KR20190011439A - Apparatus for contamination monitoring for quartz tube of UV irradiative reactor - Google Patents

Abstract

The present invention relates to an apparatus for measuring a pollution level of a quartz tube of an UV disinfection device that can measure UV transmittance in a UV reactor to determine the pollution level of the quartz tube based on the measured UV transmittance and thus accurately monitor the pollution level. The apparatus of the present invention includes a UV lamp provided in the UV reactor; a quartz tube configured to enclose the UV lamp; first and second UV intensity measuring sensors provided in the UV reactor, of which a distance spaced apart from the UV lamp is different from each other; and a control unit for calculating a ratio of a first UV intensity measured by the first UV intensity measuring sensor and a second UV intensity measured by the second UV intensity measuring sensor, and comparing the calculated ratio with a reference transmittance, thereby determining the pollution of the quartz tube.

Description

[0001] The present invention relates to a quartz tube pollution measuring apparatus for an ultraviolet disinfection apparatus,

The present invention relates to an apparatus for measuring the degree of contamination of a quartz tube in an ultraviolet ray sterilizing apparatus, and more particularly, to an apparatus for measuring a degree of contamination of a quartz tube by measuring ultraviolet ray transmittance in the ultraviolet ray bath, To a quartz pipe pollution measuring device of a disinfecting device.

Sterilization process using ultraviolet rays is applied in various water treatment processes such as sewage treatment process and equilibrium water treatment process. The ultraviolet sterilization process utilizes the principle of preventing ultraviolet rays generated from ultraviolet lamps from being absorbed by microorganisms and destroying the DNA of microorganisms, thereby preventing the growth and propagation of microorganisms.

The ultraviolet disinfection apparatus for ultraviolet disinfection process comprises a reaction tank 110 in which an ultraviolet sterilization process is performed and an ultraviolet lamp 120 provided in a reaction tank 110 to emit ultraviolet rays, And is protected by the tube 130 (see FIG. 1). The reference numeral 140 denotes an ultraviolet intensity measuring sensor.

The transparency of the quartz tube must be ensured in order to maintain the sterilization efficiency by the ultraviolet rays constantly. When the ultraviolet rays generated from the ultraviolet lamp are interfered with by the quartz tube, the sterilization efficiency by ultraviolet rays is lowered. Therefore, the transparency of the quartz tube should be maintained above a certain level, and the quartz tube must be cleaned.

On the other hand, in the conventional case, the method of cleaning the quartz tube by visually checking the contamination degree of the quartz tube is adopted. However, as the contamination degree of the quartz tube is not accurately grasped and the washing is progressed at an arbitrary point, It is not effective in optimizing the efficiency.

Korean Patent Laid-Open No. 10-2011-0118068

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an ultraviolet sterilization apparatus capable of accurately measuring the degree of contamination of a quartz tube by measuring UV transmittance in the UV- And a measuring device.

In order to accomplish the above object, according to the present invention, there is provided an apparatus for measuring the contamination degree of a quartz tube in an ultraviolet sterilizing apparatus, comprising: an ultraviolet ray reactor providing a space in which an ultraviolet sterilization reaction proceeds; An ultraviolet lamp provided in the ultraviolet ray reactor; A quartz tube enclosing the ultraviolet lamp; A first ultraviolet intensity measuring sensor and a second ultraviolet intensity measuring sensor provided in the ultraviolet ray reactor and having different distances from the ultraviolet lamp; And a ratio (I ₂ / I ₁ ) of the first ultraviolet ray intensity I ₁ measured by the first ultraviolet ray intensity measuring sensor to the second ultraviolet ray intensity I ₂ measured by the second ultraviolet ray intensity measuring sensor And control means for determining whether the quartz tube is contaminated by comparing the calculated I ₂ / I ₁ with a reference transmittance.

The first ultraviolet ray intensity measuring sensor is provided at a position close to the ultraviolet ray lamp relative to the second ultraviolet ray intensity measuring sensor. In addition, two insertion ports are provided on the inner wall of the ultraviolet ray reactor, and a first ultraviolet ray intensity measuring sensor and a second ultraviolet ray intensity measuring sensor are disposed at the respective insertion ports.

The control means determines that the quartz tube is contaminated if the calculated I ₂ / I ₁ is smaller than the reference transmittance.

The apparatus for measuring the contamination degree of quartz pipe in the ultraviolet sterilizing apparatus according to the present invention has the following effects.

It is possible to easily determine whether or not the quartz tube is contaminated by measuring ultraviolet light intensities through two ultraviolet intensity measuring sensors located at different distances from the ultraviolet lamp and judging whether the ratio thereof satisfies the reference transmittance.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram of an ultraviolet disinfecting apparatus according to the prior art.
FIG. 2 is a schematic view of an apparatus for measuring the contamination level of quartz pipe in an ultraviolet sterilizing apparatus according to an embodiment of the present invention. FIG.
3 is a flowchart for explaining a method of measuring a contamination degree of quartz pipe in an ultraviolet sterilizing apparatus according to an embodiment of the present invention.

The present invention provides a technique for determining the contamination of a quartz tube by measuring ultraviolet transmittance in an ultraviolet ray reactor.

Since only a single ultraviolet ray intensity measuring sensor capable of measuring ultraviolet ray transmittance is present in a normal water treatment ultraviolet ray reaction tank, ultraviolet ray measuring intensity may be low due to contamination of the quartz tube even though the ultraviolet ray transmittance of seawater is high. For this reason, it is not possible to directly measure the pollution degree of the quartz tube excluding the ultraviolet transmittance of the seawater. On the other hand, the germicidal effect by ultraviolet rays is closely related to the ultraviolet transmittance in the ultraviolet ray reaction tank.

Therefore, in order to increase the germicidal effect by ultraviolet rays, it is necessary to maintain the ultraviolet ray transmittance in the ultraviolet ray reactor at a certain level or more. One of the conditions for raising the ultraviolet ray transmittance to a certain level or more is to clean the quartz tube .

In the present invention, the UV intensity ratio is calculated by using two ultraviolet intensity measuring sensors located at different distances from the ultraviolet lamp, and the ultraviolet ray intensity ratio, that is, the ultraviolet ray transmittance Is judged whether or not the quartz tube is contaminated by judging whether or not the quartz tube satisfies a predetermined reference value, and the quartz tube is cleaned accordingly.

Hereinafter, an apparatus for measuring the pollution degree of quartz pipe in an ultraviolet sterilizing apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

Referring to FIG. 2, an apparatus for measuring the contamination degree of quartz tube in an ultraviolet sterilizing apparatus according to an embodiment of the present invention includes an ultraviolet ray reaction tank 210. The ultraviolet ray reaction tank 210 provides a space in which the ultraviolet sterilization reaction proceeds as the microorganisms contained in the raw water are sterilized by ultraviolet rays. Although not shown in the drawing, the raw water flows from one side of the ultraviolet ray reactor 210, and the ultraviolet ray sterilization reaction water is discharged through the other side of the ultraviolet ray reactor 210.

An ultraviolet lamp 220 for irradiating ultraviolet rays is provided in the ultraviolet ray reaction tank 210. The ultraviolet lamp 220 may emit ultraviolet rays of various wavelengths capable of sterilizing microorganisms, and one or more ultraviolet lamps 220 may be disposed in the ultraviolet ray reaction tank 210.

A quartz tube (230) is provided around the ultraviolet lamp (220). The quartz tube 230 protects the ultraviolet lamp 220 from the external environment and transmits ultraviolet rays emitted from the ultraviolet lamp 220. The transparency of the quartz tube 230 must be maintained at a certain level or more in order for ultraviolet rays of the ultraviolet lamp 220 to be irradiated without interfering with the ultraviolet ray reaction tank 210.

In the ultraviolet ray reaction tank 210, two ultraviolet ray intensity measuring sensors are provided. The ultraviolet intensity measuring sensor serves to measure the intensity (UV intensity) of the ultraviolet light irradiated by the ultraviolet lamp 220. The two ultraviolet ray intensity measuring sensors are provided at different positions from the ultraviolet ray lamp 220. The first ultraviolet ray intensity measuring sensor 241 is disposed at a position separated from the ultraviolet ray lamp 220 by a first distance L ₁ and the second ultraviolet ray intensity measuring sensor 242 is disposed at a position spaced apart from the ultraviolet ray lamp 220 by a first distance L ₁ , is provided at a position spaced apart (L _2), the first distance (L ₁₎ is smaller than the second distance _{(L 2) (L 1 <} L 2). At this time, the first ultraviolet ray intensity measuring sensor 241 and the second ultraviolet ray intensity measuring sensor 242 may be located anywhere in the ultraviolet ray reactor 210 if they satisfy the above-mentioned distance condition, 210, respectively. In this case, the ultraviolet ray intensity measuring sensor 241 and the second ultraviolet ray intensity measuring sensor 242 may be disposed on the inner wall of the ultraviolet ray reaction tank 210, respectively.

The first ultraviolet intensity measuring sensor 241 and the second ultraviolet intensity measuring sensor 242 are located at different distances from the ultraviolet lamp 220 and the first ultraviolet intensity measuring sensor 241 is located at a different distance from the second ultraviolet intensity measuring sensor 242 The first ultraviolet light intensity I ₁ measured by the first ultraviolet light intensity measuring sensor 241 is measured by the second ultraviolet light intensity measuring sensor 242 as the first ultraviolet light intensity I ₁ measured by the first ultraviolet light intensity measuring sensor 241 is positioned relatively closer to the ultraviolet lamp 220 Is greater than the second ultraviolet intensity (I ₂ ) (I ₁ > I ₂ ).

In view of the above, the present invention measures the first ultraviolet ray intensity I ₁ and the second ultraviolet ray intensity I ₂ through two ultraviolet ray intensity measuring sensors located at different distances, and measures the first ultraviolet ray intensity I ₁ ) and the second ultraviolet intensity (I ₂ ) is calculated, and this value is estimated as ultraviolet ray transmittance (UVT, UV transmittance). The calculated ultraviolet ray transmittance is compared with a predetermined reference transmittance, The degree of contamination of the quartz tube 230 is determined.

The ratio of the first ultraviolet ray intensity I ₁ and the second ultraviolet ray intensity I _{2 is} calculated through the first ultraviolet ray intensity I ₁ and the second ultraviolet ray intensity I ₂ measured, The control unit 250 may further include a determination unit that determines whether a ratio between the first ultraviolet intensity I ₁ and the second ultraviolet intensity I ₂ satisfies a preset reference transmittance. The control unit 250 receives the first ultraviolet intensity I ₁ and the second ultraviolet intensity I ₂ from the first ultraviolet intensity measuring sensor 241 and the second ultraviolet intensity measuring sensor 242, And calculates the ratio of the ultraviolet ray intensity I ₁ to the second ultraviolet ray intensity I ₂ and determines whether the calculated value satisfies the reference transmittance.

The method for measuring the degree of contamination of the quartz tube 230 of the ultraviolet sterilizing apparatus according to an embodiment of the present invention will be described in detail as follows.

3, the first ultraviolet light intensity measuring sensor 241 is disposed at a position spaced apart from the ultraviolet lamp 220 by a first distance L ₁ and the second ultraviolet light intensity measuring sensor 241 is disposed at a second distance L ₁ from the ultraviolet lamp 220. L ₂ ) (L ₁ < L ₂ ) (S 301).

When the ultraviolet light is irradiated from the ultraviolet lamp 220 in a state where the first ultraviolet ray intensity measuring sensor 241 and the second ultraviolet ray intensity measuring sensor 242 are disposed, the first ultraviolet ray intensity measuring sensor 241 detects the first ultraviolet ray intensity I ₁ ), and the second ultraviolet intensity measuring sensor 242 measures the second ultraviolet intensity I ₂ . The first ultraviolet ray intensity measuring sensor 241 is provided at a position close to the ultraviolet ray lamp 220 relative to the second ultraviolet ray intensity measuring sensor 242 so that the first ultraviolet ray intensity I ₁ is higher than the second ultraviolet ray intensity I ₁ I ₂ ) (I ₁ > I ₂ ).

When the first ultraviolet light intensity I ₁ and the second ultraviolet light intensity I ₂ are measured, the ratio of the first ultraviolet light intensity I ₁ to the second ultraviolet light intensity I ₂ is calculated and the first ultraviolet light intensity I ₁ ) and the second ultraviolet ray intensity I ₂ is regarded as ultraviolet ray transmittance (UVT, UV transmittance) (S302).

(Equation 1)

Ultraviolet ray transmittance (UVT) = second ultraviolet ray intensity (I ₂ ) / first ultraviolet ray intensity (I ₁ )

The difference between the first ultraviolet ray intensity I ₁ and the second ultraviolet ray intensity I ₂ will not be great if the ultraviolet ray transmission environment in the ultraviolet ray reaction tank 210 is excellent or the ultraviolet ray transmittance is high. If the ultraviolet transmittance is low, the difference between the first ultraviolet ray intensity I ₁ and the second ultraviolet ray intensity I ₂ will be relatively large.

In view of the above, the present invention regards the ratio of the first ultraviolet ray intensity I ₁ to the second ultraviolet ray intensity I ₂ as ultraviolet ray transmittance. The ultraviolet ray transmitting environment in the ultraviolet ray reactor 210 is determined based on whether the calculated ratio of the first ultraviolet ray intensity I ₁ to the second ultraviolet ray intensity I ₂ satisfies a preset reference transmittance range. For example, if the ratio of the first ultraviolet ray intensity I ₁ to the second ultraviolet ray intensity I ₂ is smaller than the reference transmittance, it means that the ultraviolet ray transmittance is low, and the first ultraviolet ray intensity I ₁ and the second ultraviolet ray intensity I 2 I ₂ ) is greater than or equal to the reference transmittance range, it means that the ultraviolet transmittance is high.

If the ratio of the first ultraviolet ray intensity I ₁ to the second ultraviolet ray intensity I ₂ is smaller than the reference transmittance, it means that the ultraviolet ray transmittance is low, and it can be judged that the quartz tube 230 is contaminated (S 303 ).

The control means 250 stores the preset reference transmittance from the first ultraviolet intensity measuring sensor 241 and the second ultraviolet intensity measuring sensor 242 to the first ultraviolet intensity measuring sensor 241 and the second ultraviolet intensity measuring sensor 242, I _1), the second whether by receiving the ultraviolet intensity (I ₂₎ the first UV intensity (I ₁₎ and the second is the value calculated with the also calculated the ratio of the UV intensity (I ₂₎ satisfies the standard transmission rate If it is determined that the ratio of the first ultraviolet ray intensity I ₁ to the second ultraviolet ray intensity I ₂ is smaller than the reference transmittance, it can be judged that the quartz tube 230 is contaminated.

210: ultraviolet ray reaction tank 220: ultraviolet lamp
230: quartz tube 241: first ultraviolet intensity measuring sensor
242: second ultraviolet intensity measuring sensor 250: control means

Claims (4)

An ultraviolet reactor for providing a space where an ultraviolet sterilization reaction proceeds;
An ultraviolet lamp provided in the ultraviolet ray reactor;
A quartz tube enclosing the ultraviolet lamp;
A first ultraviolet intensity measuring sensor and a second ultraviolet intensity measuring sensor provided in the ultraviolet ray reactor and having different distances from the ultraviolet lamp; And
The ratio (I ₂ / I ₁ ) of the first ultraviolet ray intensity I ₁ measured by the first ultraviolet ray intensity measuring sensor to the second ultraviolet ray intensity I ₂ measured by the second ultraviolet ray intensity measuring sensor is calculated, And a control means for judging whether the quartz tube is contaminated by comparing the calculated I ₂ / I ₁ with a reference transmittance.
The apparatus according to claim 1, wherein the first ultraviolet ray intensity measuring sensor is disposed at a position close to the ultraviolet ray lamp relative to the second ultraviolet ray intensity measuring sensor.
2. The ultraviolet sterilization apparatus according to claim 1, wherein the ultraviolet ray reactor is provided with two insertion ports on its inner wall, and a first ultraviolet ray intensity measuring sensor and a second ultraviolet ray intensity measuring sensor are disposed at the respective insertion ports. Measuring device.
The apparatus according to claim 1, wherein the control unit determines that the quartz tube is contaminated when the calculated I ₂ / I ₁ is smaller than the reference transmittance.

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