KR20130079112A - Toxicity detecting apparatus - Google Patents

Abstract

PURPOSE: An ecotoxicity measuring apparatus is provided to measure the toxicity in a subject liquid in real time. CONSTITUTION: An ecotoxicity measuring apparatus comprises: a first toxicity measuring module (10) to which a subject liquid flows in; an euglena supply module (20) which receives a liquid containing euglenas and supplies the liquid to the first toxicity measuring module; an imaging device which is able to acquire image data of euglenas in the first toxicity measuring module; and a transmission unit which transmits the image data or image data-processed information.

Description

Ecotoxicity detection apparatus {Toxicity detecting apparatus}

The present invention relates to an apparatus for measuring ecotoxicity, and more particularly, to an apparatus for measuring ecotoxicity which can be measured in real time on the presence or absence of toxicity in a liquid to be measured.

In general, the ecotoxicity measuring device is a device for measuring the presence of toxic substances in the liquid to be measured. That is, it is a device for measuring whether a toxic substance exists in the liquid to be measured through a reaction of an organism. To this end, the presence of toxic substances in the liquid to be measured was measured using daphnia magna, luminescent bacteria, and fish.

However, in the conventional ecotoxicity measuring apparatus, there was a problem that it takes a long time to determine the presence of toxic substances in the liquid to be measured. For example, when judging the presence of toxic substances in the liquid to be measured by using water fleas, 50% of the water fleas injected show the concentration of swimming inhibition for one to two days as '1 TU' and the higher the TU, the higher the toxicity. As a result of the evaluation, there was a problem that it takes a long time to determine the presence of toxic substances in the liquid to be measured.

The present invention has been made to solve various problems including the above problems, and an object of the present invention is to provide an ecotoxicity measurement apparatus capable of measuring in real time the presence of toxicity in the liquid to be measured. However, these problems are exemplary and do not limit the scope of the present invention.

According to an aspect of the present invention, a first toxicity measuring module into which the liquid to be measured may be introduced and a liquid including euglena may be accommodated, and the liquid containing the euglena may be supplied to the first toxicity measuring module. An euglena supply module, an image pickup device capable of acquiring image data of the euglena in the first toxicity measurement module, and a transmission unit capable of transmitting image data acquired by the image pickup device or information processed by the image data; Ecotoxicity measurement devices are provided.

The ecotoxicity measurement apparatus may include an inlet pipe through which the liquid to be measured flows into the first toxicity measurement module, and a temperature of the liquid to be measured flowing into the first toxicity measurement module mounted on the inlet pipe. It may be further provided with a temperature control unit.

On the other hand, it may further include a cleaning module for cleaning the inside of the first toxicity measurement module. In this case, the cleaning module may remove the euglena attached to the inner wall of the first toxicity measurement module.

The ecotoxicity measuring apparatus may further include a control supply module, which may store a liquid having no toxicity, and may supply the liquid having no toxicity to the first toxicity measuring module.

At this time, when the non-toxic liquid supplied from the control supply module and the liquid containing the euglena supplied from the euglena supply module are mixed, the first image data obtained by the imaging device, the liquid to be measured and the euglena And a comparison data generation unit for generating comparison data comparing the second image data obtained by the imaging device when the liquid including the euglena supplied from the supply module is mixed, and the transmission unit generates the comparison data generation unit. The comparison data or information processing the comparison data may be transmitted.

The apparatus may further include a first light source capable of illuminating the first toxicity measurement module, and a detector capable of acquiring fluorescence data of fluorescence of the euglena by the first light source, wherein the transmitter is obtained by the detector. Fluorescence data or information processed by the fluorescence data may be transmitted.

The ecotoxicity measurement apparatus may include a second toxicity measurement module into which a liquid to be measured may be introduced and a liquid including the euglena from the euglena supply module may flow, and the second toxicity measurement module may be illuminated. And a detector capable of acquiring fluorescence data of the fluorescence of the euglena by the first light source, and the transmitting unit may transmit fluorescence data acquired by the detector or information processing the fluorescence data. .

On the other hand, the image pickup device may be further provided with a second light source for illuminating the first toxicity measurement module, so as to obtain the image data.

According to one embodiment of the present invention made as described above, it is possible to implement the ecotoxicity measurement apparatus that can be measured in real time for the presence of toxicity in the liquid to be measured. Of course, the scope of the present invention is not limited by these effects.

1 is a configuration diagram schematically showing an ecotoxicity measuring apparatus according to an embodiment of the present invention.
FIG. 2 is a configuration diagram schematically showing a part of FIG. 1.
3 is an image schematically showing the reaction state of the euglena in the first toxicity measurement module.
Figure 4 is a schematic diagram showing a portion of the ecotoxicity measuring apparatus according to another embodiment of the present invention.
Figure 5 is a schematic diagram showing a portion of the ecotoxicity measuring apparatus according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, Is provided to fully inform the user. Also, for convenience of explanation, the components may be exaggerated or reduced in size.

FIG. 1 is a schematic view showing an apparatus for measuring ecotoxicity according to an embodiment of the present invention, and FIG. 2 is a schematic view showing a part of FIG. 1. Referring to the drawings, the ecotoxicity measuring apparatus according to the present embodiment includes a first toxicity measurement module 10, the euglena supply module 20, the image pickup device 63 and the transmission unit (65).

The measurement target liquid may be introduced into the first toxicity measurement module 10. Specifically, the measurement target liquid, which is a measurement target of whether a toxic substance is present through the inlet pipe L1, is the first toxicity measurement module 10. Can flow in. Of course, on-off valves 33 and 35 are mounted on the inlet pipe L1 to the first toxicity measurement module 10 to control the inflow of the measurement target liquid into the first toxicity measurement module 10. Further, the inlet pipe (L1) is equipped with a pump 31 as necessary, through which smooth the inflow of the liquid to be measured into the first toxicity measurement module 10 or the inflow rate into the first toxicity measurement module 10, etc. Can be controlled.

The euglena supply module 20 may accommodate a liquid including the euglena, and may further supply the liquid including the euglena to the first toxicity measurement module 10. This can be done through the euglena supply pipe (L2) connecting the euglena supply module 20 and the first toxicity measurement module (10). Of course, the euglena supply pipe (L2) is equipped with on-off valves (23, 25), it is possible to control the supply of the liquid containing the euglena to the first toxicity measurement module (10). Furthermore, the euglena supply pipe L2 is equipped with a pump 21 as necessary, thereby smoothly supplying the liquid containing the euglena to the first toxicity measurement module 10 or supplying it to the first toxicity measurement module 10. Speed and so on.

The euglena supply module 20 accommodates the liquid containing the euglena, for this purpose it can maintain the temperature of the liquid containing the euglena at 20 ℃ to 25 ℃, which is a temperature suitable for the culture of the euglena, and further euglena containing chlorophyll It may be provided with a light source that emits light for photosynthesis for survival.

In the first toxicity measurement module 10, the liquid including the supplied euglena and the incoming measurement liquid are mixed, and may have a stirring function if necessary. When the liquid including the euglena supplied from the first toxicity measurement module 10 and the introduced measurement target liquid are mixed, the imaging device 63 may acquire image data of the euglena in the first toxicity measurement module 10. . The imaging device 63 generates image data from the input light, and may further include a second light source 61 capable of illuminating the first toxicity measurement module 10 as necessary. The imaging device 63 may be a CCD or a CMOS.

The transmitter 65 may transmit image data acquired by the image pickup device 63 or information on processing such image data. The transmission unit 65 may transmit information through a wired or wireless communication network, such as the Internet network. Of course, the transmission unit 65 does not mean such a wired or wireless communication network itself, it is sufficient that it can transmit information through the wired and wireless communication network.

Such an ecotoxicity measuring apparatus according to the present embodiment is installed in a place where a measurement target liquid exists to measure the presence of a toxic substance, such as a sewage terminal treatment plant or a river near an industrial complex, to measure the presence of a toxic substance in real time. Can be. That is, the euglena immediately reacts as it comes into contact with the toxic material, so the reaction can be confirmed from the data acquired by the image pickup device 63, and the presence of the toxic material therefrom can be confirmed in real time. In addition, whether or not the presence of such toxic substances is transmitted through the transmission unit 65, so that the presence of toxic substances in the liquid to be measured at a remote location, not where the ecotoxicity measurement device is mounted.

In the conventional ecotoxicity measuring apparatus, it took a long time to determine the presence of toxic substances in the liquid to be measured, but in the case of the ecotoxicity measuring apparatus according to the present embodiment, it can be determined in real time. Therefore, in the case of the ecotoxicity measuring apparatus according to the present embodiment, when it is determined that toxic substances are present in the sewage of the sewage treatment plant or in the rivers near the industrial complex, it may provide an environment for prompt follow-up.

3 is an image schematically showing the reaction state of the euglena in the first toxicity measurement module. 3 may be, for example, an image corresponding to data acquired by the imaging device 63 of FIG. 2. Referring to FIG. 3, the euglena in the elongated form and the euglena in the round form coexist, and the euglena has a round form when a toxic substance is present. In other words, it can be understood that the higher the concentration of toxic substances in the liquid to be measured, the higher the proportion of euglena in a round form.

As described above, in the conventional ecotoxicity measuring apparatus, it takes a long time to determine the presence of toxic substances in the liquid to be measured. However, in the case of the ecotoxicity measuring apparatus according to the present embodiment, it is possible to determine in real time the presence of toxic substances in the liquid to be measured by using the properties of the euglena. In addition, by remotely confirming the image data acquired by the image pickup device 63 or the data processed therefrom, it is possible to remotely check whether the toxic substance in the liquid to be measured is present.

In this case, when the image data acquired by the imaging device 63 is remotely confirmed, an observer may recognize the presence of a toxic substance by visually acknowledging the round shape of the euglena. Of course, it is possible to determine the presence of toxic substances through the data of Euglena's aspect ratio. In this case, the data processed by the image data may be, for example, data obtained by calculating such an aspect ratio.

On the other hand, as shown in Figure 1 may be further provided with a temperature control unit 30 mounted to the inlet pipe (L1) as needed. The temperature control unit 30 may adjust the temperature of the liquid to be measured flowing into the first toxicity measurement module 10 through the inlet pipe (L1).

As described above, although the euglena are elongated, they are rounded in the presence of toxic substances. Even though the same concentration of toxic substances exists in the liquid to be measured, the ratio of euglena in the round form may vary depending on the temperature. . Therefore, it is preferable that the temperature of the liquid to be introduced into the first toxicity measurement module 10 is such that the temperature of the euglena to the toxic substance is high.

Therefore, in order to be able to quickly and accurately determine the presence of toxic substances in various liquids to be measured and liquids under various temperature conditions, the first toxicity measuring module of the liquid to be measured through the inlet pipe (L1) ( The temperature of the liquid to be measured may be a temperature within a preset temperature range through the temperature control unit 30 during the inflow into 10). Such preset temperature range may be 20 ° C to 25 ° C. Of course, the temperature of the liquid including the euglena accommodated in the euglena supply module 20 may also be a temperature within the temperature range.

On the other hand, as shown in Figure 1, after the liquid containing the euglena in the first toxicity measurement module 10 is supplied and the liquid to be measured is introduced to determine the presence of toxic substances in the liquid to be measured, the first toxicity measurement module The material in the 10 may be discharged to the discharge module 70 through the discharge pipe (L5). Of course, the discharge pipe (L5) to the discharge module 70 is equipped with on-off valves (71, 73), it is possible to control the discharge of the material in the first toxicity measurement module 10 to the discharge module (70). Furthermore, the discharge pipe (L5) may be equipped with a pump (not shown) as necessary, thereby smoothly discharging the material in the first toxicity measurement module 10 to the discharge module 70 or to control the discharge speed. .

In addition, as shown in Figure 1 may further include a cleaning module 40 for cleaning the inside of the first toxicity measurement module 10. In particular, when discharging to the discharge module 70 of the material in the first toxicity measurement module 10, the euglena is attached to the inner wall of the first toxicity measurement module 10 may not be completely discharged. The cleaning module 40 may remove such euglena that is attached to the inner wall of the first toxicity measurement module 10.

For example, the cleaning module 40 may clean the inside of the first toxicity measurement module 10 by supplying cleaning water such as ultrapure water into the first toxicity measurement module 10 through the cleaning tube L3 as shown. On-off valves 43 and 45 are mounted on the cleaning pipe L3 to the first toxicity measurement module 10 to control the supply of the cleaning water to the first toxicity measurement module 10. Furthermore, the pump 41 is attached to the washing pipe L3 as necessary to smoothly supply the washing water to the first toxicity measuring module 10, or to supply the speed and supply pressure to the first toxicity measuring module 10. Can be controlled.

Of course, unlike the illustrated, the inside of the first toxicity measurement module 10 may be mechanically / physically cleaned through a brush or the like. In addition, chemicals such as ozone water may be used, or may be cleaned using ultrasonic waves.

On the other hand, the degree of response of the euglena may be different according to the minute change in the environment for measuring ecotoxicity. Therefore, the control supply module 50 may be further provided in order to lower the possibility of misjudgment when determining whether there is a toxic substance due to such a slight change in the ecotoxicological measurement environment.

The control supply module 50 may store a liquid having no toxicity, and may supply a liquid having no such toxicity to the first toxicity measurement module 10. In this case, on the basis of the degree of reaction of the euglena when the liquid including the euglena and the non-toxic liquid are mixed in the first toxicity measuring module 10, the euglena is then placed in the first toxicity measuring module 10. The presence of toxic substances in the liquid to be measured may be determined according to the degree of reaction of the euglena when the liquid to be mixed and the liquid to be measured are mixed.

Of course, the control supply pipe (L4) to the first toxicity measurement module 10 is equipped with on-off valves (53, 55), it is possible to control the inflow of the non-toxic liquid into the first toxicity measurement module (10). . Further, the control supply pipe (L4) is equipped with a pump (41) as needed, through which smooth inflow of non-toxic liquid into the first toxicity measurement module 10 or inflow into the first toxicity measurement module (10). Speed and so on.

Figure 4 is a schematic diagram showing a portion of the ecotoxicity measuring apparatus according to another embodiment of the present invention. The ecotoxicity measuring apparatus according to the present embodiment further includes a comparison data generator 65 ′.

The comparison data generator 65 ′ obtains the image pickup device 63 when the liquid having no toxicity supplied from the control supply module 50 and the liquid including the euglena supplied from the euglena supply module 20 are mixed. When the first image data and the liquid to be measured and the liquid including the euglena supplied from the euglena supply module 20 are mixed, the comparison data is generated by comparing the second image data acquired by the imaging device 63. The transmission unit 65 may transmit the comparison data generated by the comparison data generation unit 65 ′ or information processing the comparison data.

A remote observer may receive such comparative data or information processing the comparative data and make a judgment about the presence of toxic substances in the liquid to be measured. Of course, the information processing the comparative data itself may include a result of the presence of toxic substances in the liquid to be measured.

Figure 5 is a schematic diagram showing a portion of the ecotoxicity measuring apparatus according to another embodiment of the present invention.

The ecotoxicity measuring apparatus according to the present embodiment further includes a first light source 67 and a detector 69. The first light source 67 may illuminate the first toxicity measurement module 10, and the detector 69 may acquire fluorescence data for fluorescence of the euglena by the first light source 67. In this case, the transmitter 65 may transmit the fluorescence data acquired by the detector 69 or information processing the fluorescence data.

In the ecotoxicology measuring apparatus according to the above embodiments, the presence of toxic substances was measured by using the animal characteristics of the euglena in which the euglena are present in a round shape in the environment where the toxic substances exist. In the ecotoxicity measuring apparatus according to the present embodiment, further, by using the fluorescence of the euglena that can be observed when the light is irradiated, that is, the presence of toxic substances is measured using the plant properties of the euglena. That is, the ecotoxicity measuring apparatus according to the present embodiment can accurately determine the presence of toxic substances in the liquid to be measured by simultaneously using the animal and plant characteristics of the euglena.

Specifically, since the euglena has a phytochlorophyll-like phytochemical property, chlorophyll in the euglena may be damaged depending on the degree of presence of toxic substances. When light is irradiated, fluorescence can be observed in intact chlorophyll. Therefore, the presence of toxic substances can be determined by determining the ratio of chlorophyll damaged by detecting the degree of fluorescence. Such a detector 69 may be, for example, a fluorescence detector for detecting the fluorescence emitted by the euglena. In this case, the first light source 67 may emit excitation light or actinic light.

Meanwhile, in the drawing, the euglena corresponding to a specific light source are measured according to the measurement using the animal characteristics of the euglena that the euglena takes a round shape in the presence of toxic substances, and the chlorophyll contained in the euglena is damaged in the presence of the toxic substances. Although the measurement using the botanical characteristics of the euglena is different from the observation degree of fluorescence is shown as being made in the first toxicity measurement module 10, the present invention is not limited thereto. That is, the first toxicity measurement module 10 utilizes the animal characteristics of the euglena, ie, the round shape under the environment in which the toxic substances are present, through the second light source 61 and the image pickup device 63, and whether the toxic substance exists. And a separate second toxicity measurement module (not shown) into which the liquid to be measured can be introduced and the liquid including the euglena from the euglena supply module 20 can be introduced therein, and the second toxicity The first light source illuminates the measurement module and the detector acquires fluorescence data for the fluorescence of the euglena in the second toxicology measurement module, thereby utilizing the plant properties of the euglena, that is, the fluorescence characteristics of the illumination by the first light source. You can also determine whether or not.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10: first toxicity measurement module 20: euglena supply module
30: temperature control unit 40: cleaning module
50: control supply module 61: a second light source
63: imaging device 65: transmission unit
65`: comparison data generator 67: first light source
69: detector 70: discharge module
L1: Inlet Line L2: Euglena Supply Line
L3: cleaning tube L4: control supply tube
L5: discharge pipe

Claims (9)

A first toxicity measurement module into which the liquid to be measured flows;
Euglena supply module that can accommodate the liquid containing the euglena, and can supply the liquid containing the euglena to the first toxicity measurement module;
An imaging device capable of acquiring image data of euglena in the first toxicity measurement module; And
A transmission unit capable of transmitting image data acquired by the image pickup device or information processing the image data;
With, ecotoxicity measuring device. The method of claim 1,
An inlet pipe allowing the liquid to be measured to flow into the first toxicity measurement module; And
A temperature controller mounted on the inlet pipe and configured to adjust a temperature of a liquid to be measured flowing into the first toxicity measurement module;
Further comprising, ecotoxicity measuring apparatus. The method of claim 1,
Further comprising a cleaning module for cleaning the inside of the first toxicity measurement module, ecotoxicity measurement apparatus. The method of claim 3,
The cleaning module, the ecotoxicity measurement apparatus that can remove the euglena attached to the inner wall of the first toxicity measurement module. The method of claim 1,
The non-toxic liquid can be stored, and the first toxicity measuring module, which can supply the non-toxic liquid, further comprising a control supply module, ecotoxicity measuring apparatus. The method of claim 5,
The first image data acquired by the imaging device when the non-toxic liquid supplied from the control supply module and the liquid including the euglena supplied from the euglena supply module are mixed, the liquid to be measured and the euglena supply module And a comparison data generation unit configured to generate comparison data comparing the second image data obtained by the image pickup device when the liquid including the euglena supplied from the mixture is mixed.
And the transmission unit transmits the comparison data generated by the comparison data generation unit or information processing the comparison data. The method of claim 1,
A first light source capable of illuminating the first toxicity measurement module; And
And a detector capable of acquiring fluorescence data for fluorescence of euglena by the first light source.
The transmitter may transmit the fluorescence data obtained by the detector or the information processing the fluorescence data, ecotoxicity measurement apparatus. The method of claim 1,
A second toxicity measuring module into which the liquid to be measured may be introduced, and the liquid including the euglena from the euglena supply module may be introduced;
A first light source capable of illuminating the second toxicity measurement module; And
And a detector capable of acquiring fluorescence data for fluorescence of euglena by the first light source.
The transmitter may transmit the fluorescence data obtained by the detector or the information processing the fluorescence data, ecotoxicity measurement apparatus. The method according to any one of claims 1 to 8,
And a second light source capable of illuminating the first toxicity measurement module so that the imaging device can acquire the image data.

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