KR102564301B1 - Apparatus for measuring damage of filter and measuring method using the same - Google Patents

Abstract

The present invention relates to a filter breakage measuring device and a filter breakage measuring method using the same. Specifically, according to one embodiment of the present invention, a virtual horizontal area is formed at a point spaced upward by a predetermined distance from the outlet so that the outlet of the plurality of bag filters through which dust-containing air is discharged is disposed inside, a frame in which a plurality of virtual grids are formed at positions corresponding to outlets of the plurality of bag filters in the region, and formed to surround the region; A plurality of first irradiation units disposed on one of the horizontally extending side surfaces of the frame so that light is irradiated to the plurality of grids in a vertical direction, and one of the frames so that light is irradiated to the plurality of grids in a horizontal direction. A plurality of second irradiation units disposed on a side surface extending in the vertical direction of and a third disposed at the corner of the frame between the first and second irradiation units so that light is radiated in an oblique direction to a grid on a diagonal in the area. An irradiation unit including an irradiation unit; The other side of the frame, opposite to the position where the first irradiation unit, the second irradiation unit, and the third irradiation unit are disposed so that the light irradiated from the first irradiation unit, the second irradiation unit, and the third irradiation unit of the irradiation unit is received. Includes a plurality of first receiving units disposed on a side extending in the direction, a plurality of second receiving units disposed on a side extending in another longitudinal direction of the frame, and a third receiving unit disposed at a corner in a diagonal direction of the corner a receiving unit that; a measuring unit analyzing the light received by the receiving unit and measuring a concentration value of dust in the air discharged through the outlet of each of the plurality of bag filters; and a reading unit which compares the concentration value of the dust measured by the measurement unit with a preset threshold concentration value to determine a position of a bag filter from which dust exceeding the preset threshold concentration value is discharged from among the plurality of bag filters. Including, a filter breakage measuring device and a filter breakage measuring method using the same can be provided.

Description

Filter damage measuring device and filter damage measuring method using the same {APPARATUS FOR MEASURING DAMAGE OF FILTER AND MEASURING METHOD USING THE SAME}

The present invention relates to a filter breakage measuring device and a filter breakage measuring method using the same.

A bag filter through which air containing dust passes is provided inside a bag filter used to remove and discharge dust in a factory or the like. Air passing through the above bag filter contains not only dust but also embers, and thus the bag filter may be damaged during the air filtering process. If the bag filter is damaged, dust is not removed, it is difficult to determine which of the plurality of bag filters is damaged, and since all bag filters inside the bag filter must be replaced, problems such as cost and delay in the process occur.

A general bag filter damage measuring device seals the upper part of the bag filter and blows compressed air into the lower part to measure the pressure, and determines whether the bag filter is damaged or not based on the measured pressure value. However, in the pressure measurement method as described above, it is difficult to determine the degree of damage to the bag filter due to the large deviation in the measured value, and since the above pressure measurement must be performed for all of the plurality of bag filters, the replacement time and replacement cost of the bag filter are delayed. problems such as increase.

One embodiment of the present invention was invented in view of the above background, and determines whether or not dust is generated for all of the plurality of bag filters, the concentration value of the above dust, and a threshold value in a specific bag filter at any position among the plurality of bag filters. It is intended to provide a filter damage measuring device and a filter damage measuring method using the device that can determine whether excessive dust is discharged.

According to one aspect of the present invention, a virtual horizontal area is formed at a point spaced apart from the outlet by a predetermined distance upward from the outlet so that the outlet of the plurality of bag filters through which air containing dust is discharged is disposed inside, and within the area a plurality of virtual lattices are formed at positions corresponding to the outlets of the plurality of bag filters, and a frame formed to surround the area; A plurality of first irradiation units disposed on one of the horizontally extending side surfaces of the frame so that light is irradiated to the plurality of grids in a vertical direction, and one of the frames so that light is irradiated to the plurality of grids in a horizontal direction. A plurality of second irradiation units disposed on a side surface extending in the vertical direction of and a third disposed at the corner of the frame between the first and second irradiation units so that light is radiated in an oblique direction to a grid on a diagonal in the area. An irradiation unit including an irradiation unit; The other side of the frame, opposite to the position where the first irradiation unit, the second irradiation unit, and the third irradiation unit are disposed so that the light irradiated from the first irradiation unit, the second irradiation unit, and the third irradiation unit of the irradiation unit is received. Includes a plurality of first receiving units disposed on a side extending in the direction, a plurality of second receiving units disposed on a side extending in another longitudinal direction of the frame, and a third receiving unit disposed at a corner in a diagonal direction of the corner a receiving unit that; a measuring unit analyzing the light received by the receiving unit and measuring a concentration value of dust in the air discharged through the outlet of each of the plurality of bag filters; and a reading unit which compares the concentration value of the dust measured by the measurement unit with a preset threshold concentration value to determine a position of a bag filter from which dust exceeding the preset threshold concentration value is discharged from among the plurality of bag filters. Including, a filter breakage measuring device may be provided.

In addition, the irradiation unit further includes a plurality of first divided irradiation members and a plurality of second divided irradiation members, and the receiving unit further includes a plurality of first divided receiving members and a plurality of second divided receiving members. The number of first divided irradiation members is disposed in front of the first irradiation unit so that light irradiated from the first irradiation unit in the vertical direction is divided into vertical and oblique directions, and a plurality of second divided irradiation members The light irradiated in the horizontal direction from the second irradiation unit is disposed in front of the second irradiation unit so that the light is divided into the horizontal direction and the oblique direction, and the plurality of first split receiving members are disposed in front of the second irradiation unit to divide the light into the horizontal direction and the oblique direction. The light traveling in an oblique direction or the light traveling in the vertical direction from the first divided irradiation member is disposed in front of the first receiving unit so that the light traveling in the vertical direction is received by the first receiving unit, and the plurality of second divided receiving members are arranged in the first receiving unit. Filter breakage measurement disposed in front of the second receiving unit so that the light traveling in the oblique direction from the first divided irradiation member or the light traveling in the horizontal direction from the second divided irradiation member is received by the second receiving unit. A device may be provided.

In addition, the third irradiation unit irradiates a plurality of oblique directions of light at different angles to the region, and the light emitted from the third irradiation unit in the vertical direction or the light irradiated from the first irradiation unit in the vertical direction is received. a plurality of first divided receiving members disposed in front of the first receiving unit; and a plurality of second split-receiving members disposed in front of the second receiving unit to receive the light irradiated in the horizontal direction from the third irradiation unit or the light irradiated in the horizontal direction from the second irradiation unit. A device may be provided.

In addition, a filter failure measuring device further comprising a control unit, wherein the control unit controls the irradiation unit so that the first irradiation unit, the second irradiation unit, and the third irradiation unit are operated in a predetermined order. can

In addition, a filter breakage measuring device may be provided, further comprising a calculation unit, wherein the calculation unit converts the concentration value of the dust measured by the measurement unit into a graph and derives it.

The remote management unit may further include a remote management unit configured to transmit the concentration value of the dust measured by the measurement unit and the position of the bag filter determined by the reading unit to a management server. A device may be provided.

In addition, in the filter breakage measuring method using the filter breakage measuring device, the irradiation unit is spaced upward by a predetermined distance from the outlet so that the outlet of a plurality of bag filters through which dust-containing air is discharged is disposed inside. An irradiation step of irradiating light in vertical, horizontal and oblique directions to a virtual horizontal area formed at a point; a receiving step of receiving the irradiated light by the receiving unit; a measuring step of measuring, by the measuring unit, a concentration value of dust in the air discharged through an outlet of each of the plurality of bag filters by analyzing the received light; and comparing the concentration value of the dust measured by the measuring unit with a preset threshold concentration value by the read unit, and a position of a bag filter from which dust exceeding the preset threshold concentration value is discharged from among the plurality of bag filters. A filter breakage measuring method comprising a reading step of determining can be provided.

In addition, the irradiation step further includes a control step of controlling the irradiation unit so that the first irradiation unit, the second irradiation unit, and the third irradiation unit are operated in a predetermined order by the control unit. method can be provided.

In addition, the measuring step may further include a calculating step of converting the concentration value of the dust measured from the measuring unit into a graph by the calculating unit and deriving it, the filter damage measuring method may be provided.

One embodiment of the present invention has the effect of determining whether or not dust is generated for all of a plurality of bag filters and the concentration value of the above dust.

In addition, there is an effect of determining whether dust exceeding a threshold value is discharged from a specific bag filter at any position among a plurality of bag filters.

In addition, by replacing only a specific bag filter from which dust exceeding a threshold value is discharged, there is an effect of saving replacement time and replacement cost of the bag filter.

1 is a perspective view of a filter breakage measuring device according to a first embodiment of the present invention.
2 is a diagram showing the configuration of a filter breakage measuring device according to a first embodiment of the present invention.
3 is a view of an operating state of the filter breakage measuring device according to the first embodiment of the present invention viewed from the top.
4 is a diagram of a calculation unit of a filter breakage measuring device according to a first embodiment of the present invention.
5 and 6 are views of an operating state of the filter breakage measuring device according to the first embodiment of the present invention viewed from the top when the location of the dust is different.
7 is a view of an operating state of a filter breakage measuring device according to a second embodiment of the present invention viewed from the top.
8 is a diagram showing steps of a method for measuring filter breakage according to an embodiment of the present invention.

Hereinafter, specific embodiments for implementing the technical idea of the present invention will be described in detail with reference to the drawings.

In addition, in the description of the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

In addition, it is understood that when a component is referred to as 'connected', 'supplyed' or 'transmitted' to another component, it may be directly connected to, supplied from, or delivered to the other component, but other components may exist in the middle. It should be.

Terms used in this specification are only used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise.

In addition, in this specification, expressions such as upper, lower, side, etc. are described based on the drawings, and it is made clear in advance that they may be expressed differently if the direction of the object is changed. For the same reason, some components in the accompanying drawings are exaggerated, omitted, or schematically illustrated, and the size of each component does not entirely reflect the actual size.

In addition, terms including ordinal numbers, such as first and second, may be used to describe various components, but the components are not limited by these terms. These terms are only used to distinguish one component from another.

As used herein, the meaning of "comprising" specifies specific characteristics, regions, integers, steps, operations, elements, and/or components, and other specific characteristics, regions, integers, steps, operations, elements, elements, and/or groups. does not exclude the presence or addition of

Hereinafter, the specific configuration of the filter breakage measuring device 10 according to the first embodiment of the present invention will be described with reference to the drawings.

1 to 3, in this embodiment, the filter breakage measuring device 10 includes a frame 100, an irradiation unit 200, a receiving unit 300, a measuring unit 400, and a reading unit 500. can include

Inside the bag filter 1, a plurality of bag filters (B) through which air containing dust (D) is discharged are provided, and the outlets of the plurality of bag filters (B) are disposed inside so that the upper side is opened from the upper outlet. A virtual horizontal area A may be formed at a point spaced apart by a predetermined distance. In addition, a plurality of virtual lattice may be formed at a position corresponding to the outlet of the plurality of bag filters (B) in the above region (A).

The frame 100 is provided inside the filter bag 1, and is spaced apart from the upper outlet at a predetermined distance upward so that the outlets of the plurality of bag filters (B) through which air containing dust (D) is discharged are disposed inside. It may be formed in a quadrangular shape to surround a virtual horizontal area A formed at a point.

The irradiation unit 200 may include a first irradiation unit 210 , a second irradiation unit 220 and a third irradiation unit 230 .

The first irradiator 210 irradiates light traveling in the vertical direction to a plurality of grids formed at positions corresponding to the exits of the plurality of bag filters B in the virtual area A. The frame (irradiation) 100) may be disposed on one side extending in the horizontal direction.

The light may be irradiated in a straight direction, and, for example, when it reaches the dust (D), the progress may be stopped or the infrared ray may proceed in a state in which the amount of light or intensity of light is reduced. can include Meanwhile, the first irradiation unit 210, the second irradiation unit 220, and the third irradiation unit 230 may all include various devices capable of irradiating light such as infrared rays.

A plurality of second irradiation units 220 are provided on one side extending in the vertical direction of the frame 100 to irradiate light traveling in the horizontal direction to a plurality of grids formed at positions corresponding to the outlet of the bag filter B. can be placed.

The third irradiation unit 230 irradiates light traveling in an oblique direction to a lattice located on a diagonal in the virtual area A. The frame 100 between the first irradiation unit 210 and the second irradiation unit 220 ) can be placed at the corner of one. Meanwhile, a plurality of third irradiation units 230 may be disposed at left and right corners of the frame 100, respectively.

The first irradiation unit 210, the second irradiation unit 220, and the third irradiation unit 230 all form a horizontal area A spaced upward by a predetermined distance from the outlet of the plurality of bag filters B, for example dust ( D) may function to irradiate light to the horizontal area (A) in which the air containing the air rises.

The irradiation unit 200 may further include a plurality of first divided irradiation members 250 and a plurality of second divided irradiation members 260 .

The first divided irradiation member 250 serves to divide the light irradiated in the vertical direction from the first irradiation unit 210 into the vertical direction and the oblique direction, and is disposed in front of the first irradiation unit 210 in plurality. It can be.

The second divided irradiation member 260 functions to divide the light irradiated in the horizontal direction from the second irradiation unit 220 into horizontal and oblique directions, and a plurality of second irradiation members 260 are disposed in front of the second irradiation unit 220. It can be.

The first split irradiation member 250 and the second split irradiation member 260 may be beam splitters capable of dividing light incident in a linear direction into light in a linear direction and light in an oblique direction. A beam splitter refers to an optical member that can separate incident light into two beams according to a specified ratio. In this embodiment, the beam splitter may be configured to split light traveling in a straight direction into light traveling in a straight direction and light traveling at an angle of 45 degrees. Meanwhile, the first divided irradiation member 250 and the second divided irradiation member 260 may include various members capable of dividing and propagating light in addition to the beam splitter.

The receiving unit 300 may include a first receiving unit 310 , a second receiving unit 320 and a third receiving unit 330 .

The first receiving unit 310 is configured to receive light irradiated from the first irradiating unit 210 of the irradiation unit 200 so as to face the position where the first irradiating unit 210 is disposed, and the other side of the frame 100 on the opposite side. A plurality of them may be disposed on the side extending in the horizontal direction.

The second receiving unit 320 receives the light irradiated from the second irradiating unit 220 of the irradiation unit 200 so as to face the position where the second irradiation unit 220 is disposed, and the other side of the frame 100 on the opposite side. A plurality of them may be disposed on the side extending in the vertical direction.

The third receiving unit 330 is the first receiving unit of the frame 100, which is a corner in the diagonal direction of the corner where the third irradiation unit 230 is disposed to receive the light irradiated from the third irradiation unit 230 of the irradiation unit 200. One may be disposed at a corner between 310 and the second receiver 320. On the other hand, when a plurality of third irradiation units 230 are respectively disposed at the upper left and right corners of the frame 100, a plurality of third receivers 330 may also be formed to be disposed at the lower left and right corners of the frame 100, respectively. there is.

When the light emitted from the first irradiation unit 210, the second irradiation unit 220, and the third irradiation unit 230 passes through a grating without dust D, the first receiving unit 310, the second receiving unit 320, and the The third receiving unit 330 may receive light, and when the dust D passes through the lattice, light having a reduced light quantity or intensity may be received or no light may be received.

The receiving unit 300 may include a plurality of first divided receiving members 350 and a plurality of second divided receiving members 360 .

The first divided receiving member 350 receives the light traveling in an oblique direction from the second divided irradiation member 260 or the light traveling in a vertical direction from the first divided irradiation member 250 so that the first receiving unit 310 receives it. A plurality of them may be disposed in front of the first receiving unit 310 so as to be able to do so.

The second divided receiving member 360 receives the light traveling in an oblique direction from the first divided irradiation member 250 or the light traveling in a horizontal direction from the second divided irradiation member 260 so that the second receiver 320 receives it. A plurality of them may be disposed in front of the second receiving unit 320 so as to be able to do so.

Like the first divided irradiation member 250 and the second divided irradiation member 260, the first divided receiving member 350 and the second divided receiving member 360 receive light incident in a straight direction or incident light in an oblique direction. It may include various members including a beam splitter configured to change light into light traveling in a straight direction.

In this embodiment, a control unit 600 may be further included (FIG. 2). The control unit 600 may function to control the irradiation unit 200 so that the first irradiation unit 210, the second irradiation unit 220, and the third irradiation unit 230 operate in a predetermined order. For example, the control unit 600 turns on the first irradiation unit 210 to irradiate light in the vertical direction, turns off the first irradiation unit 210 after a predetermined time, and then turns on the second irradiation unit 220. ) is turned on to irradiate light in the horizontal direction, and after a predetermined time elapses, the second irradiator 220 is turned off, and then the third irradiation unit 230 is turned on to irradiate light in the oblique direction. The first irradiation unit 210, the second irradiation unit 220, and the third irradiation unit 230 may be controlled to be sequentially turned on and off. This is because, when light is simultaneously irradiated from the first irradiation unit 210, the second irradiation unit 220, and the third irradiation unit 230, interference may occur between the irradiated lights from each irradiation unit.

Accordingly, the first receiving unit 310, the second receiving unit 320, and the third receiving unit 330 sequentially receive light from the first irradiation unit 210, the second irradiation unit 220, and the third irradiation unit 230, respectively. Similarly, light traveling in a straight or oblique direction through the first divided irradiation member 250 or the second divided irradiation member 260 is transmitted to the first divided receiving member 350 or the second divided receiving member 360 can be received sequentially. As a result, since the light does not interfere with each other, it is possible to accurately determine the position of a specific bag filter (B) from which dust (D) exceeding a predetermined threshold concentration value is discharged.

The measuring unit 400 analyzes the light quantity or intensity of the light received by the receiving unit 300 to measure the concentration value of the dust D in the air discharged through each outlet for all of the plurality of bag filters B. can For example, since the amount or intensity of the light that proceeds through the area (A) with almost no dust (D) is high, the concentration value of the dust (D) will appear small, and the area (A) with dust (D) Since the light has a small amount or intensity or does not pass through, the concentration value of the dust (D) will appear large.

The reading unit 500 compares the concentration value of the dust D measured by the measurement unit 400 with a preset threshold concentration value, and the dust D exceeding the preset threshold concentration value among the plurality of bag filters is discharged. It can function to determine the position of a specific bag filter (B) to be. The reading unit 500 may be implemented by an arithmetic device including a microprocessor, a memory, and the like, and a detailed description thereof will be omitted since an implementation method is obvious to those skilled in the art.

The preset threshold concentration value may be stored in a memory or the like, and the preset threshold concentration value is, for example, assuming that the dust (D) purification efficiency of the bag filter (B) is about 99%, so that the bag filter (B) is not damaged. If the amount of dust (D) contained in the air before passing through the bag filter (B) is 100 mg/m ² , the amount of dust (D) passing through the bag filter (B) will be about 1 mg/m ² . Therefore, in the above case, the predetermined critical concentration value may be 1 mg/m ² . Similarly, if the amount of dust (D) contained in the air is based on 300mg/m ² , the predetermined critical concentration value may be 3mg/m ² . The above preset dust (D) concentration value may be arbitrarily set by the user.

When the amount of dust (D) contained in the air is based on 300mg/m ² , if the measured concentration value of dust (D) is less than the preset critical concentration value of 3mg/m ² , the bag filter (B) is in a normal state. It can be determined that, and the measured dust (D) concentration value exceeds a predetermined critical concentration value of 3mg / m ² It can be determined that the bag filter (B) is damaged or has an abnormality. In addition, the reading unit 500 determines which of the plurality of bag filters (B) has discharged dust D exceeding the preset threshold concentration value, that is, which of the bag filters B has exceeded the preset threshold concentration value. The position of a specific bag filter (B) can be determined. In addition, determination of the position of the bag filter B by the reading unit 500 may be implemented by an arithmetic device including a microprocessor.

Referring to FIG. 4 , a calculating unit 700 may be further included. The calculation unit 700 may perform a function of converting the concentration value of the dust D in the air discharged to the outlet of each of the plurality of bag filters B measured by the measuring unit 400 into a graph and deriving it. The concentration value of dust (D) measured through the above graph can be grasped relatively more easily than the concentration value expressed only numerically. On the other hand, the values of the horizontal axis (not shown) and the vertical axis of the illustrated graph are based on the relative ratio of the concentration value of the dust D in the air discharged to each outlet of the bag filter B and the preset threshold concentration value. It can be expressed as an absolute value representing the concentration of (D).

The measurement unit 400 may further include a noise removal unit (not shown) for removing signals other than light irradiated from the irradiation unit 200 in vertical, horizontal, and oblique directions and received by the receiving unit 300. can As a result, the measurement unit 400 can more accurately measure the concentration value of the dust D, and the reading unit 500 also more accurately exceeds the predetermined threshold concentration value based on the concentration value of the dust D. It is possible to determine the position of the bag filter (B) from which the dust (D) to be discharged.

In this embodiment, a remote management unit 800 may be further included (FIG. 2). The remote management unit 800 is a bag filter through which dust D exceeding the concentration value of the dust D measured by the measuring unit 400 and the preset critical concentration value determined by the reading unit 500 is discharged. (B) can function to automatically transmit data on the location to a management server (not shown) having a receiving unit (not shown) through a separate communication network. In addition, the data transmitted to the management server may be automatically transmitted to the manager's mobile terminal through a mobile communication network by a separate controller (not shown). Therefore, the user can check the damage or abnormal state of the bag filter B through the management server or through the mobile terminal even if outside.

Hereinafter, with reference to FIGS. 5 and 6, the operation and effect of the filter breakage measuring device 10 having the above configuration will be described.

When the irradiation unit 200 irradiates light and the receiving unit 300 receives light, the positions D23 and D32 of dust D in FIG. 5 and the position of dust D in FIG. 6 ( D22 and D33) are different. However, the first receivers 310-2 and 310-3 and the second receivers 320-2 and 320-3 do not receive the light emitted from the first irradiator 210 and the second irradiator 220, or Since only light with a reduced light quantity or intensity is irradiated, dust (D) is emitted from the bag filter (B) at exactly any position among the positions (D23, D32, D22, D33) where dust (D) is discharged from the bag filter (B) above. ) is difficult to determine.

However, in FIG. 5, since the light irradiated from the third irradiation unit 230 is received by the third receiving unit 330, it is determined that there is no dust D at the positions D22 and D33. Therefore, in the case of FIG. 5, D23 And it can be seen that dust (D) is discharged from the D32 position. Similarly, in FIG. 6 , light divided in an oblique direction from the first divided irradiation member 250-1 in front of the first irradiation unit 210-1 passes through the second divided receiving member 360-5 to the second receiving unit 320. -5), and the light divided in an oblique direction from the second divided irradiation member 260-2 in front of the second irradiation unit 220-1 passes through the first divided receiving member 350-5 to the first Since the reception is received by the receiver 310-5, it is determined that there is no dust D at the positions D23 and D32, and therefore, in the case of FIG. 6, it is possible to determine that dust D is discharged at the positions D22 and D33. In this way, by irradiating light in the vertical and horizontal directions as well as in the oblique direction to the grid, there is an effect of accurately determining at which position the dust D is generated in the bag filter B.

By analyzing the light by the measuring unit 400, it is possible to measure the concentration value of the dust D in the air discharged to each outlet for all of the plurality of bag filters B, and measured by the reading unit 500. The location of a specific bag filter (B) where dust (D) exceeding the preset critical concentration value is discharged by comparing the concentration value of the dust (D) with a preset critical concentration value (eg, D23, D32 or D22, D33) can be easily determined.

On the other hand, as described above, after identifying the position of the bag filter (B) from which dust (D) exceeding the critical concentration value is discharged, only the corresponding bag filter (B) needs to be replaced, thus reducing the replacement time and replacement cost of the bag filter. It works.

Meanwhile, in addition to this configuration, according to the second embodiment of the present invention, the filter breakage measuring device 10 excludes the first divided irradiation member 250 and the second divided irradiation member 260 in the irradiation unit 200. It may include only a plurality of first divisional receiving members 350 and a plurality of second divisional receiving members 360, and the third irradiation unit 230 may include a plurality of light beams in an oblique direction having different angles in the area A. can be formed to investigate.

A second embodiment will be described below with reference to FIG. 7 . In describing the second embodiment of the present invention, when compared with the above-described embodiments, the filter breakage measuring device 10 includes the first divided irradiation member 250 and the second divided irradiation member in the irradiation unit 200 Excluding 260, it may include only a plurality of first divided receiving members 350 and a plurality of second divided receiving members 360, and the third irradiation unit 230 has different angles in the area A, respectively. There is a difference in that it is formed to irradiate light in a plurality of oblique directions, and this difference will be mainly described, and the same description and reference numerals refer to the above-described embodiments.

The third irradiation unit 230 is located in a virtual horizontal area A spaced upward by a predetermined distance from the outlet so that the outlet of the plurality of bag filters B through which air containing dust D is discharged is disposed inside. It may be formed to emit light in a plurality of oblique directions having different angles. Specifically, light may be irradiated not only to the lattice at a position corresponding to the center of the outlet of the bag filter (B), but also to an area corresponding to the entire area of the outlet of the bag filter (B) slightly out of the lattice.

A rotation module (not shown) formed to be rotatable may be coupled to the third irradiation unit 230, and the above rotation module is sequentially rotated at a predetermined angle set by the user so that each angle is different from the third irradiation unit 230. It can be formed so that a plurality of lights to be irradiated. Alternatively, a plurality of third irradiation units 230 may be disposed at different angles. Meanwhile, a plurality of third irradiation units 230 may be disposed at left and right corners of the frame 100, respectively.

A plurality of first divisional receiving members 350 are provided in front of the first receiving unit 310 to receive light radiated from the third irradiation unit 230 in the vertical direction or light radiated from the first irradiation unit 210 in the vertical direction. can be placed.

A plurality of second split receiving members 360 are provided in front of the second receiver 320 to receive light irradiated in a horizontal direction from the third irradiator 230 or light irradiated in a horizontal direction from the second irradiator 220 . can be placed.

In the case of the present embodiment, since the light is irradiated not only to the lattice at the position corresponding to the center of the outlet of the bag filter (B) but also to the area corresponding to the entire area of the outlet of the bag filter (B) slightly out of the lattice, dust (D ) is discharged to a location slightly out of the center of the grid, there is an effect of more accurately determining the position of a specific bag filter (B) from which dust (D) exceeding the critical concentration value is discharged.

Hereinafter, a filter breakage measuring method (S1) using the filter breakage measuring device 10 according to an embodiment of the present invention will be described with reference to FIG. 8 .

In this embodiment, the filter breakage measuring method (S1) may include an investigation step (S10), a receiving step (S20), a measuring step, and a reading step (S40).

The irradiation step (S10) is a point spaced upward by a predetermined distance from the upper outlet so that the outlets of the plurality of bag filters (B) through which the air containing the dust (D) is discharged by the irradiation unit 200 are disposed inside. It is possible to irradiate light in a vertical direction, a horizontal direction, and an oblique direction to the virtual horizontal area (A) formed in.

In the receiving step (S20), the irradiated light may be received by the receiving unit 300.

In the measuring step (S30), the concentration value of the dust (D) in the air discharged from each outlet for all of the plurality of bag filters (B) by analyzing the light quantity or light intensity of the received light by the measuring unit (400). can measure

In the reading step (S40), the concentration value of the dust D measured by the measuring unit 400 is compared with a preset threshold concentration value by the reading unit 500 to set a preset critical concentration among the plurality of bag filters B. It is possible to determine the position of a specific bag filter (B) from which dust (D) exceeding the value is discharged.

As described above, there is an effect of determining the position of the bag filter (B) from which dust (D) exceeding a predetermined threshold concentration value is discharged through the above irradiation step (S10) to reading step (S40).

Meanwhile, the irradiation step (S10) may further include a control step (S11). In the control step (S11), the control unit 600 controls the irradiation unit 200 so that the first irradiation unit 210, the second irradiation unit 220, and the third irradiation unit 230 are operated according to a predetermined order. may be a step. A specific embodiment uses the embodiment of the control unit 600 described above.

Meanwhile, the measuring step may further include a calculating step (S31). The calculation step (S31) can be derived by converting the concentration value of the dust (D) in the air discharged to the outlet of each of the plurality of bag filters (B) into a graph by the calculation unit (700). A specific embodiment uses the embodiment of the calculation unit 700 described above.

Although the embodiments of the present invention have been described as specific embodiments, this is merely an example, and the present invention is not limited thereto, and should be construed as having the widest scope according to the technical spirit disclosed herein. A person skilled in the art may implement a pattern of a shape not indicated by combining/substituting the disclosed embodiments, but this also does not deviate from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on this specification, and it is clear that such changes or modifications also fall within the scope of the present invention.

10: filter damage measuring device 100: frame
200: irradiation unit 210: first irradiation unit
220: second irradiation unit 230: third irradiation unit
250: first divided irradiation member 260: second divided irradiation member
300: receiving unit 310: first receiving unit
320: second receiving unit 330: third receiving unit
350: first divided receiving member 360: second divided receiving member
400: measuring unit 500: reading unit
600: control unit 700: calculation unit
800: remote management unit

Claims (9)

A virtual horizontal area is formed at a point spaced upward by a predetermined distance from the outlet so that the outlets of the plurality of bag filters through which air containing dust is discharged are disposed inside, and the outlets of the plurality of bag filters are formed in the area. A plurality of virtual grids are formed at positions corresponding to
a frame formed to surround the area;
A plurality of first irradiation units disposed on one of the horizontally extending side surfaces of the frame so that light is irradiated to the plurality of grids in a vertical direction, and one of the frames so that light is irradiated to the plurality of grids in a horizontal direction. A plurality of second irradiation units disposed on a side surface extending in the vertical direction of and a third disposed at the corner of the frame between the first and second irradiation units so that light is radiated in an oblique direction to a grid on a diagonal in the area. An irradiation unit including an irradiation unit;
The other side of the frame, opposite to the position where the first irradiation unit, the second irradiation unit, and the third irradiation unit are disposed so that the light irradiated from the first irradiation unit, the second irradiation unit, and the third irradiation unit of the irradiation unit is received. Includes a plurality of first receiving units disposed on a side extending in the direction, a plurality of second receiving units disposed on a side extending in another longitudinal direction of the frame, and a third receiving unit disposed at a corner in a diagonal direction of the corner a receiving unit that;
a measuring unit analyzing the light received by the receiving unit and measuring a concentration value of dust in the air discharged through the outlet of each of the plurality of bag filters;
a reading unit which compares the concentration of dust measured by the measurement unit with a preset threshold concentration value and determines a position of a bag filter from which dust exceeding the preset threshold concentration value is discharged from among the plurality of bag filters; and
including a control unit;
The control unit controls the irradiation unit so that the first irradiation unit, the second irradiation unit, and the third irradiation unit are operated in a predetermined order.
Filter breakage measuring device. A virtual horizontal area is formed at a point spaced upward by a predetermined distance from the outlet so that the outlets of the plurality of bag filters through which air containing dust is discharged are disposed inside, and the outlets of the plurality of bag filters are formed in the area. A plurality of virtual grids are formed at positions corresponding to
a frame formed to surround the region;
A plurality of first irradiation units disposed on one of the horizontally extending side surfaces of the frame so that light is irradiated to the plurality of grids in a vertical direction, and one of the frames so that light is irradiated to the plurality of grids in a horizontal direction. A plurality of second irradiation units disposed on a side surface extending in the vertical direction of and a third disposed at the corner of the frame between the first and second irradiation units so that light is radiated in an oblique direction to a grid on a diagonal in the area. An irradiation unit including an irradiation unit;
The other side of the frame, opposite to the position where the first irradiation unit, the second irradiation unit, and the third irradiation unit are disposed so that the light irradiated from the first irradiation unit, the second irradiation unit, and the third irradiation unit of the irradiation unit is received. Includes a plurality of first receiving units disposed on a side extending in the direction, a plurality of second receiving units disposed on a side extending in another longitudinal direction of the frame, and a third receiving unit disposed at a corner in a diagonal direction of the corner a receiving unit that;
a measuring unit analyzing the light received by the receiving unit and measuring a concentration value of dust in the air discharged through the outlet of each of the plurality of bag filters; and
and a reading unit comparing the concentration value of the dust measured by the measurement unit with a preset threshold concentration value to determine a position of a bag filter from which dust exceeding the preset threshold concentration value is discharged from among the plurality of bag filters. and
The irradiation unit further includes a plurality of first divided irradiation members and a plurality of second divided irradiation members,
The receiving unit further includes a plurality of first divided receiving members and a plurality of second divided receiving members,
The plurality of first divided irradiation members are disposed in front of the first irradiation unit so that the light irradiated from the first irradiation unit in the vertical direction is divided into a vertical direction and an oblique direction, and
The plurality of second divided irradiation members are disposed in front of the second irradiation unit so that the light irradiated in the horizontal direction from the second irradiation unit is divided into a horizontal direction and an oblique direction, and
The plurality of first divided receiving members may be configured such that the light traveling in the oblique direction from the second divided irradiation member or the light traveling in the vertical direction from the first divided irradiation member is received by the first receiving unit. It is placed in front of the receiver,
The plurality of second divided receiving members may be configured such that the light traveling in the oblique direction from the first divided irradiation member or the light traveling in the horizontal direction from the second divided irradiation member is received by the second receiving unit. placed in front of the receiver,
Filter breakage measuring device. A virtual horizontal area is formed at a point spaced upward by a predetermined distance from the outlet so that the outlets of the plurality of bag filters through which air containing dust is discharged are disposed inside, and the outlets of the plurality of bag filters are formed in the area. A plurality of virtual grids are formed at positions corresponding to
a frame formed to surround the region;
A plurality of first irradiation units disposed on one of the horizontally extending side surfaces of the frame so that light is irradiated to the plurality of grids in a vertical direction, and one of the frames so that light is irradiated to the plurality of grids in a horizontal direction. A plurality of second irradiation units disposed on a side surface extending in the vertical direction of and a third disposed at the corner of the frame between the first and second irradiation units so that light is radiated in an oblique direction to a grid on a diagonal in the area. An irradiation unit including an irradiation unit;
The other side of the frame, opposite to the position where the first irradiation unit, the second irradiation unit, and the third irradiation unit are disposed so that the light irradiated from the first irradiation unit, the second irradiation unit, and the third irradiation unit of the irradiation unit is received. Includes a plurality of first receiving units disposed on a side extending in the direction, a plurality of second receiving units disposed on a side extending in another longitudinal direction of the frame, and a third receiving unit disposed at a corner in a diagonal direction of the corner a receiving unit that;
a measuring unit analyzing the light received by the receiving unit and measuring a concentration value of dust in the air discharged through the outlet of each of the plurality of bag filters; and
and a reading unit comparing the concentration value of the dust measured by the measurement unit with a preset threshold concentration value to determine a position of a bag filter from which dust exceeding the preset threshold concentration value is discharged from among the plurality of bag filters. do,
The third irradiation unit irradiates a plurality of oblique directions of light at different angles to the area,
a plurality of first divisional and receiving members disposed in front of the first receiving unit to receive the light emitted from the third irradiation unit in a vertical direction or the light irradiated from the first irradiation unit in a vertical direction; and
A plurality of second split-receiving members disposed in front of the second receiver so that the light irradiated in the horizontal direction from the third irradiator or the light irradiated in the horizontal direction from the second irradiator is received,
Filter breakage measuring device. delete According to claim 1,
Further comprising an output unit,
The calculation unit is derived by converting the concentration value of the dust measured by the measurement unit into a graph,
Filter breakage measuring device. According to claim 1,
Further comprising a remote management unit,
The remote management unit transmits the concentration value of the dust measured by the measuring unit and the location of the bag filter determined by the reading unit to a management server.
Filter breakage measuring device. In the filter breakage measuring method using the filter breakage measuring device according to any one of claims 1 to 3, 5, and 6,
By the irradiation unit, the vertical direction, horizontal direction and An irradiation step of irradiating light in an oblique direction;
a receiving step of receiving the irradiated light by the receiving unit;
a measuring step of measuring, by the measuring unit, a concentration value of dust in the air discharged through an outlet of each of the plurality of bag filters by analyzing the received light; and
The reading unit compares the concentration value of the dust measured by the measurement unit with a preset threshold concentration value to determine the position of the bag filter from which dust exceeding the preset threshold concentration value is discharged from among the plurality of bag filters. Including the reading step of determining,
Filter breakage measurement method. According to claim 7,
In the investigation step,
Further comprising a control step of controlling, by the control unit, the irradiation unit so that the first irradiation unit, the second irradiation unit, and the third irradiation unit are operated in a predetermined order.
Filter breakage measurement method. According to claim 7,
In the measuring step,
Further comprising a calculation step of converting and deriving the concentration value of the dust measured from the measurement unit by the calculation unit into a graph,
Filter breakage measurement method.

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