KR102308875B1 - Probe for Particle Measurement - Google Patents

Abstract

Disclosed is a probe for measuring particles. The present invention includes: an air injection port which injects air to a particle measurement target surface; an air suction port which sucks in air containing particles separated from the particle measurement target surface; and a distance measuring unit which measures a separation distance to the particle measurement target surface. According to the present invention, the air injection and air suction of the probe for measuring particles are performed in a state in which the probe for measuring particles and a measurement target surface form a constant separation distance, and thus the accuracy of particle measurement can be greatly improved.

Description

Probe for Particle Measurement

The present invention relates to a particle measuring probe, and more particularly, the accuracy of particle measurement as the particle measuring probe is sprayed and air sucked in a state in which the particle measuring probe and the measuring target surface form a constant separation distance. It relates to a probe for measuring particles that can significantly increase .

In general, the particle counter sucks air containing particles separated from the measurement target surface by the air sprayed to the measurement target surface through a particle measurement probe, and then counts the number of particles contained in the sucked air. works with

On the other hand, for accurate measurement of particles, air injection and air suction of the particle measurement probe must be performed while the separation distance from the measurement target surface of the particle measurement probe is kept constant, but the particle measurement probe according to the prior art There was a technical limitation in that there is no means for maintaining a constant separation distance from the measurement target surface.

Accordingly, it is an object of the present invention to greatly increase the accuracy of particle measurement as the particle measurement probe and the particle measurement probe perform air injection and air suction in a state where a predetermined distance is formed between the probe and the measurement target surface. To provide a probe for measurement.

The probe for particle measurement according to the present invention for achieving the above object includes: an air injection hole for spraying air to a particle measurement target surface; an air inlet for sucking air containing particles separated from the particle measurement target surface; and a distance measuring unit measuring a separation distance to the particle measurement target surface.

Preferably, it further comprises a sterilization lamp for irradiating sterilization light to the particle measurement target surface.

In addition, when the separation distance measured by the distance measuring unit coincides with a predetermined reference distance, it is characterized in that the air injection through the air injection hole is started.

According to the present invention, it is possible to greatly increase the accuracy of particle measurement as the particle measurement probe and the particle measurement probe perform air injection and air suction in a state where a predetermined separation distance is formed between the probe and the measurement target surface.

1 is a view showing the structure of a particle measuring probe provided in a particle measuring device according to an embodiment of the present invention;
2 is a configuration diagram illustrating the principle of operation of a particle measuring device according to an embodiment of the present invention;
3 is a functional block diagram showing the structure of a particle counter according to an embodiment of the present invention; and
4 is a flowchart illustrating an operation process of a particle measuring device according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. It should be noted that the same components in the drawings are denoted by the same reference numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted.

1 is a diagram illustrating a structure of a particle measuring probe provided in a particle measuring device according to an embodiment of the present invention. Referring to FIG. 1 , in the particle measurement probe 100 according to an embodiment of the present invention, the measurement end surface facing the particle measurement target surface has an air injection port 110 , an air intake port 130 , and a distance measurement unit ( 150), and a germicidal lamp 170 is provided.

A plurality of air injection holes 110 are formed on the end surface along the circumferential direction of the circular end surface of the particle measurement probe 100, and the air supplied from the air pump 500 to the particle measurement probe 100 is air. By being sprayed on the measurement target surface through the injection hole 110, the particles are separated from the measurement target surface.

The air suction port 130 is formed in the center of the circular end of the particle measurement probe 100, and the suction pressure of the air pump 500 connected to the particle measurement probe 100 is applied to the air suction port 130. Accordingly, the air including the particles separated from the measurement target surface is sucked through the air inlet 130 .

The distance measuring unit 150 including a distance measuring sensor such as an ultrasonic sensor and an infrared sensor installed on the measuring end surface of the particle measuring probe 100 is a particle measuring target surface from the end face of the particle measuring probe 100 . Measure the separation distance to

The sterilization lamp 170 may be an ultraviolet lamp that irradiates ultraviolet rays to the measurement target surface while installed on the measurement end surface of the particle measurement probe 100, and such a sterilization lamp 170 is the measurement target surface before particle measurement. It enables more accurate particle measurement by sterilizing the

2 is a configuration diagram illustrating an operating principle of a particle measuring device according to an embodiment of the present invention. Referring to FIG. 2 , a particle measuring device according to an embodiment of the present invention includes a particle measuring probe 100 , a particle counter 200 , a first flow rate controller 300 , a second flow rate controller 400 , and an air pump. 500 , and a filter unit 600 .

The particle measurement probe 100 includes an exhaust passage that is a passage for supplying air supplied from the air pump 500 to the particle measurement probe 100 , and air containing particles sucked by the particle measurement probe 100 . Intake flow passages that are flow passages for transporting the particles to the particle counter 200 are connected to each other.

Meanwhile, in practicing the present invention, the particle counter 200 may measure the concentration of particles by counting the particles included in the air sucked in by the particle measuring probe 100 through a light scattering method or the like.

In addition, in carrying out the present invention, the particle counter 200 may be provided integrally with the particle measuring device according to an embodiment of the present invention, or may be separately connected and installed outside the particle measuring device.

The first flow controller 300 is installed on the exhaust passage, which is a passage for supplying the air injected to the measurement target surface through the particle measurement probe 100 to the particle measurement probe 100, such a first flow controller Reference numeral 300 controls the air supply flow rate from the air pump 500 to the particle measurement probe 100 (ie, the air injection flow rate from the particle measurement probe 100 to the measurement target surface).

On the other hand, the second flow controller 400 is installed on a branch flow path that is a flow path branched from an intake flow path that is a flow path for supplying the air sucked by the particle measurement probe 100 to the particle counter 200 , The flow controller 400 controls the flow rate of the air that is not introduced into the particle counter 200 by controlling the flow rate in the branch flow path by controlling the flow rate of the air that is not introduced into the particle counter 200 by flowing into the branch flow path among the air sucked by the particle measurement probe 100 for particle measurement. Regardless of the amount of air sucked by the probe 100 , only a constant amount of air (eg, 1 CFM [Cubic Feet per Minute]) is always supplied to the particle counter 200 .

Specifically, the particle counter 200 sets the set value for the amount of air supplied to the particle measurement probe 100 through the first flow controller 300 and the amount of air per unit time to be introduced into the particle counter 200 . Control the operation of the first flow controller 300 and the second flow controller 400 based on the value (eg, 1 CFM).

On the other hand, as shown in FIG. 2 , the start end of the exhaust passage is connected to the discharge port of the air pump 500 , and the particle measurement probe 100 is connected to the end of the exhaust passage, and the start end of the intake passage is connected. A particle measuring probe 100 is connected and installed, and the suction port of the air pump 500 is connected and installed at the end of the intake flow path.

On the other hand, the branch flow path branches from the intake flow path near the start end of the intake flow path, and merges with the intake flow path near the end end of the intake flow path.

In addition, the particle measuring device according to the present invention forms an air circulation structure in which the flow rate of air supplied to the exhaust passage through the discharge port of the air pump 500 and the air flow rate sucked from the intake passage through the inlet of the air pump 500 are the same. will do

The filter unit 600 is installed on the exhaust passage as shown in FIG. 2 to filter and remove various particles such as foreign substances from the air transferred through the exhaust passage, and the air injected from the particle measurement probe 100 to the measurement target surface. It enables more accurate particle measurement by not including particles. Meanwhile, such a filter unit 600 may include a HEPA filter.

3 is a functional block diagram illustrating the structure of a particle counter according to an embodiment of the present invention. Referring to FIG. 3 , the particle counter 200 according to an embodiment of the present invention includes an input unit 210 , a control unit 230 , a display unit 250 , and a communication unit 270 .

In the input unit 210 of the particle counter 200 , the set value for the reference separation distance from the measurement target surface of the measurement end of the particle measurement probe 100 , the particle measurement probe 100 through the first flow controller 300 . ), various set values determined by the user for the operation of the particle measurement equipment, such as the set value for the air supply flow rate to ), and the set value for the air supply flow rate supplied from the particle measurement probe 100 to the particle counter 200 are input do. Such an input unit 210 may include a touch-type display device.

The control unit 230 of the particle counter 200 is the air pump 500, the first flow rate controller 300 and the second flow rate based on the various set values as described above for the particle measuring equipment input through the input unit 210. Controls the operation of the controller 400 .

The display unit 250 such as the display device displays information on the separation distance to the measurement target surface measured by the distance measurement unit 150 provided in the particle measurement probe 100 and the particle counting value measured by the particle counter 200 . do.

On the other hand, the communication unit 270 of the particle counter 200 receives the separation distance information from the distance measurement unit 150 to the measurement target surface measured by the distance measurement unit 150 provided in the particle measurement probe 100, and , it may be possible to receive from the user terminal the various setting value information as described above that the user input into the user terminal such as a smart phone.

In this case, the control unit 230 of the particle counter 200 may control the operation of the particle measuring device based on the setting value received from the user terminal.

In addition, in carrying out the present invention, the communication unit 270 of the particle counter 200 includes the separation distance information from the distance measuring unit 150 of the particle measuring probe 100 to the measurement target surface, and the particle counter ( 200) may transmit the measured particle counting value to the user terminal.

4 is a flowchart illustrating an operation process of a particle measuring device according to an embodiment of the present invention. Hereinafter, an operation process of the particle measuring device according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4 .

First, the user refers to the user's manual of the particle measuring equipment, and the set value (for example, 5 cm) for the reference separation distance between the measurement end of the particle measurement probe 100 for accurate measurement of particles and the measurement target surface. It may be input through the input unit 210 of the particle counter 200 (S710).

In addition, the user has a first flow rate set value (eg, 2CFM), which is a set value for the air supply flow rate to the particle measurement probe 100 through the first flow controller 300 , and the particle measurement probe 100 . A second flow rate set value (eg, 1 CFM), which is a set value for the air supply flow rate supplied to the particle counter 200 from the , may be input through the input unit 210 of the particle counter 200 (S720) .

Thereafter, as the user approaches the measuring end of the particle measuring probe 100 to the measurement target surface while holding the particle measuring probe 100 by hand, a distance measuring unit provided in the particle measuring probe 100 ( 150 measures the separation distance between the measurement end of the particle measurement probe 100 and the measurement target surface, and transmits the measured separation distance information to the communication unit 270 of the particle counter 200 (S730).

On the other hand, in implementing the present invention, the separation distance information received by the communication unit 270 of the particle counter 200 may be displayed through the display unit 250 of the particle counter 200, whereby the user can display the separation distance information. By checking through the display unit 250, the accuracy of particle measurement is improved as the particle measurement probe 100 can be operated so that the separation distance between the measurement end of the particle measurement probe 100 and the measurement target surface is kept constant. can be raised

In addition, the control unit 230 of the particle counter 200 determines whether the separation distance value received from the particle measurement probe 100 matches the reference separation distance value set in step S710 described above (S740), and both If they match, it will be possible to start the operation of the particle measuring equipment by driving the air pump 500 (S750).

As described above, according to the present invention, as the particle measurement is performed in a state where the measurement end of the particle measurement probe 100 and the measurement target surface form a predetermined reference separation distance, it is possible to increase the accuracy of particle measurement.

As the operation of the particle measuring equipment is started in step S750 described above, the control unit 230 of the particle counter 200 controls the first flow controller 300 to control the first flow rate set value (eg, in step S720). For example, a supply flow rate according to 2CFM) is supplied to the particle measurement probe 100 through the first flow rate controller 300 ( S760 ).

In addition, the control unit 230 of the particle counter 200 may be configured such that the supply flow rate according to the second flow rate set value (eg, 1CFM) in the above-described step S720 may be supplied to the particle counter 200 , the second By controlling the flow rate controller 400, a flow rate equal to the difference between the first flow rate set value (eg, 2 CFM) and the second flow rate set value (eg, 1 CFM) to a branch flow path that is a flow path branched from the intake flow path (eg 2CFM-1CFM) is allowed to flow in.

Accordingly, the particle counter 200 measures the particles included in the air supplied from the particle measurement probe 100 according to the second flow rate set value (eg, 1 CFM) in step S720 described above (S780). .

As described above, according to the present invention, for accurate measurement of particles on the measurement target surface, even when the particle measurement probe 100 increases the air flow rate sprayed to the measurement target surface so as to minimize particles that are not separated from the measurement target surface , since only a constant amount of air (eg, 1 CFM) is always supplied to the particle counter 200, the accuracy of particle measurement can be greatly improved.

Meanwhile, in practicing the present invention, the structure and operation principle of the particle sampling device in Korean Patent No. 1149443 may be applied to the particle counter 200 according to the present invention, and thus, the patent of Korean Patent No. 1149443 The content contained in the publication forms a part of this specification.

Terms used in the present invention are only used to describe specific embodiments and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

In the above, preferred embodiments and applications of the present invention have been shown and described, but the present invention is not limited to the specific embodiments and applications described above, and the present invention is not limited to the scope of the present invention as claimed in the claims. Various modifications may be made by those skilled in the art to which this belongs, of course, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

100: particle measurement probe, 110: air nozzle,
130: air intake, 150: distance measurement unit,
170: germicidal lamp, 200: particle counter,
210: input unit, 230: control unit,
250: display unit, 270: communication unit,
300: a first flow controller, 400: a second flow controller;
500: an air pump, 600: a filter unit.

Claims (3)

Air injection port 110 for injecting air to the particle measurement target surface;
an air suction port 130 for sucking air containing particles separated from the particle measurement target surface; and
a distance measurement unit 150 for measuring a separation distance to the particle measurement target surface;
includes,
When the separation distance measured by the distance measuring unit 150 matches a predetermined reference distance, the air injection through the air injection hole 110 is started.
According to claim 1,
Particle measurement probe further comprising a sterilization lamp 170 for irradiating sterilization light to the particle measurement target surface.
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