KR101775927B1 - Apparatus for measuring TRO - Google Patents

Abstract

The present invention relates to an apparatus to measure a concentration of residual chlorine, comprising: a measurement unit having a light emitting unit and a light receiving unit, wherein a sample water inflow pipe into which sample water flows is installed; a reagent storage unit in which an accommodating space is formed to accommodate a reagent, and the accommodating space reduced when being pressurized; an elastic member pressurizing one side of the reagent storage unit; and a control unit measuring oxidizer concentration of a sample water based on a signal received in the light receiving unit after light generated in the light emitting unit penetrates through the sample water. As such, a structure is simplified to improve durability.

Description

Apparatus for measuring TRO [0002]

The present invention relates to an apparatus for measuring residual chlorine concentration. More particularly, the present invention relates to a device for measuring residual chlorine concentration, which not only improves the durability by simplifying the structure for injecting reagents but also allows a reagent to be injected in a fixed amount.

In general, cargo vessels transported on the sea are mostly single-headed except for vessels that are traveling round-trip for the exchange of similar cargoes. In addition, the ballast water is flown into the ballast water in order to improve the balance of the ship, the safety and the maneuverability of the ballast water when the ballast water is sailed.

At this time, the ballast water is filled in one port and transported elsewhere, where it is discharged into a new port. Thus, the release of marine organisms and pathogens contained in ship ballast water from distant locations is not only detrimental to the new environment, but can also be dangerous to both humans and animals in new ports.

The introduction of non-natural marine life into new ecosystems can have devastating effects on native flora and fauna that may not have a natural defense system against new species. In addition, harmful bacterial pathogens such as cholera may be present in the original harbor. These pathogens may proliferate in ballast tanks over time and cause disease in areas where they are released.

The risks posed by these marine organisms and pathogens can be controlled by killing the species present in the ballast water.

An electrolytic method is mainly used for disinfecting ship ballast water. A ship ballast water treatment system using an electrolysis method has a TRO sensor unit for measuring TRO of ballast water.

Here, "TRO" stands for "Total Residual Oxidant", which means the total residual oxidizing agent present in the ballast water. Usually, the chlorine generated through the electrolysis process oxidizes aquatic organisms in the ballast water and the remaining chlorine Measured values are obtained. When electrolysis or chlorine disinfection of sea water or salt mixed water is performed, TRO is replaced by an atom such as bromine instead of active chlorine, and various kinds of oxidizing agents coexist, and all active oxidizing agents present at this time are indicated.

Since the above-mentioned TRO sensor must operate in various water quality conditions such as fresh water and seawater according to the route of the ship, the TRO sensor using the DPD reagent, which is less sensitive to the water quality change, is mainly used.

The TRO measurement sensor using the DPD reagent not only includes a transfer pump for injecting the reagent into the measuring part in the reagent container but also includes a check valve in the supply pipe to prevent backflow when the reagent is transferred through the transfer pump The configuration is very complex.

The transfer pump included in the TRO measurement sensor is used for transferring the DPD reagent, which is a chemical product, so that corrosion is easily generated, thereby causing durability problems and frequent failures.

Also, since the variation of the input amount depending on the pressure is large, it is difficult to inject the DPD reagent in a fixed amount.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a residual chlorine concentration measuring device capable of simplifying a constitution for injecting reagents of ship equilibrium water, .

According to an aspect of the present invention, there is provided an apparatus for measuring residual chlorine concentration, comprising: a measurement unit having a light emitting unit and a light receiving unit and provided with a sample water inlet pipe into which sample water flows; A reagent storage part in which a receiving space is formed to receive a reagent and the receiving space is reduced at the time of pressurization; An elastic member for pressing one side of the reagent storage part; And a controller for measuring an oxidant concentration of the sample water based on a signal received by the light receiving unit after the light generated by the light emitting unit transmits the sample water.

Here, the reagent reservoir may be composed of bellows, and may be composed of a cylinder and a piston.

The elastic member may be a spring, and one end of the spring may further include height adjusting means for adjusting the height.

Meanwhile, in the reagent storage unit, a reagent inlet pipe may be connected to inject the reagent into the measurement unit, a reagent control valve may be installed in the reagent inlet pipe, and a reagent control valve may be a pinch valve . In addition, the reagent inlet pipe may be made of a chemical resistant tube.

The reagent storage unit may be provided with a plurality of reagents so that the reagents can be continuously supplied when the reagents are replaced.

The measurement unit may include a sample water outlet pipe through which the sample water inlet pipe is provided with an inlet valve and through which the measured sample water is discharged, and a drain valve may be installed in the sample water outlet pipe.

In addition, the measurement unit may be formed of a transparent material through which light can pass, and may be configured to connect an overflow pipe.

The light emitting unit may be a white LED, and the light receiving unit may be an RGB sensor.

According to the present invention, the reagent storage portion is pressed by the elastic member to inject the reagent, thereby simplifying the structure and improving the durability.

In addition, according to the present invention, there is an effect that the amount of reagent can be controlled by including the pressure regulating unit for regulating the pressing force of the elastic member.

FIG. 1 is a configuration diagram showing an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention,
FIG. 2 illustrates a reagent supply unit provided in an apparatus for measuring residual chlorine concentration according to another embodiment of the present invention,
FIG. 3 illustrates a reagent supply unit provided in an apparatus for measuring residual chlorine concentration according to another embodiment of the present invention,
FIG. 4 is a graph showing the relative responsivity of the light-receiving unit provided in the apparatus for measuring residual chlorine concentration according to an embodiment of the present invention,
5 is a flowchart showing a method for measuring residual chlorine concentration according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

1 is a configuration diagram showing an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention.

1, the residual chlorine concentration measuring apparatus 100 includes a measuring unit 110 for measuring the residual chlorine concentration of the sample water, a reagent holding reagent and a reagent for injecting the reagent into the measuring unit 110, And a control unit 150 for opening or closing the valves according to the sensing information measured by the measuring unit 110. [

The measurement unit 110 is installed on both side surfaces so that the light emitting unit 111 and the light receiving unit 113 face each other. The measuring unit 110 is formed of a transparent material through which light can pass so that the light generated by the light emitting unit 111 can pass through the measuring unit 110 and reach the light receiving unit 113 .

Here, the light emitting unit 111 may be a white LED for measuring all three-wavelength wavelength bands. The light receiving unit 113 is composed of an RGB sensor having a color filter corresponding to Red, Green, and Blue, and is configured to recognize all wavelengths of three channels. By confirming the three wavelength bands, it is possible to increase the accuracy in measuring the concentration of the oxidizing agent that has been developed with DPD, and to cope with all kinds of reagents that produce different colors with one device.

When the white LED of the light emitting unit 111 is turned on, the intensity of light transmitted through the RGB sensor of the light receiving unit 113 can be measured to measure the residual chlorine concentration.

The measurement unit 110 is provided with a sample water inlet pipe 121 to allow the sample water to flow therein and a sample water outlet pipe 125 to discharge the measured sample water.

The sample water inlet pipe 121 is provided with an inlet valve 123 and the sample water outlet pipe 125 is provided with a discharge valve 127 so that the reagent introduced from the reagent storage section 130 is reacted with the sample water So that it can be discharged smoothly afterwards.

The apparatus for measuring residual chlorine concentration (100) according to an embodiment of the present invention measures the concentration of diethyl-p-phenylende diamine (DPD) reagent in various equipments for measuring oxidizing agent to be fed into ballast water, And the concentration of the residual oxidizing agent is measured.

The DPD type oxidizing agent measuring apparatus includes a reagent storage unit 130 for storing the DPD reagent since a portion of the treated ship equilibrium water is sampled and then the DPD reagent is input to measure the oxidizing substance concentration. The DPD reagent is mixed with the buffer solution and injected into the measuring unit 110. The DPD reagent and the buffer solution may be mixed and stored in one container, but they are preferably stored in separate containers.

Further, the reagent storage unit 130 may further include a temperature holding unit (not shown) which is maintained at a predetermined temperature to increase the reactivity of the reagent and the lifetime of the reagent.

The residual chlorine concentration measuring apparatus 100 according to an embodiment of the present invention includes elastic members 133a and 133b for pressing one side of the reagent storage unit 130 so that the reagent is injected into the measuring unit 110.

The elastic members 133a and 133b perform a function of generating a pressing force and can replace the pressurizing pump included in the existing residual chlorine concentration measuring apparatus and can supply the reagent stored in the reagent storage unit 130 with a simple structure do.

According to one embodiment of the present invention, the elastic members 133a and 133b are constituted by coil springs, but not limited thereto, various members having elastic force can be used.

Here, the upper end and the lower end of the elastic member 133 are connected to the upper plate 131 and the lower plate 135, respectively.

The lower plate 135, which is a lower end of the elastic member 133, may further include a height adjusting means 139 for adjusting the height of the lower plate 135 by providing a threaded portion 137. The pressing force of the elastic member 133 can be increased or decreased while the lower plate 135 is raised or lowered by the threaded portion 137 when the height adjusting means 139 is rotated in a predetermined direction.

Such an elastic member 133 generates a pressing force by a law of a hook, and the force F applied is equal to the product of the constant k and the displacement x or the length x. That is, F = kx. Here, the value of k is related not only to the type of elastic material to be considered but also to its size and shape. In one embodiment of the present invention, the height adjustment means 139 increases or decreases the value of k.

Unlike the embodiment shown in FIG. 1, the lower end of the elastic member 133 does not include the height adjusting means 139, and the lower end of the elastic member 133 is connected to the inner surface of the lower housing 101 of the residual chlorine concentration measuring apparatus 100 It may be configured to be supported.

The reagent storage part 130 is configured such that a receiving space is formed therein to receive the reagent, and the receiving space is reduced when the reagent is pressurized.

In one embodiment of the present invention, the reagent storage unit 130 is formed of bellows in the form of a corrugated tube.

2 shows a reagent supply unit provided in the apparatus for measuring residual chlorine concentration according to another embodiment of the present invention. The lower end of the reagent storage unit 130 is supported by the housing 101, Is pressed by the elastic member 133 located on the upper side.

The residual chlorine concentration measuring apparatus 100 of the present invention is not limited to this, and the reagent storage unit 130 may be configured to be pressed in the lateral direction. 1 or 2, the elastic member 133 or the reagent storage part 130 is supported by the side housing of the apparatus for measuring residual chlorine concentration 100. In this case,

3 shows a reagent supply unit provided in the apparatus for measuring residual chlorine concentration according to another embodiment of the present invention. Referring to FIG. 3, the reagent storage unit 170 includes a cylinder And a piston 173 which is inserted into the cylinder 175 and reciprocates.

The lower end of the piston 173 is coupled to the lower plate 131 and is supported by the elastic member 133.

2 and 3 are the same as those in FIG.

1, the apparatus 100 for measuring residual chlorine concentration according to an embodiment of the present invention includes a reagent storage unit 130 for storing a reagent solution such that the DPD reagent stored in the reagent storage unit 130 is supplied to the measuring unit 110, A reagent inlet pipe 141 is provided between the storage unit 130 and the measurement unit 110 and a reagent control valve 143 may be installed in the reagent inlet pipe 141 to control the inflow flow of the reagent.

The reagent storage unit 130 may include a plurality of reagent storage units 130 as shown in FIG. The first reagent storage unit 130a and the second reagent storage unit 130b are configured to store the reagents in the first reagent storage unit 130a and the second reagent storage unit 130b, Since the reagent can be supplied through the reaction tube 130b, continuous reagent supply becomes possible.

Here, the reagent inlet pipe 141 may be formed of a chemical resistant tube to prevent corrosion or breakage by the supplied reagent.

The reagent control valve 143 may be a pinch valve. The pinch valve is a device that regulates the opening and closing of the valve while pressing the elastic body up and down with two bars (BAR). Since the fluid to be delivered is only in contact with the inside of the elastic body and no driving parts are contacted with the valve, There is no fear of corrosion of the valve due to no contact, and durability is improved, so that maintenance and repair costs can be minimized.

Meanwhile, the elastic member 133 of the present invention maintains a state of being compressed by a predetermined displacement at the initial position, and the pressing force is generated by the upward force of the top plate 131 due to the restoring force. Since the elastic member 133 operates by the above- As the top plate 131 rises, the displacement decreases and the pressing force also decreases linearly.

The residual chlorine concentration measuring apparatus 100 of the present invention should adjust the opening time of the reagent control valve 143 in consideration of such a linear change of the pressing force in order to supply a reagent of a predetermined amount. For example, at the point where the top plate 131 rises to a certain height from the initial position and the pressing force becomes 1/2 of the initial value, the opening time of the reagent control valve 143 is doubled so that the reagent injection amount can be supplied in a constant amount .

The residual chlorine concentration measuring apparatus 100 according to an embodiment of the present invention may include an overflow pipe 160 connected to the measuring unit 110 as shown in FIG.

Here, the overflow pipe 160 can simultaneously perform an overflow function and an air vent function for discharging the sample when the number of samples in the measurement unit 110 is overflowed. The overflow pipe 160 is preferably connected to the upper end of the measuring unit 110 so that the overflow pipe 160 performs an air vent function well.

The control unit 150 measures the residual chlorine concentration of the sample water based on the signal received by the light receiving unit 113 after the light generated by the light emitting unit 111 passes the sample water.

If the number of samples is not equal to the number of samples in the measurement unit 110 after the inlet valve 123 is opened, the control unit 150 can recognize that no sample water is flowing and generate an alarm. When the discharge valve 125 is opened An alarm may be generated if the sample water of the unit 110 is not discharged. The control unit 150 turns on the light emitting unit 111 while the measurement unit 110 is empty and stores the light amount measured by the light receiving unit 113 and determines whether the light is to be filled based on the stored light amount. That is, when the light amount becomes weaker than a certain level, it is judged that the number of samples is filled. In addition, if the amount of light exceeds a certain amount even when the number of samples is empty, it is determined that the measuring unit 110 is contaminated.

In addition, the control unit 150 may repeat the opening / closing operation of the inlet valve 121 so that the reagent injected into the measuring unit 110 is well mixed.

Although not shown in FIG. 1 of the present invention, the measuring part 110 is formed in a hollow cylindrical shape, and the direction of the sample water inlet is formed in a direction in contact with the inner wall surface so that the number of samples injected along the inlet part rotates along the inner wall surface .

FIG. 4 is a graph showing the relative responsivity of the light receiving unit included in the apparatus for measuring residual chlorine concentration according to an embodiment of the present invention.

Referring to FIG. 4, the relative reactivity of the red, green, and blue regions varies depending on the wavelength. For example, in the red region, the relative reactivity is increased at the wavelength of about 750 nm, and the green region is increased in the relative reactivity at the wavelength of about 560 nm Able to know.

The measurement unit 110 of the present invention measures the presence or absence of filling of the sample using the RED region of the RGB sensor using the graph of FIG. 4, and the residual chlorine concentration of the sample water is measured in the GREEN region . ≪ / RTI >

That is, the measurement unit 110 turns on the light emitting unit 111 and stores the amount of light measured in the RED (about 750 nm wavelength) area by the light receiving unit 113, The reagent is injected into the sample water, the light emitting unit 111 is turned on, and then the light amount is measured using the GREEN region (wavelength of 560 nm) of the light receiving unit 113.

5 is a flowchart showing a method for measuring residual chlorine concentration according to an embodiment of the present invention. The residual chlorine concentration measuring method of the present invention uses the residual chlorine concentration measuring apparatus disclosed in Figs. 1 and 2.

Referring to FIGS. 1 to 5, the residual chlorine concentration measuring method according to an embodiment of the present invention first opens the inlet valve 123 and the discharge valve 127 to bypass the number of samples (S110). The number of samples to be bypassed is used to clean the sample water inlet pipe 121 and the sample water outlet pipe 125, and the sample water inlet space of the measuring unit 110.

Next, the discharge valve 127 is closed to fill the measuring unit 110 with the sample water (S120). Whether or not the number of samples is filled can be determined by measuring the amount of light in the light receiving unit 113 after the light emitting unit 111 is turned on. When the number of samples of the predetermined capacity is filled, the inlet valve 123 is closed.

Then, the reference point is set by measuring the absorbance of the sample water without injecting the reagent into the filled sample number (S130). This reference point is the reference absorbance.

Thereafter, the discharge valve 127 is opened, the number of samples for which the reference absorbance measurement is completed is discharged from the measuring unit 110, the discharge valve 127 is closed after the discharge is completed, (S140).

At this time, in order to confirm the discharge completion of the sample water, the absorbance of the sample is measured by the measuring unit 110. After the discharge is confirmed, the discharge valve 127 is left open for a few seconds, . By this operation, the measurement error can be reduced.

When the number of new samples is injected into the measuring unit 110 in the step of replacing the number of samples (S140), the number of samples is filled by opening the inlet valve 123, Confirm by absorbance. When the number of samples is filled, the opening / closing of the inlet valve 123 is repeatedly operated. For example, it is opened for about 0.5 second and then closed for about 0.5 second so that the sample water flows into the measuring unit 110 while forming a vortex. Through this operation, the introduced reagents are mixed well.

Next, the reagent is injected into the number of replaced samples (S150), and the colorimetric absorbance is measured by the measuring unit 110 (S160).

In this case, when the reagent control valve 143 is opened, the reagent storage unit 130 pressurized by the elastic member 133 injects the reagent while reducing the accommodation space.

More specifically, after the reagent control valve 143 is opened for a short time and then closed to inject a small amount of reagent after the initial two to three times of the opening / closing operation of the inlet valve 123, The reagent is well mixed in the measuring unit 110. [

Thereafter, the control unit 150 converts the residual chlorine concentration based on the measured reference absorbance and the color absorbance (S170). That is, when measuring the standard absorbance, the amount of sample light received in the absence of reagent is measured. When measuring the color absorbance, the light amount of the number of samples injected with the reagent is measured, Converted to the residual chlorine concentration. The a value is an LED having a light emitting portion 111 and a light emitting portion 111 having a transmittance of the measuring portion 110 and a light receiving portion 113, All. After mixing the reagents, the sample water is developed, so that a light absorbing power is generated and the light amount measured by the light receiving unit 113 is weakened. The higher the residual chlorine concentration, the more color is produced and the light amount value becomes smaller. If there is no coloration after mixing the reagents, the same amount of light as the reference light amount is measured. Since there is no difference, the residual chlorine concentration becomes zero.

Next, the number of samples for which the residual chlorine concentration is measured is discharged with the discharge valve 127 being opened (S180).

Thereafter, the repeating operation is performed again from the step S110 of bypassing the number of samples in order to measure the residual chlorine concentration of the new sample number.

As described above, the residual chlorine concentration measuring apparatus 100 according to an embodiment of the present invention is configured to have a structure in which the reagent is pushed and injected by the elastic member 133, so that a separate pressurizing means (for example, a pump) It is possible to improve the durability and the maintenance of the reagent. Further, the amount of the reagent can be kept constant and the reagent can be supplied in a fixed amount.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: Residual chlorine concentration measuring device 110:
111: light emitting portion 113: light receiving portion
121: sample water inlet pipe 123: inlet valve
125: sample water discharge pipe 127: discharge valve
130, 170: Reagent storage part 133: Elastic member
141: Reagent inlet tube 143: Reagent regulating valve
150: control unit 173: piston
175: Cylinder

Claims (12)

A measuring unit having a light emitting unit and a light receiving unit and provided with a sample water inlet pipe into which sample water flows;
A reagent reservoir formed in the bellows so as to accommodate the reagent therein and to reduce the accommodation space when pressurized;
An elastic member for pressing one side of the reagent storage part; And
And a control unit for measuring the oxidant concentration of the sample water based on a signal received by the light receiving unit after the light generated by the light emitting unit transmits the sample water,
The reagent storage unit may include a reagent inlet pipe connected to inject the reagent into the measurement unit,
A reagent control valve is installed in the reagent inlet pipe,
Wherein the controller is configured to adjust the opening time of the reagent control valve in consideration of a linear change in the pressing force of the elastic member so that a reagent of a predetermined amount is supplied.
delete delete The method according to claim 1,
Wherein the elastic member comprises a spring,
Wherein the one end of the spring further comprises a height adjusting means for adjusting a height of the spring.
delete The method according to claim 1,
Wherein the reagent control valve is a pinch valve.
The method according to claim 1,
Wherein the reagent storage unit is provided with a plurality of reagent storage units.
The method according to claim 1,
Wherein the measuring unit comprises:
An inlet valve is installed in the sample water inlet pipe,
Wherein a sample water discharge pipe through which sample water is discharged is provided, and a discharge valve is provided in the sample water discharge pipe.
The method according to claim 1,
Wherein the measuring unit is formed of a transparent material through which light can pass.
The method according to claim 1,
Wherein the light emitting portion comprises a white LED,
Wherein the light receiving unit is constituted by an RGB sensor.
The method according to claim 1,
Wherein the reagent inlet pipe is made of an chemical resistant tube.
The method according to claim 1,
Wherein the measuring unit is connected to an overflow pipe.

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