KR101489630B1 - water sensor probe of which sensor is cleaned for itself - Google Patents

Abstract

The present invention relates to a water sensor probe for measuring water quality, and more particularly, to a water sensor probe for measuring water quality, more specifically, by providing a flow fan rotating by a motor on a sensor cover, And a sensor cleaning function capable of precisely measuring water quality of measurement water in spite of long-term water quality measurement by preventing foreign matter such as water or dust from sticking to the sensor.

Description

[0001] The present invention relates to a water sensor probe having a sensor cleaning function,

The present invention relates to a water sensor probe for measuring water quality, and more particularly, to a water sensor probe for measuring water quality, more specifically, by providing a flow fan rotating by a motor on a sensor cover, And a sensor cleaning function capable of precisely measuring water quality of measurement water in spite of long-term water quality measurement by preventing foreign matter such as water or dust from sticking to the sensor.

In order to prevent the sticking of foreign matter such as water or dust by the long-term water quality measurement, it is required to measure the acidity and turbidity of wastewater applied to the Korean Utility Model Application No. KR20- 1995-0029667).

The prior art is characterized in that the funnel shape has a drain pipe provided with a solenoid valve at the center of the bottom plate and has an overflow pipe for keeping the wastewater at a predetermined level at a predetermined position of the side plate, A sensor for measuring the acidity of the wastewater in the sample container, the sensor being fixed to the sample tube lid by a welded guide, and a lid fixed by a welded guide A turbidity measuring sensor for measuring the turbidity of the wastewater in the sample cylinder, a nozzle for cleaning the pH sensor and a nozzle for cleaning the turbidity measuring sensor in a lower fractionation pipe located inside the sample cylinder with a solenoid valve And a cleaning water supply pipe provided with the cleaning water supply pipe.

However, in the prior art, since a cleansing water supply pipe for supplying cleansing water is separately required, it is difficult to provide a cleansing water supply pipe when the sensor is installed far from the deep cleansing water.

Although the present invention does not use a separate rinse water, it locally increases the speed of water movement around the sensor surface, generates a vortex around the sensor surface, and measures long-term water quality of the water, So that it is possible to accurately measure the quality of the water.

The main body 100 includes a tubular main body 100, a sub body 200 sealing the lower end of the main body 100 and fastened to the main body 100, And a sensor cover (400) which surrounds the sensor (300) and is fastened to the sub body (200) to protect the sensor (300) A flow fan 530 installed inside the sensor cover 400 to be rotatable by a driving force; A guide pipe 610 installed above the flow fan 530 to guide the measurement water inside the sensor cover 400 upward as the flow fan 530 rotates to clean the sensor 400; The present invention relates to a water sensor probe having a sensor self-cleaning function.

In the present invention, the cross-sectional area of the guide pipe 610 may be reduced while moving upward.

 In the present invention, a spiral-shaped vortex-forming projection 610 may protrude from the inner circumferential surface of the guide tube 610 so that the measurement water sprayed from the guide tube 610 forms a vortex.

The guide tube 610 is protruded from the upper surface of a fixing plate 600 whose circumferential surface is in contact with the inner surface of the sensor cover 400 and is fixed to the guide plate 610, May be disposed on a straight line formed along the longitudinal direction of the sensor 300. [

In the present invention, a mounting groove or mounting protrusion for mounting the shielding plate is formed on the upper end of the guide pipe 610 so that a shielding plate for shielding the outlet of the guide pipe 610 can be selectively mounted. .

In the present invention, a mesh screen is provided at the lower end of the sensor cover 400, and the rotation axis of the motor 520 may be selectively rotated forward and reverse.

In the present invention, by providing a flow fan rotating by a motor on a sensor cover, measurement water in the sensor cover flowing by the flow fan flows upward to clean the sensor, and foreign matter such as water or dust is fixed to the sensor It is possible to accurately measure the water quality of the measurement water despite the long-term water quality measurement.

1 is a perspective view of an embodiment of the present invention;
2 is a partially cutaway perspective view of one embodiment of the present invention;
3 is an exploded perspective view of a main portion of an embodiment of the present invention;
4 is a detailed view of a guide tube according to an embodiment of the present invention;

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

1 is a perspective view of an embodiment of the present invention, FIG. 2 is a partially cutaway perspective view of an embodiment of the present invention, FIG. 3 is an exploded perspective view of a main part of an embodiment of the present invention, It shows the detailed view of the guide pipe.

Referring to FIG. 1, an embodiment of the present invention includes a probe body 100, a sensor 300 fastened to the lower ends of the probe bodies 100 and 200, And a sensor cover 400 which surrounds the probe body 300 and is fastened to the probe bodies 100 and 200. The probe bodies 100 and 200 may include a tubular main body 100 and a sub body 200 coupled to a lower end of the main body 100.

Referring to FIG. 1, a motor support bar 510 is installed in the sensor cover 400. Both ends of the motor support bar 510 are supported and fixed to the inner surface of the sensor cover 400. A motor 520 is fixed to the motor support bar 510.

Referring to FIG. 1, a flow fan 530 is installed below the sensor cover 400. The flow fan 530 is connected to the rotation shaft of the motor 520 so as to rotate by the driving force of the motor 520. The flow fan 530 is intended to flow the measured water inside the sensor cover 400 upward.

Referring to FIGS. 2 and 3, a fixing plate 600 is installed inside the sensor cover 400. The fixing plate 600 is fixed in contact with the inner surface of the sensor cover 400. The fixing plate 600 is installed above the flow fan 530.

Referring to FIGS. 2 and 3, a guide pipe 610 is protruded from the upper surface of the fixing plate 600. The guide pipe 610 is for cleaning the sensor 400 by guiding upward the measurement water inside the sensor cover 400 as the flow fan 530 rotates. Therefore, the fixing plate 600 is installed so that the discharge port of the guide pipe 610 is positioned on a straight line formed along the longitudinal direction of the sensor 300.

2 to 4, the guide tube 610 is formed so as to have a reduced cross-sectional area while going upward. The measuring water flowing upward by the flow fan 530 flows through the guide pipe 610 above the fixing plate 600 and the sectional area decreases while the guide pipe 610 moves upward, The measured water flowing upward through the outlet of the guide pipe 610 has a relatively fast flow rate. Therefore, it is possible to effectively remove foreign matters such as water moss and dust attached to the sensor 300. [

Referring to FIG. 4, a spiral-shaped vortex-forming projection 612 is protruded from the inner circumferential surface of the guide tube 610. The vortex forming protrusion 612 is for generating a vortex in the measurement water passing through the guide tube 610 and injecting the measurement water into the vortex form from the guide tube 610. The measurement water is sprayed in the form of a vortex from the guide pipe 610 to clean the sensor 300, so that the foreign matter adhered to the sensor 300 can be more effectively removed.

FIG. 3 shows a case where four guide pipes 300 are provided. When two sensors 300 are fastened to the sub-body 200, the remaining two guide pipes 610 except for the two guide pipes 610 located on the straight line formed along the longitudinal direction of the two sensors 300 610, the measured water need not be injected. Therefore, in order to selectively mount a shielding plate (not shown) for shielding the outlet of the guide pipe 610, an upper end of each guide pipe 610 is provided with an opening A mounting groove or mounting projection is formed. By shielding the remaining two guide pipes 610 with the shielding plate (not shown), measurement can be performed only through the two guide pipes 610 located on the straight line formed along the length direction of the sensor 300 The flow rate of the measurement water jetted from the guide pipe 610 located below the sensor 300 is relatively increased and the sensor (610) 300 can be more effectively removed.

Although not shown in FIG. 1, a screen mesh (not shown) in the form of a mesh network is installed at the lower open end of the sensor cover 400. The screen (not shown) is to prevent foreign matter having a predetermined size or more from flowing into the sensor cover 400. In the case where the measurement water passes only above the screen (not shown), foreign matter adheres to the outside of the screen (not shown) to shield a part of the screen (not shown). Accordingly, the motor 520 can be selectively operated so as to remove foreign substances adhered to the outside of the screen (not shown) by rotating the flow fan 530 in the reverse direction to flow down the measured water inside the sensor cover 400 So that a reverse driving force can be generated.

100: Main body 200: Sub-body
300: Sensor 400: Sensor cover
510: motor support bar 520: motor
530: Flow fan 600: Fixing plate
610: guide tube 612: vortex forming projection

Claims (6)

delete delete A main body 100 having a cylindrical shape and a sub body 200 sealing the lower end of the main body 100 and fastened to the main body 100 and a sensor fastened to the lower end of the sub body 200 And a sensor cover (400) which surrounds the sensor (300) and is fastened to the sub body (200) to protect the sensor (300)
A flow fan 530 disposed inside the sensor cover 400 so as to be rotatable by the driving force of the motor 520 and a flow rate measuring unit 530 disposed inside the sensor cover 400 as the flow fan 530 rotates, And a guide pipe (610) guided upward to be installed above the flow fan (530) to clean the sensor (300)
The guide tube 610 is configured to have a reduced sectional area while being directed upward,
A spiral-shaped vortex-forming projection 612 is protruded on the inner circumferential surface of the guide tube 610 to form a vortex of the measurement water jetted from the guide tube 610. Water sensor probe.
The method of claim 3,
The guide tube 610 has a circumferential surface protruding from the upper surface of the fixing plate 600, which is in contact with the inner surface of the sensor cover 400,
Wherein the fixing plate (600) is installed such that a discharge port of the guide pipe (610) is positioned on a straight line formed along the longitudinal direction of the sensor (300).
5. The method of claim 4,
A mounting groove or mounting protrusion for mounting the shielding plate is formed on the upper end of the guide pipe 610 so that a shielding plate for shielding the outlet of the guide pipe 610 can be selectively mounted. Sensor Water sensor probe with self-cleaning function.
The method of claim 3,
A mesh screen screen is installed at the lower end of the sensor cover 400,
Wherein the rotation axis of the motor (520) is selectively forwardly and reversely rotatable.

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