KR101990792B1 - Measuring apparatus for water pollutant inducing environmental stress - Google Patents

Abstract

According to an embodiment of the present invention, an apparatus for measuring a material causing environmental stress analyzes a water quality state of a marine product farm, and comprises: a reagent supply unit to supply a fixed amount of a light emitting reagent to a sensor unit through a reagent supply path; a sample fixed amount supply unit to receive a sample through a sample supply path to supply a fixed amount of the same to the sensor unit; and the sensor unit to receive the light emitting reagent and the sample from the reagent supply unit and the sample fixed amount supply unit. The sensor unit includes: a flow cell to provide a space in which the light emitting reagent and the sample are mixed to cause a chemical light emission reaction; and a light detection unit to detect light emitted by the chemical light emission reaction.

Description

TECHNICAL FIELD [0001] The present invention relates to a measuring apparatus for measuring environmental stress,

The present invention relates to an environmental stressor measuring device, and more particularly, to an environmental stressor measuring device capable of analyzing the quality of water in aquaculture farm.

Environmental stress is a factor that can inhibit the growth of aquaculture in aquaculture farm and further destroys ecological environment. It means stress caused by lost feed or stress caused by secretory material of fish and shellfish.

The increase of environmental stressor in the aquaculture farms causes massive deaths of aquaculture inside the aquaculture farm, and the effluent of the outflowing farms leads to the destruction of the ecological environment.

Recently, water pollution measurement and monitoring systems have been increasingly installed to measure water quality in real time in order to minimize water pollution and provide immediate measures against water pollution.

There is a system for monitoring water pollution using an optical sensor as disclosed in the following Patent Document 1 by the prior art. However, the water quality information that can be measured through the optical sensor used in this technology is easy to measure with domestic technology such as hydrogen ion concentration (pH), redox potential (ORP), dissolved oxygen (DO) or sodium It is only information.

Water quality information such as NH _4, NO ^{2 -} , or NO ^{3 -} often uses expensive foreign technology products, which makes purchasing and procedures complex and costly to maintain.

The prior art of Patent Document 1 also has a problem that the accuracy and accuracy of the sensor are lowered due to the accumulation of contaminants around the sensor. In order to solve this problem, a physical cleaning method of periodically cleaning using a brush disposed around the sensor . However, periodic cleaning apparatuses may have insufficient cleaning during periods of high contamination, which may result in lower accuracy and precision of water quality measurement.

Patent Document 1: Japanese Patent Application Laid-Open No. 2005-108734

According to one embodiment of the present invention, manganese oxide (for example, Mn (II)), iron oxide (for example, Fe (II)) contained in fish, shellfish seawater are suitable for analysis of water quality in aquaculture farm, ), Uric acid, cobalt (Co), glutamic acid, ascorbic acid, lactam antibiotics, or red tide phytoplankton which generates red tide with organic pollutants in seawater (Chattonella marina) and the like can be provided.

According to an embodiment of the present invention, an environmental stress-inducing substance measuring device can be provided which is convenient to use and maintain and does not incur a cost burden.

According to an embodiment of the present invention, an environmental stressor measuring device capable of increasing the accuracy and precision of the sensor unit by filtering the sample sample before the sample sample is supplied to the sensor unit can be provided.

According to an embodiment of the present invention, there is provided an environmental stress-inducing substance measuring device capable of analyzing the quality of water in aquaculture farm, comprising: a reagent supply unit for supplying a light emitting reagent to a sensor unit in a predetermined amount through a reagent supply path; Supplying a sample to the sensor unit by supplying the sample sample through the sample supply path in a predetermined amount; A sensor unit for receiving the reagent and the sample sample from the reagent supply unit and the sample quantitative supply unit; Wherein the sensor unit comprises: a flow cell for providing a space through which the light emitting reagent and the sample are mixed to chemiluminescence; A photodetector capable of detecting light emitted by the chemiluminescent reaction; The environmental stress-inducing substance measuring device may be provided.

In the above embodiment, the reagent supply unit may include a first reagent supply unit for supplying the first reagent, a second reagent supply unit for supplying the second reagent, and a third reagent supply unit for supplying the third reagent.

In the above-described embodiment, the first reagent is a chemiluminescent compound, and the second reagent or the third reagent may be an activator that activates chemiluminescence of the first reagent.

In the above-described embodiment, the first reagent supply unit supplies the first reagent to the sensor unit in a first predetermined amount, the second reagent supply unit supplies the second reagent to the sensor unit in a second fixed amount, 3 reagent supply unit can supply the third reagent to the sensor unit in a third predetermined amount.

The environmental stressor measuring device according to an embodiment of the present invention may further include a filter unit positioned upstream of the sample metering supply unit on the sample supply path.

In the above-described embodiment, the filter unit may receive the sample sample, filter the sample sample, and supply the filtered treatment water to the sample metering supply unit.

In addition, in the above-described embodiment, the filter unit may be formed of a resin column containing a masking agent, and an interfering substance that interferes with the chemiluminescence reaction between the light emitting reagent and the sample May be filtered by a masking agent.

The sensor unit constituting the environmental stress-inducing substance measuring apparatus of the present invention has an effect of being easy to use and manage by a simple configuration.

The sensor unit according to an embodiment of the present invention includes a chemiluminescence sensor to detect manganese oxide (for example, Mn (II)) contained in seawater in fishes and shellfish farms, iron oxide (for example, Fe (Ⅱ)), uric acid, cobalt (Co), glutamic acid, ascorbic acid, lactam antibiotics, organic pollutants in seawater and red tide phytoplankton (Chattonella marina) and the like can be provided.

Particularly, since a sample which is disturbed by environmental stress-inducing substance measurement is targeted and removed through a masking agent included in the filter unit before the sample sample is supplied to the sensor unit, more accurate measurement can be performed .

1 is a view for explaining a structure of an environmental stressor measuring apparatus according to an embodiment of the present invention;
FIG. 2 is a view for explaining a sample quantitative supply unit according to an embodiment of the present invention;
3 is a view for explaining an exemplary structure of a sensor unit according to an embodiment of the present invention,
4 is a view for explaining the structure of a sensor unit according to another embodiment of the present invention, and Fig.
5 is a table for explaining a masking agent according to a light emitting reagent and an interference substance according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features, and advantages of the present invention will become more readily apparent from the following description of preferred embodiments with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.

In this specification, when an element is referred to as being on another element, it may be directly formed on another element, or a third element may be interposed therebetween. Further, in the drawings, the thickness of the components is exaggerated for an effective description of the technical content.

Where the terms first, second, etc. are used herein to describe components, these components should not be limited by such terms. These terms have only been used to distinguish one component from another. The embodiments described and exemplified herein also include their complementary embodiments.

In the present specification, the singular form includes plural forms unless otherwise specified in the specification. The terms "comprise" and / or "comprising" used in the specification do not exclude the presence or addition of one or more other elements.

In this specification, 'and / or' means 'and' or 'or', for example, including 'component A and / or component B' means that component A, component B, Is used to mean including element A and element B (i.e., including at least one of element A and element B).

Definition of Terms

The term "upstream" of component B on the flow path of the fluid in this context means that component A and component B are positioned such that the fluid passes first through component B, B is arranged or configured in the above route.

Herein, that the component B is located 'downstream' of the component A on the flow path of the fluid means that the component A and the component A are positioned such that the fluid passes through the component B after passing the component A first B is arranged or configured in the above route.

The presence of the component A in any 'pathway' herein means that the component A and the path are organically arranged or configured to allow the component A to flow in or out of the fluid flowing in the path.

As used herein, 'path' or 'tubing' may be such as a pipeline that provides a space for the fluid to flow, for example, a closed interior space to allow fluid to move without leaking.

In the present specification, 'communication' means that a path or pipe is connected so that the fluid is movable, and 'untrusted' means that the path or pipe is not connected to each other such that the fluid is not movable.

As used herein, the term 'environmental stressor' is a contaminant capable of destroying the ecological environment of aquaculture farm, including manganese oxide (for example, Mn (II)), iron oxide (for example, Fe (Ⅱ)), uric acid, cobalt (Co), glutamic acid, ascorbic acid, lactam antibiotics, and / or organic pollutants in seawater. And red tide phytoplankton (Chattonella marina).

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail with reference to the drawings. Various specific details are set forth in the following description of specific embodiments in order to provide a more detailed description of the invention and to aid in understanding the invention. However, it will be appreciated by those skilled in the art that the present invention may be understood by those skilled in the art without departing from such specific details. In some cases, it should be mentioned in advance that it is common knowledge in describing an invention that parts not significantly related to the invention are not described in order to avoid confusion in explaining the present invention.

1, an environmental stressor measuring apparatus 150 according to an embodiment of the present invention includes a reagent supply unit 151 and a sensor unit 159 for supplying a light emitting reagent in a predetermined amount to a sensor unit 159 And a sample quantitative supply unit 157 for supplying a sample sample in a constant amount.

When a sample sample contains an environmental stress-inducing substance that can be detected by a light-emitting reagent, light is emitted by a chemiluminescence reaction between the light-emitting reagent and the environmental stress-inducing substance, thereby indicating the presence of an environmental stress-inducing substance. Furthermore, depending on the embodiment, the amount of environmental stressor may be known.

The chemiluminescence reaction between the luminescent reagent and the detection target produces an electrically excited product. The generated material returns from the excited state to the ground state, emits light directly, or emits light while transferring excited energy to another molecule .

Such a chemiluminescence reaction is generally slow in the reaction rate, and thus it is difficult to visually confirm in a short time. Therefore, the reaction can be promoted by using a catalyst suitable for the luminescent reagent. In the present invention, the environmental stress-inducing substances detectable serve as such catalysts. The 'object to be detected' according to the present invention is an environmental stress- .

In the following embodiments of the present invention, the specific configuration of the environmental stressor measuring device 150 capable of detecting such environmental stressor substances will be described.

Meanwhile, in the present specification, the 'luminescent reagent' that emits light when it reacts with the detection target is a compound capable of chemiluminescent reaction such as Luminol, and can be chemiluminescent by mixing ' Is used as a mixture to mean that it includes all of 'broad light emitting reagent'. If there is no merit of distinction, it will be explained as 'luminescent reagent'.

1 is a view for explaining the structure of an environmental stressor measuring apparatus according to an embodiment of the present invention.

1, an environmental stressor measuring apparatus 150 according to an embodiment includes a reagent supply unit 151, a plurality of tubular peristaltic pumps 153, a filter unit 155, a sample quantitative supply unit 157, And a sensor unit 159. Here, a portion of the reagent supply unit 151 and the tube-linked pump 153 are located on the reagent supply path, and the reagent supply unit 151 is located on the upstream side of the peristaltic pump 153. The filter portion 155 and the sample quantitative supply portion 157 are located on the sample supply path and the filter portion 155 is located upstream of the sample quantitative supply portion 157. On the other hand, the sensor unit 159 is located at a point where the sample supply path and the reagent supply path join with each other.

The sensor unit 159 receives a predetermined amount of the light emission reagent from the reagent supply unit 151 and receives a predetermined amount of sample from the sample quantity supply unit 157. The light emission reagent and the sample are mixed, (Hereinafter referred to as a " mixture ") containing a mixture of a sample and a sample to be detected.

According to one embodiment, the reagent supply unit 151 stores the luminescent reagent, and supplies the luminescent reagent to the sensor unit 159 in a fixed amount through the reagent supply path.

In the embodiments of the present invention, 'reagent supply path' refers to a component that provides a space through which the reagent stored in the reagent supply unit 151 can move. For example, it could be a pipeline with an enclosed interior space so that the fluid can move without leaking.

According to one embodiment, the peristaltic pumps 153a, 153b, and 153c are disposed downstream of the reagent supply unit 151 on the reagent supply path to supply the reagent from the reagent supply unit 151 to the sensor unit 159 side And the supply amount of the light emitting reagent to be supplied can be controlled.

For example, the peristaltic pumps 153a, 153b, and 153c supply the reagent to the sensor unit 159 in a predetermined amount (hereinafter, referred to as a "fixed amount") for a predetermined period of time in the reagent supply unit 151.

According to the present embodiment, a plurality of reagent supply units 151 may be provided. 1, the reagent supply unit 151 includes a first reagent supply unit 151a for supplying the first reagent R1, a second reagent supply unit 151b for supplying the second reagent R2, And a third reagent supply unit 151c for supplying the third reagent R3. The first reagent supply unit 151a supplies the first reagent R1 to the sensor unit 159 in a first fixed amount and the second reagent supply unit 152b supplies the second reagent R2 to the sensor unit 159 in the second fixed amount And the third reagent supply unit 151c supplies the third reagent R3 to the sample quantitative supply unit 157 in a third predetermined amount.

According to the present embodiment, each of the tubular peristaltic pumps 153a, 153b, and 153c is disposed on each of the reagent supply paths connected to the respective reagent supply portions 151a, 151b, and 151c, , And 151c.

According to the present embodiment, the environmental stressor measuring device 150 according to an embodiment may further include a T-shaped pipe 161 positioned on the reagent supply path. The T-type pipe 161 receives at least two fluids as inputs, and mixes and outputs the two fluids. The T-shaped pipe 161 is located downstream of the peristaltic pumps 153a and 153b and is located upstream of the sensor unit 159. [

On the other hand, the T-type pipe 161 receives the output of the tube-linked pump 151a and the output of the tube-linked pump 151b, and mixes and outputs them. The output of the T-type pipe 161 is supplied to the sensor unit 159.

For example, as shown in FIG. 1, each of the tube-associated pumps 153a and 153b connected to the respective reagent supply portions 151a and 151b by the T-shaped piping 161 is connected to the tube- And the reagents R1 and R2 output by the sensors 153a and 153b may be supplied to the sensor unit 159 in a mixed state. And the reagent R3 output by the tube peristaltic pump 151c may be supplied to the sample quantitative supply part 157. [

However, since this is an illustrative example, it is also possible to configure the reagent to be mixed only with necessary reagents.

According to one embodiment, the first reagent R1, the second reagent R2, and the third reagent R3 are reagents having different functions, and the reagent supplied to the sensor unit 159 is the first reagent R1), the second reagent (R2), or the third reagent (R3). For example, the light emitting reagent supplied by the reagent supply unit 151 to the sensor unit 159 may be composed of a mixture containing at least one of the first reagent R1 or the second reagent R2, The light-emitting reagent supplied to the sample quantification part 157 by the first reagent 151 may be composed of the third reagent R3.

According to one embodiment, the first reagent R 1 is a chemiluminescent compound and the second reagent R 2 and the third reagent R 3 are chemiluminescent reagents of the first reagent R 1 . ≪ / RTI >

According to one embodiment, the second reagent R2 may be composed of one of an oxidizing agent or a reducing agent which causes a chemiluminescence reaction with the first reagent R1 so that the first reagent R1 can chemiluminesce.

According to one embodiment, the third reagent R3 may be composed of a basic or acidic compound which causes a chemiluminescence reaction with the first reagent R1 so that the first reagent R1 can chemiluminesce. For efficient reaction, it is preferable to be composed of strongly basic or strongly acidic compound. On the other hand, the third reagent R3 may be supplied to the sample quantitative supply unit 157 and act as a carrier in the sample quantitative supply unit 157. [

Various reagents can be used for the light emitting reagent depending on the detection target. For example, one of Luminol, Lucigenin, Luciferin, Acridinium, Oxalate or ruthenium series can be used. However, the present invention is not limited thereto, and it is possible to use various luminescent reagents capable of emitting light in response to a detection target.

The sample quantitative supply part 157 receives the sample sample through the sample supply path and supplies it to the sensor unit 159 in a fixed amount.

The 'sample supply path' means a component for providing a space through which the sample sample supplied by the sample quantitative public service unit 157 can move. For example, it could be a pipeline with an enclosed interior space so that the fluid can move without leaking.

According to one embodiment, the sample quantitative supply part 157 can receive a sample sample from the sample reservoir R disposed on the sample supply path. The tube-operated pump 153d is arranged on the sample supply path so as to be connected to the sample reservoir R to pump the sample sample stored in the sample reservoir R and supply it to the filter unit 155, The supply amount of the sample to be supplied to the filter unit 155 can be controlled.

According to the present embodiment, the environmental stressor measuring apparatus 150 according to an embodiment may further include a filter unit 155 positioned on the sample supply path.

The filter unit 155 may be located upstream of the sample metering supply unit 157 on the sample supply path. The filter unit 155 filters the sample sample supplied from the sample reservoir R and supplies the filtered sample sample (process water) to the sample quantitative supply unit 157.

According to one embodiment, the filter unit 155 may be composed of an adsorbent resin column or an extraction coil including a masking agent. Masking agent means a substance for filtering an interference substance that interferes with a chemiluminescence reaction between a detection target substance and a light emission reagent in a sample sample.

The filter unit 155 can perform filtering by removing interference substances in a sample sample using a masking agent or extracting only a detection target substance from sample samples.

Depending on the type of environmental stressor substance to be detected, various kinds of luminescent reagents can be used, and the kind of interfering substances that interfere with the reaction depending on the luminescent reagent may be changed. The masking agent can be configured in various ways so as to target (remove) the interference substance according to the light emitting reagent, thereby enabling more accurate and precise detection.

FIG. 5 is a table showing a light emitting reagent, an interference substance, and a masking agent according to an object to be detected. Hereinafter, a specific example will be described with reference to FIG.

Example 1) When the detection target is uric acid

In order to detect uric acid, which is an environmental stressor in the sample, Octyl phenyl Polyglycol ether as a first reagent (R1), KMnO ₄ as a second reagent (R2), a third reagent (R3 ) and you can use the HNO _3. The substance which interferes with the chemiluminescence reaction with the Uric acid is ascorbic acid. As a masking agent for this, a trivalent iron ion (Fe (III )) Can be used.

Example 2) When the detection target is a divalent cobalt ion (Co (II))

In order to detect divalent cobalt ions (Co (II)) corresponding to the environmental stress-inducing substance in the sample, the luminescent reagent contains Luminol as the first reagent (R1), H ₂ O ₂ as the second reagent (R2) NaOH may be used as the third reagent (R3). The substance which interferes with the chemiluminescence reaction with the divalent cobalt ion (Co (II)) is a trivalent iron (Fe (III)), and as a masking agent, ascorbic acid acid may be used.

Example 3) When the detection target is 1-glutamic acid

In order to detect 1-glutamic acid, which is an environmental stress-inducing substance in the sample, peroxyoxylate as a first reagent (R1), H ₂ O ₂ as a second reagent (R2), and a third reagent HNO ₃ may be used. The substance that interferes with the chemiluminescence reaction with 1-glutamic acid is monovalent potassium ion (K (I)) and bivalent magnesium (Mg (II)), and the masking agent Perylene can be used.

Hereinafter, the operation of the sample quantitative supply unit 157 will be described in detail with reference to FIG.

Referring to FIG. 2, the sample quantitative supply unit 157 is configured to supply a sample sample in a quantitative manner. For example, it can be composed of a 6-way valve that can supply a sample sample quantitatively by changing position A and position B. Hereinafter, the operation of the sample quantitative feeder 157 will be described on the assumption that the sample quantitative feeder 157 is constituted by a six-way valve.

The sample quantitative supply unit 157 includes a main body B and pipings L1, L2, L3, and L3 having six ports P1, P2, P3, P4, P5, and P6 capable of inputting / L4). Here, the pipes L1, L2, L3 and L4 are located outside the main body B so as to communicate between the ports or to communicate with an external path (or pipe).

The first pipeline L1 is a path for communicating the sample reagent path, specifically the output of the filter 155, with the first port (also referred to as a "sample side port") P1 and the second pipeline L2, Is a path for communicating the second port P2 with the fifth port P5 and the third pipeline L3 is a path for communicating with the third port P3 or the sensor port P3, The fourth pipe L4 is a path for communication between the fourth port and the carrier reservoir (not shown), and the fifth pipe L5 is a path for communicating with the input of the sensor unit 159, And a path for communication between the sixth port P6 and the discharge portion (not shown).

That is, the first pipeline L1 is for allowing the sample to be output from the filter 155 to be input to the first port P1, and the third pipeline L3 is for outputting the sample to be output to the third port P3. Is input to the sensor unit 159.

The fluid does not always flow to the above-mentioned pipes L1, L2, L3 and L4 and by the internal connection of the ports in the main body B, some of the pipes L1, L2, L3 and L4 flow , And the rest may become clogged without flowing fluid. Here, the internal connection can be changed by the operation of the six-way valve (not shown) included in the main body B (here, the operation of the valve in the direction of the arrow is described). On the other hand, the internal connection is defined as Position B to Position B in the embodiment of the present invention.

In position A, the main body B is internally connected so that the first port P1 and the second port P2 are communicated with each other, and the fifth port P5 and the sixth port P6 are communicated with each other, Lt; / RTI > Here, the third port P3 and the second port P2 are internally unconnected, and the fourth port P4 and the fifth port P5 are internally disconnected from each other.

On the other hand, for the purpose of explanation of the present invention, when a valve (not shown) is positioned so as to be Position A, it is assumed that the sample quantitative supply part 157 performs a quantitative filling operation. The quantitative filling operation is an operation of filling the sample sample in a predetermined amount, and in this embodiment, the sample sample can be filled, for example, in the second pipe L2.

In position B, the first port P1 and the sixth port P6 of the main body B are internally connected to communicate with each other, and the second port P2 and the third port P3 are communicated with each other. And the fourth port P4 and the fifth port P5 are internally connected to communicate with each other. Here, the third port P3 and the second port P2 are internally unconnected, and the fifth port P5 and the sixth port P6 are internally disconnected from each other.

On the other hand, for the purpose of the description of the present invention, it is assumed that the sample quantitative supply unit 157 is performing a quantitative supply operation when a valve (not shown) is positioned so as to be at Position B. That is, the quantitative supply operation is an operation of supplying a sample sample filled in a fixed amount in the quantitative filling operation to the sensor unit 159.

The sample sample supplied to the first pipe L1 through the tube peristaltic pump 153 is supplied to the first port P1, the second port P2, the second port P2, The fifth port P5 and the sixth port P6 and the fifth pipe L5 and the carrier is discharged through the fourth pipe L4 and the fourth port P4 ), The third port P3, and the third pipe L3.

On the other hand, after the instant when the sample sample is discharged to the outside through the fifth pipe L5, it is switched to the position B state (that is, the fixed amount supply operation state).

When the position A is changed to the position B, the sample sample supplied to the first pipe L1 through the tube-associated pump 153 is introduced into the first port P1, the sixth port P6, the fifth pipe L5, And is discharged to the outside. Further, when the carrier is supplied to the fourth pipe L4, the sample sample that has been filled in the second pipe by the carrier is supplied to the sensor unit 159 through the third port P3. Specifically, when the carrier is supplied to the fourth pipe L4, the carrier moves to the fourth port P4, the fifth port P5, the third pipe L3, the second port P2, the third port P3, , And the third pipe (L3).

Here, when all the sample samples stored in the third pipe L3 are supplied to the sensor unit 159, the state is switched to the Position A state (i.e., the constant filling operation state).

In the above-described manner, the sample sample is supplied to the sensor unit 159 by a predetermined amount while the operation is alternately switched between Position A and Position B.

3 is a view for explaining an exemplary structure of a sensor unit according to an embodiment of the invention.

Referring to FIG. 3, the sensor unit 159 includes a flow cell 152 that provides a space through which a light emitting reagent and a sample can be chemically reacted with each other, and a light- And a light detection unit 154 that can detect the light.

According to one embodiment, the sensor unit 159 can be manufactured in such a manner that a flow cell 152 and a light detecting unit 154 are mounted on a flexible substrate such as an aluminum plate.

The flow cell 152 may be composed of a reaction chamber 152a having an internal space in which the light emitting reagent and the sample sample can be received and kept airtight. The reaction chamber 152a is formed of a transparent material through which light can be transmitted and the light emitted from the inner space is transmitted through the reaction chamber 152a so as to be transmitted only through a part of the reaction chamber 152a Other portions except for a part (hereinafter referred to as "light-transmitting portion") are configured to be wrapped with an opaque material.

The reaction chamber 152a may be composed of a transparent glass (for example, borosilicate) having excellent durability and transparency or a transparent plastic (for example, acrylic plastic).

According to one embodiment, the reaction chamber 152a may be configured to be wrapped with an opaque material such as black PVC to prevent light from leaking out of the light-transmitting portion allowed to transmit light.

The photodetector 154 couples with the flow cell 152 in such a manner as to completely cover the light transmitting portion allowed to transmit light in the reaction chamber 152a.

According to an embodiment, a light inlet portion (PMT hole) through which the light transmitted through the light transmitting portion of the reaction chamber 152a can be formed may be formed in the light detecting portion 154, ) And the light transmitting portion of the reaction chamber 152a are airtightly coupled with the flow cell 152a at the corresponding positions. Herein, the light inlet hole has a size enough to completely cover the light transmitting portion of the reaction chamber 152a and a size of the light of the reaction chamber 152a so that light emitted from the light transmitting portion of the reaction chamber 152a can be transmitted only to the light detecting portion 154 And is configured to be tightly coupled to the transmissive portion.

According to one embodiment, the photodetector 154 may include a transducer that converts the intensity of the light sensed when the light is emitted from the light transmitting portion of the reaction chamber 152a into an electrical signal and outputs the electrical signal. For example, the transducer may be composed of a photo multiplier tube (PMT), a photomultiplier, a photodiode or a photo transistor.

That is, the light detecting unit 154 is a device for receiving light, that is, converting light into an electrical signal, and may further include a device for amplifying an optical and / or electrical signal.

An electrical signal output from the light detecting unit 154 is transmitted to the computer 200, and the computer 200 may analyze the electrical signal characteristic to determine the degree of contamination of the sample.

For example, the computer 200 may compare the intensity of the electrical signal with a reference value (a value predetermined for each environmental stressor) to determine whether the sample contains environmental stressor substances to be detected. Also, the computer 200 may determine how much the environmental stressor substance to be detected by analyzing how much the intensity of the electrical signal is greater than the reference value.

Various reagents can be used for the luminescent reagent depending on the type of the environmental stress-inducing substance to be detected. Therefore, the reference value may mean a predetermined value for each light emitting reagent depending on the environmental stressor.

4 is a view for explaining a structure of a sensor unit according to another embodiment of the present invention.

Referring to FIG. 4, the sensor unit 159 includes a flow cell 152 for providing a space in which a light emitting reagent and a sample are mixed with each other to chemilatively emit light, a light emitted by a chemiluminescent reaction A plurality of optical detectors 154a, 154b, and 154c, and an optical wavelength divider 156 that can detect the light.

4 and the embodiments described with reference to Figs. 1 to 3, the embodiment of Fig. 4 further includes an optical wavelength splitter 156, and the sensor unit 159 also includes a plurality of optical detecting sections There is a difference between the two. Hereinafter, the embodiment of FIG. 4 will be mainly described.

According to the embodiment of FIG. 4, the sensor unit 159 shown in FIG. 4 includes a reagent supply unit 151, So that the detection object can be confirmed according to the kind of the reagent.

Since the wavelength of light emitted differs depending on the type of the light emitting reagent, light having different wavelengths is emitted when a plurality of light emitting reagents reacting in the flow cell 152 are present.

The optical wavelength divider 156 is an optical element that divides light according to wavelengths when it receives an optical signal including lights of different wavelengths.

According to one embodiment, the light wavelength divider 156 receives the light emitted from the flow cell 152, divides the light into different wavelengths, and emits the light.

The optical wavelength divider 156 and the flow cell 152 are coupled such that the optical wavelength divider 156 is such that the light emitted from the flow cell 152 is not leaked to the outside but is introduced into the optical wavelength splitter 156.

On the other hand, the lights of different wavelengths split by the optical wavelength divider 156 are individually provided as a plurality of optical detectors 154a, 154b and 154c.

Each of the plurality of photodetecting sections 154a, 154b, and 154c is configured to be able to detect light by separately receiving light of each wavelength divided by the optical wavelength divider 156, The detection target can be confirmed.

The operation and configuration of each of the plurality of optical detectors 154a, 154b, and 154c in FIG. 4 are described with reference to FIGS. 1 to 3. FIG.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents. And should be determined by equivalents to the scope of the appended claims.

150: Environmental Stress Indicator
151: Reagent supply part
152: Flow cell
153: Pump peristaltic pump
154:
155:
157: Sample quantitative supply unit
159: Sensor unit
161: T-piece (tee pipe)
200: computer
201:
203: AD converter
205: Computer processor

Claims (13)

An environmental stressor measuring device (150) for analyzing a water quality of a fish farm,
A reagent supply unit 151 for supplying the light emitting reagent to the sensor unit 159 in a quantitative manner via the reagent supply path;
A sample quantitative supply unit 157 for supplying a sample sample through the sample supply path and supplying a sample sample to the sensor unit 159 in a predetermined amount;
A sensor unit 159 receiving the reagent and the sample from the reagent supply unit 151 and the sample quantitative supply unit 157; And
And a filter unit (155) located upstream of the sample metering supply unit (157) on the sample supply path,
The sensor unit 159,
A flow cell 152 for providing a space in which the light emitting reagent and the sample sample are mixed with each other and chemiluminescent reaction can be performed; And
A photodetector 154 capable of detecting light emitted by the chemiluminescence reaction; Lt; / RTI >
The flow cell 152 is composed of a reaction chamber 152a having an internal space capable of accommodating a light emitting reagent and a sample sample and kept airtight,
The reaction chamber 152a is formed of a transparent material through which light can be transmitted, and the light emitted from the internal space can be transmitted only through a part of the reaction chamber 152a-the light transmitting part- The partial-light-transmitting portion is configured to be wrapped with an opaque material,
The light detecting unit 154 is formed with a light inlet hole through which the light transmitted through the light transmitting portion of the reaction chamber 152a can be received,
The light inlet hole is formed to have a size enough to completely cover the light transmitting portion so that light emitted from the light transmitting portion of the reaction chamber 152a can be transmitted only to the light detecting portion 154,
Wherein the flow cell (152) and the light detection unit (154) are closely contacted to each other at a position corresponding to the light inflow hole and the light transmission unit,
The filter unit 155 may be composed of a resin column containing a masking agent and an interference substance interfering with the chemiluminescence reaction between the light emitting reagent and the sample sample may be formed in the masking agent Masking agent for measuring environmental stress. The method according to claim 1,
The reagent supply unit 151 includes a first reagent supply unit 151a for supplying a first reagent, a second reagent supply unit 151b for supplying a second reagent, and a third reagent supply unit 151c for supplying a third reagent and,
The first reagent is a chemiluminescent compound, and the second reagent or the third reagent is an activator that activates chemiluminescence of the first reagent,
The first reagent supply unit supplies the first reagent to the sensor unit 159 in a first fixed amount, the second reagent supply unit supplies the second reagent to the sensor unit 159 in a second fixed amount, And the third reagent supply unit supplies the third reagent to the sample quantitative supply unit 157 in a third predetermined amount. 3. The method of claim 2,
Wherein the second reagent is one of an oxidizing agent and a reducing agent,
Wherein the third reagent is one of a basic or an acidic compound. The method according to claim 1,
The optical detector 154 includes a converter for converting the intensity of the detected light into an electrical signal and outputting the electrical signal,
Wherein the transducer is one of a photoelectron amplifier tube (PMT), a photodiode, or a photo transistor. The method according to claim 1,
Wherein the filter unit (155) receives the sample sample and filters the sample sample, and the filtered sample sample is supplied to the sample quantitative supply unit (157). delete delete The method according to claim 1,
Wherein the sample quantitative supply part (157) is constituted by a six-way valve (157) configured to change the flow path. The method according to claim 1,
The environmental stress-
The present invention is not limited to any one of manganese oxide, iron oxide, uric acid, cobalt (Co), glutamic acid, ascorbic acid, lactam antibiotics and Chattonella marina Characterized by an environmental stressor measuring device. 3. The method of claim 2,
Wherein the first reagent is any one of Luminol, Lucigenin, Luciferin, Acridinium, Oxalate or ruthenium series. The method according to claim 1,
Wherein the masking agent is any one of iron oxide, ascorbic acid, and perylene. The method according to claim 1,
A light wavelength splitter 156 capable of splitting the light emitted by the chemiluminescence reaction into light of different wavelengths in a flow cell 152; And
And a plurality of optical detectors (154)
Wherein each of the plurality of light detecting units (154) receives light of each wavelength divided by the light wavelength dividing unit (156) separately and detects light. 6. The method of claim 5,
Further comprising a plurality of tubular peristaltic pumps (153)
The plurality of tube peristaltic pumps 153 are configured to be disposed upstream of the filter unit 155 on the sample supply path and downstream of the reagent supply unit 151 on the reagent supply path,
The tubular peristaltic pump 153a disposed upstream of the filter unit 155 on the sample supply path is connected to a sample storage tank in which the sample is stored to supply the sample to the filter unit 155 or the sample quantitative supply unit 157 Supply,
The peristaltic pumps 153b, 153b, and 153d disposed downstream of the reagent supply unit 151 on the reagent supply path are configured to supply the reagent stored in the reagent supply unit 151 to the sensor unit 159 Characterized by an environmental stressor measuring device.

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