KR100310531B1 - Automatic measuring apparatus of dissolved oxygen - Google Patents

Abstract

Dissolved oxygen measuring unit with a built-in micro-process, Compressed air supply unit is provided on one side of the dissolved oxygen measuring unit to generate compressed air, the bottom is open and at least one or more micropores are formed in the upper surface or the upper side to be immersed in the sample water A membrane formed horizontally above the inside of the housing and having fine pores formed therein for permeating gas molecules such as oxygen contained in the sample water and not permeating water molecules, and integrally with the membrane; A dissolved oxygen electrode which is connected to the measurement unit and generates a electromotive force by causing a chemical reaction with oxygen that has permeated through the pores of the membrane, and is installed through the upper surface or the side of the housing, and is controlled to the membrane side under the control of the microprocess. By blowing the compressed air of the compressed air supply unit It is installed through the cleaning nozzle for cleaning the membrane and the upper surface or the side of the housing, by the compressed air supply of the compressed air supply to the inside of the housing under the control of the micro-process the sample inside the housing Dissolved oxygen automatic measuring device equipped with a standardizing nozzle for discharging water and filling only the compressed air inside the housing can clean the membrane while the electrode is immersed in the sample, and at the same time the housing submerged in the sample The air can be introduced while discharging the internal sample to standardize the electrode.

Description

Dissolved Oxygen Automatic Measuring Equipment {AUTOMATIC MEASURING APPARATUS OF DISSOLVED OXYGEN}

The present invention relates to an automatic measuring device for dissolved oxygen, and more particularly, an electrode and a membrane are installed inside a housing submerged in sample water to clean the membrane using compressed air and oxygen is introduced to simultaneously standardize the electrode. The present invention relates to an automatic measuring device for dissolved oxygen.

In general, as a method for measuring dissolved oxygen in water, a measuring method using a galvanic cell electrode and a measuring method using a polarographic electrode are used.

The galvanic cell type electrode includes a membrane in which fine pores are formed that allow gas molecules such as oxygen to pass but not water molecules, an electrode plate of a cathode formed of platinum (Pt) inside the membrane, and the electrode. It is composed of a positive electrode wound on the back of the plate a predetermined number of times and formed of lead (Pb), and an electrolyte (KCL or KI) that maintains a current movement between the negative electrode and the positive electrode.

The galvanic (Galvanic) Terrain electrode is brought oxygen (O ₂₎ a cathode (Pt) ion (OH ^-) from the surface through the membrane to form a and an ion (OH ^-) generates a current to the reaction and the anode (Pb) Let's go.

A negative electrode (Pt) _{reaction: O 2 + 2H 2 O +} 4e - -> 4OH - ( 0.576V electromotive force is generated)

The anode (Pb) ^{reaction: 2Pb + 4OH - -> 2PbO} + 2H 2 O + 4e - ( 0.401V electromotive force is generated)

Total response of the electrode: O ₂ + 2Pb-> 2PbO (total electromotive force generated 0.977V)

Since the generated current is proportional to the amount of oxygen dissolved in water and the temperature correction coefficient, the amount of dissolved oxygen in the water is measured by the amount of current generated in the battery.

The polarographic electrode differs from that of the galvanic electrode in that the anode is made of silver, and the galvanic electrode in its operation also has its own chemical reaction. While generating electromotive force, the polarographic electrode differs from applying a constant voltage from the outside.

When a voltage of 0.6V to 1.0V is applied to the polarographic electrode, oxygen (O ₂ ) passing through the membrane is reduced on the surface of the cathode to allow a reduction current to flow. At this time, the concentration of oxygen is measured by measuring a reduction current.

The current flowing at this time,

I = N, F, A, Pm, C (O ₂ )

A: area of electrode

Pm: oxygen permeability of the membrane

N: 4 (chemical formula)

F: Faraday constant

Can be expressed as Pm is a function of temperature, so temperature compensation is required.

When the electrode is made, the remainder is a constant, and thus it can be expressed as I = K · Pm (T) · C (O ₂ ) (T: temperature). That is, the current becomes a value proportional to the temperature and the concentration of oxygen.

However, in the conventional dissolved oxygen automatic measuring device configured as described above, in order to prevent the micropore clogging of the membrane, the membrane may be cleaned by ultrasonic cleaning, high pressure water spraying, or a method of forming a water stream by attaching a small stirrer around the electrode. , But it was difficult to make accurate measurement because it could not be cleaned cleanly. In addition, standardization of electrode was performed by manual removal of electrode out of sample and standardization of electrode. There was this difficult issue.

The present invention has been made to solve the above problems, the object of which is to spray the compressed air to the membrane side while the electrode is immersed in the sample to clean the membrane, and discharge the sample inside the housing using a standardizing nozzle The present invention provides an automatic dissolved oxygen measuring apparatus capable of standardizing electrodes by introducing oxygen.

1 is a use state diagram showing a state of use of the automatic dissolved oxygen measuring apparatus according to the prior art

2 is a use state diagram showing a state of use of the automatic dissolved oxygen measuring apparatus according to the present invention

Figure 3 is a block diagram showing the configuration of the first embodiment of the dissolved oxygen electrode device portion of the present invention

4 is a main configuration of FIG.

5 is a configuration diagram showing the configuration of the second embodiment of the dissolved oxygen electrode device portion of the present invention;

6 is a main configuration of FIG.

<Explanation of symbols for main parts of the drawings>

100: dissolved oxygen measuring unit 120, 200: dissolved oxygen electrode unit

212 cleaning pipe 214 cleaning nozzle

220: membrane 222: dissolved oxygen electrode

224: electrode fixing screw 230: housing

232: fine hole 240: cable fixing

242: electrode cable 243: standardized piping

250: support rod 300: compressed air supply

Features of the present invention for achieving the above object, the dissolved oxygen measuring unit with a built-in micro-process, the compressed air supply unit is provided on one side of the dissolved oxygen measuring unit to generate compressed air, the bottom is open and the top or side At least one micropores are formed on the upper side to be immersed in the sample water, and are installed horizontally above the inside of the housing, and fine pores which allow gas molecules such as oxygen contained in the sample water to pass through, but do not transmit water molecules. The formed membrane, the dissolved oxygen electrode which is integrally provided with the membrane and is connected to the dissolved oxygen measuring unit, generates a electromotive force by causing a chemical reaction with oxygen that has passed through the pores of the membrane, and penetrates the upper surface or the side of the housing. The membrane by the control of the microprocessor A cleaning nozzle for cleaning the membrane by injecting compressed air into the compressed air supply unit and penetrating through an upper surface or a side surface of the housing, and under the control of the microprocess, the compressed air supply unit to the inside of the housing. It is provided with a standardizing nozzle for discharging the sample water in the housing by injecting compressed air and at the same time only the compressed air filled in the housing.

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

2 is a state diagram showing the state of use of the automatic dissolved oxygen measuring apparatus according to the present invention. Here, reference numeral 100 denotes a dissolved oxygen measuring unit, reference numeral 200 denotes a dissolved oxygen electrode device unit, and reference numeral 300 denotes a compressed air supply unit.

First, the dissolved oxygen measuring unit 100 has a general micro process (not shown), is installed on a fixture such as a bottom of a deposit, such as a sample water, and measures the amount of current generated in the dissolved oxygen electrode device 200. The amount of oxygen in the stream is measured.

The dissolved oxygen electrode device 200 is directly immersed in the sample water to generate a current by causing a chemical reaction with oxygen in the sample water of the acid pipe of the sewage and wastewater treatment plant.

In addition, the compressed air supply unit 300 is for cleaning the membrane by spraying compressed air to the membrane side while the dissolved oxygen electrode device 200 is immersed in the sample water.

3 is a configuration diagram showing the configuration of the first embodiment of the dissolved oxygen electrode device 200, Figure 4 shows the main configuration of FIG.

Next, the configuration of the dissolved oxygen electrode device 200 according to the present invention will be described with reference to FIGS. 2 to 4.

First, the upper end side is positioned outside the sample water and is supported by a fixture such as a floor, and the lower end side is provided with a round pipe-shaped support rod 250 immersed in the sample water, and the membrane 220 is fixed to the lower end of the support rod 250. The membrane 220 is formed with fine pores that allow gas molecules, such as oxygen, contained in the sample water to permeate but do not permeate the water molecules. The dissolved oxygen electrode 222 is provided integrally with the membrane 220, and the dissolved oxygen electrode 222 generates an electromotive force by causing a chemical reaction with oxygen in gas molecules introduced through the membrane 220. The magnitude of the electromotive force is transmitted to the dissolved oxygen measuring unit 100, and based on this, the amount of oxygen contained in the sample water is measured. The member lane 220 and the dissolved oxygen electrode 222 are connected to the electrode fixing screw 224. It is fixed to the lower end of the support bar (250). In addition, a housing 230 having an open bottom surface covering the membrane 220 and the dissolved oxygen electrode 222 is fixed to the support rod 250. That is, a predetermined chamber is formed inside the housing 230, and the member lane 220 and the dissolved oxygen electrode 222 are positioned in the chamber. At this time, it is natural that the housing 230 is installed to be completely immersed in the sample water. The dissolved oxygen electrode 222 is connected to the dissolved oxygen measuring unit 100 using the electrode cable 242 as a medium, and the electrode cable 242 is supported by the cable fixing part 240 fixed to the housing 23. The fixed air in which the dissolved oxygen measuring unit 100 is installed is provided with a compressed air supply unit 300, the compressed air supply unit 300 is a cleaning nozzle 214 installed in the housing 230 adjacent to the member lane 220 side ). That is, the compressed air supply unit 300 and the cleaning nozzle 214 communicate with the cleaning pipe 212 through the medium. The cleaning nozzle 214 sprays the compressed air introduced through the cleaning pipe 212 to the membrane 220 to clean the member lane 220. That is, the member lane 220 is cleaned by the flow of compressed air and the sample water. Some of the compressed air injected from the cleaning nozzle 214 is discharged through at least one fine hole 232 formed on the upper surface or the upper side of the housing 230 (in FIG. Seems to form). Then, after the cleaning or standardization process is finished, the compressed air is discharged to the outside of the housing 230 through the micro-pores 232 of the housing 230, which is a bubble generated from the diffuser of the sewage and wastewater treatment plant, etc. This is to prevent the trapped inside the 230 to interfere with the standardized measurement of the electrode.

Referring to the operation of the present invention by the above configuration as follows.

First, when an electric valve (not shown) mounted in the compressed air supply unit 300 is opened according to the control signal of the dissolved oxygen measuring unit (100 of FIG. 2), compressed air is injected from the cleaning nozzle 214 to vortex the sample water. Is formed to clean the surface of the membrane 220. That is, the membrane 220 is exposed to the air because the sample water filled in the housing 230 is pushed out of the housing 230 by the pressure of the compressed air flowing in. Compressed air blows dirt, water film and microbial layers on the surface of the membrane 220, and repeating this process 3 to 5 times, the membrane 220 is cleaned by hydraulic / pneumatic action.

When the electric valve (not shown) mounted on the compressed air supply unit 300 is closed and another electric valve (not shown) is opened according to the control signal of the microprocessor embedded in the dissolved oxygen measuring unit 100, the pressure of the larger pressure is compressed. Air continues to fill the housing 230 so that the sample water is pushed out of the housing 230 completely. At this time, since the dissolved oxygen electrode 222 is completely exposed to the air inside the housing 230, it becomes a state that can be standardized. That is, the amount of current generated by the dissolved oxygen electrode 222 is sensed by the dissolved oxygen measuring unit 100 and recognized as a saturated oxygen concentration of the corresponding temperature band, and stored in a microprocessor as a reference value for continuous measurement to perform standardization. In summary, the cleaning operation and the standardization operation can be performed by adjusting the pressure of the compressed air injected from the cleaning nozzle 214.

When the other electric valve mounted on the compressed air supply unit 300 is closed according to the control signal of the dissolved oxygen measuring unit 100, air is discharged through the micropores 232 drilled on the upper side of the housing 230. The water is easily and accurately filled into the interior of the housing 230.

Thereafter, the dissolved oxygen electrode 222 continuously and automatically measures the dissolved oxygen concentration in the sample water.

5 is a configuration diagram showing the configuration of the second embodiment of the dissolved oxygen electrode device 200 invented in the present invention, Figure 6 shows the configuration of the main part of FIG. This is provided separately from the standardization pipe 243 and the standardization pipe 243 in communication with the compressed air supply unit 300 and the standardization nozzle 243a installed in the housing 230. That is, to perform the cleaning operation of the member lane 220, the compressed air is injected through the cleaning nozzle 214, and when the standardization operation is to be performed, the compressed air is injected through the standardizing nozzle 243a. It is. At this time, the cleaning nozzle 214 is removed and only the standardizing nozzle 243a is installed in the housing 230, so that the cleaning operation and the standardization operation can be performed as described with reference to FIGS. 3 and 4.

As described above, according to the automatic dissolved oxygen measuring apparatus of the present invention, the membrane can be cleaned while the electrode is immersed in the sample, and the standardization of the electrode is performed by introducing air while discharging the sample inside the housing submerged in the sample. You can.

In addition, preferred embodiments of the present invention are disclosed for the purpose of illustration, those skilled in the art will be possible to various modifications, changes, additions, etc. within the spirit and scope of the present invention, these modifications and changes should be seen as belonging to the following claims. something to do.

Claims (3)

Dissolved oxygen measuring unit with a built-in micro-process, A compressed air supply unit provided at one side of the dissolved oxygen measuring unit to generate compressed air; A housing which is opened at a bottom and formed with at least one micropores on an upper surface or an upper side thereof, and is immersed in the sample water; Membrane is installed horizontally above the inner side of the housing, the membrane formed with fine pores that permeate gas molecules such as oxygen contained in the sample water, but does not permeate water molecules; A dissolved oxygen electrode provided integrally with the membrane and connected to the dissolved oxygen measuring unit to generate an electromotive force by causing a chemical reaction with oxygen that has permeated through the pores of the membrane; A cleaning nozzle installed to penetrate the upper surface or the side surface of the housing and spraying the compressed air of the compressed air supply unit to the membrane side under the control of the microprocess; It is installed through the upper surface or the side of the housing, by the compressed air supply of the compressed air supply unit to the inside of the housing under the control of the micro-process to discharge the sample water inside the housing and at the same time inside the housing Dissolved oxygen automatic measuring device characterized in that it comprises a standardized nozzle to be filled in the compressed air only. The method of claim 1, Only one of the cleaning nozzle and the standardizing nozzle is provided, and the pressure of the compressed air injected from any one nozzle selected from the cleaning nozzle and the standardizing nozzle is controlled in the microprocess according to its use. Dissolved oxygen automatic measuring device. The method according to claim 1 or 2, The cleaning nozzle and the standardization nozzle are in communication with the compressed air supply unit using the cleaning pipe and the standardization pipe as a medium, respectively. Dissolved oxygen automatic measuring device, characterized in that the cleaning nozzle and the standardizing nozzle is the cleaning pipe and the standardization pipe, respectively.