KR102134020B1 - Apparatus for measuring residual chlorine - Google Patents

Abstract

An embodiment of the present invention relates to a residual chlorine meter, and more specifically, to a residual chlorine meter, which measures the concentration of residual chlorine contained in the measurement solution using an indicator electrode and a non-electrode in contact with the measurement solution. The residual chlorine meter includes: a main body unit; a storage unit disposed at a predetermined position of the body unit and forming a storage space in which the measurement solution is stored; a measuring module disposed at a predetermined position of the main body unit and contacting the measuring solution stored in the storage unit to measure the concentration of residual chlorine contained in the measuring solution; and a rotation module that applies a rotational force to the measurement module so that the measurement module can be rotated, wherein the measurement module includes the indicator electrode and the comparison electrode in contact with the measurement solution, and the indicator electrode and the non-electrode can be rotated on the measurement solution by the rotation module.

Description

Residual Chlorine Meter {APPARATUS FOR MEASURING RESIDUAL CHLORINE}

The present invention relates to a residual chlorine meter, and more particularly, to a residual chlorine meter for measuring the concentration of residual chlorine contained in the measurement liquid using an indicator electrode and a comparative electrode contacting the measurement liquid.

Chlorine disinfection is a disinfection method that oxidizes contaminants during water purification and sterilizes pathogens and pathogenic microorganisms, and has a long lasting effect, low cost, and is one of the most widely used disinfection methods at home and abroad.

In addition to the water purification process, the chlorine disinfection is widely used in sewage treatment facilities, food processing facilities, swimming pool disinfectants, and household disinfecting bleach.

After the chlorine disinfection treatment, the effective chlorine remaining in the water is called residual chlorine, and the residual chlorine concentration before or after drinking water is 0.2 mg/L to ensure the safety of drinking water and to protect health from contamination in the water supply and drainage stage. Is regulated.

The residual chlorine refers to free effective chlorine (free residual chlorine) such as tea (hypo) chlorophyll and binding effective chlorine (bound residual chlorine) such as chloramine, and remaining after 30 minutes by adding chlorine. It refers to the amount of chlorine expressed in mg/L.

If the residual chlorine temperature is high, disinfection by-products such as Trihalomethane (THM) such as chloroform, which is known as a carcinogen, may be generated, and excessive concentrations more than necessary may control chlorine concentration in the water treatment process for reasons such as causing a sense of rejection to tap water users Measurement is considered a very important process.

Accordingly, there is a need for an electrochemical residual chlorine measurement system capable of real-time monitoring of residual chlorine concentration during water treatment.

On the other hand, Japanese Patent No. 4818164 B2 (registered on November 11, 2011) takes FIG. 6 as an example. Using the indicator electrode 1 and the comparative electrode 2, the current flowing between them is measured to measure residual chlorine. Disclosed to do.

Here, since the indicator electrode 1 should be rotated at a constant speed by the motor 3, the brush 42 is used for electrical connection with the non-rotating comparative electrode 2.

The brush 42 has a problem in that the electrical connection between the indicator electrode 1 and the comparative electrode 2 is weakened due to wear as the usage period becomes longer.

The present invention is to solve the above problems, and to provide a residual chlorine meter capable of measuring residual chlorine more reliably and more easily with an electrical connection between an indicator electrode and a comparative electrode.

The problems to be solved by the present invention are not limited to the above-described problems, and the problems not mentioned will be clearly understood by those skilled in the art from the present specification and the accompanying drawings. .

Residual chlorine meter according to an embodiment of the present invention is to measure the concentration of residual chlorine contained in the measurement liquid by using an indicator electrode and a comparative electrode contacting the measurement liquid, the main body portion; A storage unit disposed at a predetermined position of the main body and forming a storage space in which the measurement liquid is stored; A measurement module disposed at a predetermined position in the main body part and measuring the residual chlorine concentration contained in the measurement solution in contact with the measurement solution stored in the storage unit; And a rotation module that applies a rotational force to the measurement module so that the measurement module can be rotated. The measurement module includes the indicator electrode and the comparison electrode in contact with the measurement liquid, and the indicator electrode and the comparison electrode Can be rotated on the measuring liquid by the rotating module.

According to the residual chlorine meter according to an embodiment of the present invention, there is an advantage in that the electrical connection between the indicator electrode and the comparative electrode can be reliably and more easily measured.

The effects of the present invention are not limited to the above-described effects, and the effects not mentioned will be clearly understood by those skilled in the art from the present specification and the accompanying drawings.

1 is a schematic front view of a residual chlorine meter according to an embodiment of the present invention.
Figure 2 is a schematic plan view for explaining the position movement of the supply module of the residual chlorine meter according to an embodiment of the present invention.
Figure 3 is a schematic front view showing that the supply module of the residual chlorine meter according to an embodiment of the present invention is moved to the second position.
Figure 4 is a schematic cross-sectional view for explaining the fixing module of the residual chlorine meter according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and a person skilled in the art who understands the spirit of the present invention may add another component within the scope of the same spirit, change, delete, etc. Other embodiments included within the scope of the invention idea can be easily proposed, but this will also be included within the scope of the invention.

Residual chlorine meter according to an embodiment of the present invention is to measure the concentration of residual chlorine contained in the measurement liquid by using an indicator electrode and a comparative electrode contacting the measurement liquid, the main body portion; A storage unit disposed at a predetermined position of the main body and forming a storage space in which the measurement liquid is stored; A measurement module disposed at a predetermined position in the main body part and measuring the residual chlorine concentration contained in the measurement solution in contact with the measurement solution stored in the storage unit; And a rotation module that applies a rotational force to the measurement module so that the measurement module can be rotated. The measurement module includes the indicator electrode and the comparison electrode in contact with the measurement liquid, and the indicator electrode and the comparison electrode Can be rotated on the measuring liquid by the rotating module.

In addition, the measurement module may further include a calculator for measuring the current flowing through the indicator electrode and the comparative electrode to calculate the concentration of residual chlorine contained in the measurement solution.

In addition, the measurement module is rotated by the rotation module, it may further include a fixing module for fixing the position of the measurement module to be disposed at a predetermined position of the main body.

In addition, the fixing module may include a fixing portion fixed to the main body portion, a contact portion contacting the measurement module to receive a load from the measurement module, and a bearing portion disposed between the fixing portion and the contact portion.

In addition, the measurement module includes a wireless power receiver for wirelessly receiving power, and is provided at a predetermined position in the main body, and a supply module for wirelessly supplying power to the wireless power receiver of the measurement module. Can.

In addition, the supply module is moved to a first position, a position where wireless power is supplied to the wireless power receiver, and a second position, which is a position that is moved from the first position and does not wirelessly supply power to the wireless power receiver. Can be.

In addition, the supply module may further include a guide module for guiding the position movement of the supply module such that the supply module is moved from the first position to the second position and from the second position to the first position.

Components having the same function within the scope of the same idea appearing in the drawings of each embodiment will be described using the same reference numerals.

1 is a schematic front view of a residual chlorine meter according to an embodiment of the present invention.

Figure 2 is a schematic plan view for explaining the position movement of the supply module of the residual chlorine meter according to an embodiment of the present invention.

3 is a schematic front view showing that the supply module of the residual chlorine meter according to an embodiment of the present invention has been moved to the second position.

Figure 4 is a schematic cross-sectional view for explaining the fixing module of the residual chlorine meter according to an embodiment of the present invention.

In order to more clearly express the technical spirit of the present invention, the accompanying drawings are simplified or omitted from parts that are less relevant to the technical spirit of the present invention or that can be easily derived from those skilled in the art.

1 to 4, the residual chlorine meter 10 according to an embodiment of the present invention is a measuring instrument for measuring the concentration of residual chlorine contained in the measurement liquid (K), the measurement liquid (K) Residual chlorine concentration may be measured by measuring a current flowing between the indicator 230 and the comparative electrode 240 using the contacting electrode 230 and the comparative electrode 240 in contact.

For example, the indicator electrode 230 and the comparative electrode 240 have different oxidation/reduction reactivity, so that current can flow through their reactivity without applying a separate voltage.

That is, the indicator electrode 230 and the comparison electrode 240 may be electrodes using a galvanic battery method, but are not limited thereto, and the indicator electrode 230 and the comparison electrode 240 are constant. Voltage may be applied.

At this time, it can be rotated on the measurement liquid (K) to rub with the beads (eg, ceramic beads) dropped on the measurement liquid (K) to prevent foreign substances from depositing on the surface of the indicator electrode (230).

As described above, the method for measuring the electrode rotary residual chlorine is a well-known technique, as described in Japanese Patent No. 4818164 B2, etc., which has already been described above.

Residual chlorine meter 10 according to an embodiment of the present invention may include a body portion 100.

The main body 100 may be configured to provide an area in which other components of the residual chlorine meter 10 to be described below are arranged and fixed, and may be configured to implement a function of a frame.

That is, the main body 100 may be configured to support other components by receiving loads from other components.

Here, as an example, the residual chlorine meter 10 may include a storage unit 700 disposed at a predetermined position of the main body 100 and forming a storage space in which the measurement liquid K is stored.

As an example, the storage unit 700 may be designed to be detachable from the main body 100 as a configuration for storing the measurement liquid K, or may be integrally designed with the main body 100.

In one example, the measurement liquid (K) may be subjected to a pre-treatment unit (not shown) to remove foreign substances or bubbles before reaching the storage space.

In one example, the measurement liquid (K) may be continuously introduced into the storage space, and may be continuously discharged from the storage space as much as it is introduced.

For example, a plurality of beads that are in contact with the indicator 230 to remove foreign substances on the surface of the indicator 230 may be dropped on the storage space.

Here, as an example, the residual chlorine meter 10 is disposed at a predetermined position of the main body 100 and is in contact with the measurement liquid K stored in the storage unit 700 and included in the measurement liquid K A measurement module 200 for measuring the residual chlorine concentration may be further included.

For example, the measurement module 200 may include the indicator electrode 230 and the comparison electrode 240 in contact with the measurement liquid K.

That is, the indicator electrode 230 and the comparative electrode 240 may be in contact with the measurement liquid K stored on the storage space, and current may flow due to a difference in oxidation/reduction reactivity between each other.

Here, as an example, the residual chlorine meter 10 may further include a rotation module 500 that applies rotational force to the measurement module 200 so that the measurement module 200 can be rotated.

For example, the rotation module 500 may be configured to receive an external force from the motor M and apply rotational force to the measurement module 200.

As a result, the measurement module 200 including the indicator electrode 230 and the comparison electrode 240 may be rotated based on the main body 100.

Hereinafter, a technical idea related to the rotation mechanism of the measurement module 200 will be described in more detail.

In one example, the measurement module 200 may include an electrical circuit that electrically connects the indicator electrode 230 and the comparative electrode 240, and further, optionally, the indicator electrode 230 as necessary. And a voltage applying unit (not shown) for applying a voltage to the comparison electrode 240, and measuring a current flowing through the indicator electrode 230 and the comparison electrode 240 to measure the liquid (K). It may further include a calculation unit (not shown) for calculating the concentration of residual chlorine contained in.

That is, the measurement module 200 may include all configurations of electrodes, circuits, processors, memory, etc. for calculating the concentration of residual chlorine in the measurement liquid K, and as a result, constituting the measurement module 200 All components can be rotated relative to the main body 100 by the rotation module 500.

As a result, since all the components constituting the measurement module 200 are not rotated relative to each other, the rotating configuration and the non-rotating configuration in Japanese Patent No. 4858164 B2 (registered on November 11, 2011) described above do not rotate. Components such as the brush 42 that implement the electrical connection of the components may be omitted.

As a result, even if the measurement module 200 is continuously rotated by the rotation module 500, the electrical connection between the indication electrode 230 and the comparison electrode 240 can be continuously and firmly maintained.

Here, as an example, the measurement module 200, the measurement rotation unit 210 receiving the rotational force from the rotation module 500, extending from the measurement rotation unit 210, the indicator 230 and the comparison pole ( 240) extending from the measurement electrode unit 220 and the measurement rotation unit 210 to provide an area to be mounted, and an arrangement space in which a plurality of components constituting the measurement module 200 such as the calculation unit are disposed. A measurement body portion 250 to be formed may be provided.

In one example, the measurement rotation unit 210 may receive the rotational force from the wire W linked to the rotation module 500, and may form a connection groove S to which the wire W is connected.

In one example, the measurement rotating unit 210 may be rotated based on the first axis (C) receiving the rotational force from the wire (W).

In one example, the first axis (C) may be a central axis of the measurement rotation unit 210.

For example, the measuring electrode unit 220 may be equipped with the indicator electrode 230 and the comparison electrode 240, and the electric wire, electric circuit, etc. connected to the indicator electrode 230 and the comparison electrode 240 It can be placed.

Meanwhile, the rotation module 500 is rotated to provide an external force applying unit 510 receiving rotational force from the motor M and a region to which the wire W is linked, receiving the rotational force from the external force applying unit 510. A link unit 520 may be provided.

Accordingly, when the motor M is operated, the external force applying unit 510 receives the rotational force from the motor M, and the rotational link unit 520 receives the rotational force from the external force applying unit 510. It can be rotated about the 2 axis (B).

In one example, the second axis (B) may be a central axis of the rotary link portion 520.

In addition, the wire W connected to the rotating link unit 520 and the measuring rotating unit 210 may transmit rotational force from the rotating link unit 520 to the measuring rotating unit 210.

In one example, the wire (W) may be an elastic material.

Although the rotation module 500 has been described as transmission of rotational force through the wire W as an example of a rotation transmission mechanism to the measurement rotation unit 210, the rotation module 500 is not limited thereto, and may be variously modified from the viewpoint of those skilled in the art.

On the other hand, the residual chlorine meter 10, the measurement module 200 is rotated by the rotation module 500, the measurement module 200 is fixed to the position to be disposed at a predetermined position of the main body 100 The fixed module 400 may be further included.

In one example, the fixing module 400 receives the load from the measuring module 200 so that the measuring module 200 is fixed to a predetermined position of the body portion 100 and transmits it to the body portion 100 It is also a configuration, and may be a configuration that is fixed to a predetermined position of the main body 100 so that the measurement module 200 can be rotated by the rotation module 500.

In one example, the fixing module 400 is fixed to the main body 100, the fixed part 430, the measurement module 200 is in contact with the measurement module 200 to receive a load from the measurement module 200 and A bearing part 420 disposed between the fixing part 430 and the contact part 410 may be provided.

Therefore, the load of the measurement module 200 may be sequentially transferred to the body portion 100 through the contact portion 410, the bearing portion 420, and the fixing portion 430.

In one example, the measurement module 200 may be mounted on the contact portion 410 to transfer a load to the contact portion 410.

In addition, as an example, the measurement module 200 may be detached from the contact portion 410.

For example, a thread may be formed in the measurement rotation part 210 of the measurement module 200, and a thread may also be formed in the contact part 410, so that the measurement rotation part 210 and the contact part 410 are mutually screwed. It can also be combined.

When the user wants to clean or repair the measurement module 200, the measurement rotation part 210 can be separated from the contact part 410.

For example, the fixing part 430 may be connected to the main body 100 to be detached or may be integrally formed.

In one example, the bearing portion 420 transfers the load of the measurement module 200 from the contact portion 410 to the fixing portion 430, but the contact portion 410 is based on the fixing portion 430. It may be configured to rotate.

In one example, the bearing portion 420 is a contact bearing portion 421 connected to the contact portion 410, a fixed bearing portion 423 connected to the fixed portion 430, and the contact bearing portion 421 and the fixed bearing A ring 425 disposed between the portions 423 may be provided.

As a result, the measurement module 200 is fixedly arranged at a predetermined height based on the main body 100 and can be rotated by the rotation module 500.

On the other hand, the connection method between the measurement module 200 and the fixed module 400 may be variously changed from the viewpoint of those skilled in the art.

For example, the measurement rotating part 210 forming the connection groove S may be integrally connected to the fixing module 400, the measurement electrode part 220 and the measurement rotating part 210 The measuring body portion 250 may be seated, and the measuring electrode portion 220 and the measuring body portion 250 may be detached from each other in a manner such as screw coupling with the measuring rotating portion 210.

Hereinafter, the power supply and communication method to the measurement module 200 will be described in detail.

For example, the measurement module 200 may include a wireless power receiver (not shown) that wirelessly receives power.

For example, the wireless power receiver may be disposed on the upper side of the measurement body 250.

For example, the wireless power receiver may receive power wirelessly from the outside and supply wired/wireless power to a configuration requiring power among the configurations included in the measurement module 200.

Here, as an example, the residual chlorine meter 10 according to an embodiment of the present invention is disposed at a predetermined position of the main body 100 and wirelessly supplies power to the wireless power receiver of the measurement module 200 It may further include a supply module 300.

In one example, the supply module 300 may be disposed at a predetermined distance above the measurement module 200, and may include a wireless power transmitter (not shown) that supplies power to the wireless power receiver.

For example, the radio power transmitter may be disposed on the lower side of the supply module 300 to face the wireless power receiver.

Here, as an example, the supply module 300 is a position that does not wirelessly supply power to the wireless power receiver by moving the position from the first position and the first position, which is a position to wirelessly supply power to the wireless power receiver. Can be moved to the second position.

To explain this in more detail, the first position is a position where at least a portion overlaps between the supply module 300 and the measurement module 200, where the wireless power transmitter can wirelessly supply power to the wireless power receiver. Can mean

As an example, the first position, as shown in Figures 1 and 2 (a), the supply module 300 overlaps in the height direction with the measurement module 200 on the upper side of the measurement module 200 It can be a location.

On the other hand, the second position is a position where at least a portion does not overlap between the supply module 300 and the measurement module 200, and means that the wireless power transmitter cannot wirelessly supply power to the wireless power receiver. can do.

For example, as shown in FIGS. 3 and 2(b), the first position overlaps the supply module 300 in the height direction with the measurement module 200 on the upper side of the measurement module 200. It may not be the location.

When the user needs to clean and repair the measurement module 200, the user moves the supply module 300 located in the first position to the second position, and then moves the measurement module 200 to the fixed module 400. It can be lifted from and separated from the body portion 100.

The measurement module 200 can be freely rotated by the rotation module 500 in that it is wirelessly powered from the supply module 300.

Here, as an example, the residual chlorine meter 10 of the supply module 300 so that the supply module 300 is moved from the first position to the second position and from the second position to the first position. A guide module 600 for guiding position movement may be further included.

In one example, the guide module 600 is fixed to the supply module 300 at a predetermined height on the body portion 100, but from the first position to the second position based on the body portion 100 , It may be configured to rotate from the second position to the first position.

In one example, the guide module 600 is in contact with the supply module 300, the guide contact portion 630 receiving the load from the supply module 300, the guide fixing portion 610 fixed to the main body portion 100 ) And the guide fixing part 610 and the guide contacting part 630, and a guide medium part 620 rotated by an external force on the guide fixing part 610 may be provided.

Meanwhile, the measurement module 200 may further include a communication unit (not shown) capable of wirelessly transmitting/receiving predetermined information/data with an external electronic device.

For example, the communication unit may be disposed on the measurement body unit 250.

In general, the communication unit may communicate with a communication device disposed in the supply module 300 or may communicate with a display unit (not shown) connected to the main unit 100.

For example, the measurement module 200 may transmit the residual chlorine concentration of the measured measurement liquid K to the display unit and/or the supply module 300 through the communication unit.

On the other hand, in the example of the preceding description, based on the measurement module 200, the supply module 300 is the first position from the first position by the guide module 600 to the second position and the second position from the second Although described as being moved to one position, the positional movement of the supply module 300 may be a concept including a relative positional movement based on the measurement module 200.

That is, as an example, the supply module 300 is fixed on the main body 100, the measurement module 200 is overlapped with the supply module 300 based on the main body 100 Of course, it may be moved to the first position and the second position that does not overlap with the supply module 300.

In the above, the configuration and features of the present invention have been described based on the embodiment according to the present invention, but the present invention is not limited to this, and various modifications or changes can be made within the spirit and scope of the present invention. It is apparent to those skilled in the art, and thus, such changes or modifications are revealed to be within the scope of the appended claims.

100: main body
200: measurement module
300: supply module
400: fixed module

Claims (8)

In the residual chlorine meter for measuring the concentration of residual chlorine contained in the measurement liquid by using an indicator electrode and a comparative electrode contacting the measurement liquid,
Body part;
A storage unit disposed at a predetermined position of the main body and forming a storage space in which the measurement liquid is stored;
A measurement module disposed at a predetermined position in the main body part and measuring the residual chlorine concentration contained in the measurement solution in contact with the measurement solution stored in the storage unit; And
Includes; a rotation module for applying a rotational force to the measurement module so that the measurement module can be rotated,
The measurement module,
It is provided with the indicator electrode and the comparative electrode in contact with the measurement liquid,
The indicator electrode and the comparative electrode,
It is rotated on the measurement liquid by the rotation module,
The measurement module,
It has a wireless power receiver for receiving power wirelessly,
It further includes a supply module which is disposed at a predetermined position of the main body portion and supplies power wirelessly to the wireless power receiver of the measurement module.
The supply module,
The first position, which is a position for wirelessly supplying power to the wireless power receiver, and the first position, are moved to a second position, which is a position where wireless power is not supplied to the wireless power receiver,
A guide module for guiding the position movement of the supply module such that the supply module is moved from the first position to the second position and from the second position to the first position while being fixed to a predetermined height of the main body; Containing more,
Residual chlorine meter.
According to claim 1,
The measurement module,
Further comprising a calculation unit for measuring the current flowing through the indicator and the comparative electrode to calculate the concentration of residual chlorine contained in the measurement solution,
Residual chlorine meter.
According to claim 2,
The measurement module is rotated by the rotation module, the fixing module for fixing the position of the measurement module to be disposed at a predetermined position of the main body; further comprising,
Residual chlorine meter.
According to claim 3,
The fixed module,
Fixing part fixed to the main body,
A contact part in contact with the measurement module to receive a load from the measurement module, and
And a bearing portion disposed between the fixing portion and the contact portion,
Residual chlorine meter.
delete delete delete According to claim 1,
The measurement module,
The calculated residual chlorine concentration is wirelessly transmitted to the supply module,
Residual chlorine meter.

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