxicity are detected.

In the second reactor, the detection apparatus according to the present invention continuously detects toxicity by growing and maintaining genetically recombined microorganisms so as to emit light depending on the type of toxicity. When using the same amount of media as previously used, the operating time is also increased, and the space used for installation can be made very small through vertical arrangement as well as volume reduction of the first reactor and the second reactor. Will be.

Best of all, the recombinant microorganisms can be safely carried out because they exist in a box and move directly from the box to the waste container.

That is, since the detection device provided by the present invention has a small operating volume, not only a small amount of nutrient medium required to maintain the growth of microorganisms but also a small size of the device as a whole, the production cost of the reactor is reduced, and operation and management are easy. .

On the other hand, when the microorganisms used for the detection of toxicity are mixed with the toxic substances, the growth is inhibited and cannot be used for the detection of the toxicity for a long time. In the case of the detection device provided by the present invention, the microorganisms in the first reactor are completely different from the toxic substances. Since it is not mixed, it is maintained and flows into the second reactor, so it is possible to detect toxicity continuously for a long time despite the influx of toxic substances.

In addition, in the second reactor, the optical fiber is connected so that the change of light according to the time when microorganisms are mixed with the toxic substances is immediately transmitted to the light measuring device without loss, so that the inflow of toxic substances into the wastewater treatment plant, the river, and the water supply The presence or absence can be detected simply and continuously.

Therefore, by the on-site application of the detection device provided by the present invention to analyze the sudden discharge of toxic substances due to water pollution accidents or accidents during the operation of the wastewater treatment plant, etc., it is possible to alert to exposure to the source of pollution, and to install As it is suitable for the natural characteristics of the water source, it can prevent the destruction of the ecosystem due to the increase of water pollution.

Hereinafter, the present invention will be described in detail based on the following examples, but the present invention is not limited thereto.

Example 1

After injecting 1.41 ppm of hydrogen peroxide into an integrated small multi-channel continuous underwater toxicity detector, the reaction of the DK1 strain in the device was investigated.

As a result, as shown in FIG. 3, the light increased immediately after the sample was injected, and it can be confirmed that the concentration of the strain was kept constant with time.

Example 2

Six different concentrations of paraquat were injected continuously in one reactor, and the reaction of the EBHJ2 strain was investigated.

The results were observed that the light increases after the sample is injected as shown in Figure 4, and the strain and the sample that caused the reaction over time to escape through the outlet to recover the ability to test the sample continuously have.

In addition, the concentration of the strain remains constant.

As described above, the integrated underwater toxicity detection apparatus of the present invention is provided with a two-stage reactor and four channels integrated into a cylinder having a total diameter of 120 mm, thereby providing simplicity and economy in installation and operation of the apparatus.

This is very effective in field installation applications such as remote unmanned systems compared to conventional devices.

In addition, the miniaturization properties of the present invention significantly reduce the amount of the medium and the waste liquid, allowing for longer periods of operation with the same performance as conventional devices.

The apparatus of the present invention can be usefully used for the detection of toxic substances such as watersheds, wastewater treatment plants and water supplies in rivers.

Claims (4)

A cover 10 having a plurality of inlets for inlet of the medium, inlet of the sample, and inlet of air; The reactor has an upper end closed by the cover 10 and a channel 13 in which the first reactor 11 and the second reactor 12 are vertically disposed while being formed independently of the upper and lower parts, respectively. Main body 14; The reactor body 14 is hermetically contained and the optical fiber 15 contacting the second reactor 12 side of the channel 13 is attached to the bottom side and the reactor side has a discharge port for discharging waste liquid. A housing 16; Integrated underwater toxicity detection device comprising a. According to claim 1, wherein the channel (13) has a constant volume of the upper open first reactor (11) extending from the wall in the middle position of the height, the channel body below the first reactor (11) A second reactor 12 formed by an inner lower space is formed, and a medium inlet 17 extending vertically through the upper cover 10 is extended to the first reactor 11 side, and the second reactor 12 extends. A sample inlet 18 and an air inlet 19 extending vertically through the upper lid 10 toward the bottom of the reactor 12 extend to the bottom of the reactor 12, and at the bottom of the second reactor 12, the reactor housing ( 16) Integrated underwater toxicity detection device, characterized in that the optical fiber 15 of the structure made in contact with. 2. The integrated underwater toxicity detector according to claim 1, characterized in that the reactor body (14) has at least four channels (13) arranged side by side to simultaneously classify and detect the toxicity of several samples. 2. The integrated type of claim 1, wherein the reactor housing (16) further comprises a water jacket (20) capable of circulating water around the reactor body (14) to maintain temperature in the channel (13). Underwater toxicity detectors.