KR101121821B1 - Apparatus for detecting damage of bag filter for dust collecting and method thereof - Google Patents

Abstract

The present invention relates to a bag filter burnout detection apparatus and a method thereof, and more particularly, to a bag filter burnout detection device and a method for detecting a burnt out position of a bag filter for collecting dust. Bag filter burnout detection apparatus according to an embodiment of the present invention is arranged to be movable through the moving unit inside the baghouse configured to collect the dust in the air through the multi-arranged bag filter through the multi-arranged bag filter A laser dust concentration detector for detecting dust concentration in air; A dust concentration comparison unit determining a position of the dust concentration detected by the laser dust concentration detection unit that is equal to or greater than a reference value; And a control unit for detecting a damaged bag filter among the bag filters arranged in a row based on the determination result of the dust concentration comparison determination unit.

Bag filter, laser, damage

Description

Bag filter burnout detection apparatus and its method {APPARATUS FOR DETECTING DAMAGE OF BAG FILTER FOR DUST COLLECTING AND METHOD THEREOF}

The present invention relates to a bag filter burnout detection apparatus and a method thereof, and more particularly, to a bag filter burnout detection device and a method for detecting a burnt out position of a bag filter for collecting dust.

Generally, a steel mill or the like is provided with a dust collecting device for removing and discharging dust generated in the factory. Dust collectors in steel mills arrange bag filters inside the ducts to filter out dust in the exhaust gas.

As shown in FIG. 1, a conventional dust collector sucks dust or dust (gas containing gas) generated during an operation of a steel mill through a blower, etc., and a bag filter 2 disposed in the baghouse 1. The dust is collected by passing it through) and then letting it out into the atmosphere. And the dust collected by the bag filter 2 is configured to be discharged to the outside through a separate hopper (3).

The gas containing the dust generated in the steel mill as described above maintains a high temperature, including not only solid dust but also a large amount of embers cause a fire in the dust bag inside the back filter (2). In this case, the dust bag is burned and partially forms a pore, which cannot filter out all the dust in the gas generated at the steel mill, thus contaminating the air environment. In addition, since the bag filter 2 having the reduced dust collection performance has to replace all the internal dust bags, its durability is lowered and the life of the equipment is shortened.

Therefore, conventionally, a damaged bag filter had to be inspected by an operator, and it is difficult to inspect when the bag filter is large. Therefore, there are many cases where the damaged back filter is completely replaced while driving to the limit operation situation. In this case, the damaged bag filter reduces the efficiency of the baghouse due to the pressure imbalance and the tendency of dust to shorten the life of the bag.

The present invention has been made to solve the above-described problems, and an object of the present invention is based on a dust concentration measured using a laser on a burnt out bag filter among a plurality of bag filters configured in a bag house for collecting dust. The present invention provides a bag filter burnout detection apparatus and a method thereof.

In addition, another object of the present invention is to operate the laser in the baghouse horizontally and vertically when the dust concentration discharged from the rear end of the bag filter increases the bag filter burnout detection device that can accurately track the location of the bag filter discharged high dust concentration And improving the method.

Bag filter burnout detection apparatus according to an embodiment of the present invention is arranged to be movable through the moving unit inside the baghouse configured to collect the dust in the air through the multi-arranged bag filter through the multi-arranged bag filter A laser dust concentration detector for detecting dust concentration in air; A dust concentration comparison unit determining a position of the dust concentration detected by the laser dust concentration detection unit that is equal to or greater than a reference value; And a control unit for detecting a damaged bag filter among the bag filters arranged in a row based on the determination result of the dust concentration comparison determination unit.

In addition, the laser dust concentration detection unit, the first laser dust concentration detection unit for detecting the dust concentration while the left and right reciprocating movement in the column direction of the direction in which the bag filters are arranged in oh and heat; And a second laser dust concentration detector for detecting the dust concentration while reciprocating in the five directions orthogonal to the movement path of the first laser dust concentration detector.

In addition, the dust concentration comparison determiner, it is preferable to compare the dust concentration values measured in the first and second laser dust concentration measurement unit with the reference value, respectively, to calculate the position of the reference value or more as x or y orthogonal axis value.

In addition, the control unit, it is preferable to track the bag filter disposed at a position intersecting each other by matching the position values calculated by the dust concentration comparison determination unit on the xy orthogonal axis.

In addition, the laser dust concentration detection unit, a laser irradiation unit for irradiating a laser; And it is preferable to include a laser receiver for detecting the dust concentration by absorbing the laser irradiated from the laser irradiation unit.

In addition, it is preferable that the laser irradiation part and the laser receiver be movable through the moving part in synchronization with each other along the rail disposed on the housing edge of the baghouse.

On the other hand, the bag filter burnout detection method according to an embodiment of the present invention is a multi-row laser dust concentration detection unit arranged to be movable through the moving unit inside the baghouse configured to collect the dust in the air through the multi-array bag filter A first step of detecting dust concentration in air passing through the disposed bag filter; A second step in which the dust concentration comparison determination unit determines a position which is equal to or greater than a reference value among the dust concentrations detected by the laser dust concentration detection unit; And a third step of the control unit detecting the damaged bag filter among the bag filters arranged in a row based on the determination result of the dust concentration comparison determination unit.

In the second step, it is preferable that the dust concentration comparison determination unit compares the dust concentration values measured by the laser dust concentration measurement unit with a reference value, respectively, and calculates a position that is equal to or greater than the reference value as an x or y orthogonal axis value.

In the third step, it is preferable that the controller tracks the bag filters disposed at positions crossing each other by matching the position values calculated by the dust concentration comparison determination unit on the xy orthogonal axis.

According to the present invention, the position of a damaged bag filter among a plurality of bag filters in a baghouse collecting dust is detected based on the dust concentration measured using a laser, thereby quickly tracking the position of a damaged bag filter. The repair time can be shortened.

This reduces the time to replace the bag filter by manually checking for damage to the bag, and quickly replaces the dust bag inside the damaged factory to prevent deterioration and to reduce the damage of other dust bags. You can increase it.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Repeated descriptions, well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention, and detailed description of the configuration will be omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shape and size of elements in the drawings may be exaggerated for clarity.

2 is a block diagram showing the configuration of a bag filter burnout detection apparatus according to an embodiment of the present invention, Figures 3 and 4 is an exemplary view showing an application example of the bag filter burnout detection apparatus according to the present invention.

The bag filter burnout detection apparatus according to the embodiment of the present invention is applied to the bag filter of the conventional dust collector shown in FIG. The dust collector draws dust or dust containing gas (hereinafter referred to as hamjin gas) generated during operation of the steel mill to the inlet through a blower, etc., and a plurality of bag filters disposed in the baghouse 1 ( After passing through 2), dust is collected by discharging it into the atmosphere through the discharge port. Such a bag filter is arranged to communicate air inside a housing in which an inlet for suctioning a vacuum containing a vacuum and an outlet for exhausting clean air are formed. Since the configuration of the bag filter is a known matter, a detailed description thereof will be omitted.

The bag filter burnout detection apparatus according to the embodiment of the present invention is applied to the bag filter 2 of the conventional dust collector shown in FIG. The dust collector sucks dust or dust containing gas (hereinafter referred to as hamjin gas) generated during the operation of the steel mill to the inlet 6 through a blower (not shown), etc., which is a baghouse (1) The dust is collected by passing it through the bag filter 2 arranged in a row and then discharging it into the atmosphere through the discharge port 7. The bag filter 2 is arranged to communicate air inside the housing 5 in which the inlet 6 for sucking the vacuum air and the outlet 7 for discharging the clean air are formed. Since the configuration of the bag filter 2 is well known, detailed description thereof will be omitted.

2 to 4, the bag filter burnout detection apparatus according to an embodiment of the present invention comprises a laser dust concentration detection unit 50, dust concentration comparison determination unit 30, the control unit 40.

The laser dust concentration detection unit 50 passes through the multi-arranged bag filter 2 which is arranged to be movable through the moving unit inside the baghouse 1 configured to collect dust in the air through the multi-arranged bag filter. Detects the concentration of dust in the air. Here, the moving part is configured to be movable in the form of a motor or a belt pulley. Since the configuration of the moving part is well known, a detailed description thereof will be omitted.

For example, the laser dust concentration detection unit 50 may include at least one bag filter 2 arranged to communicate air inside a housing 5 in which an inlet 6 for suctioning vacuum air and an outlet 7 for exhausting clean air are formed. It is arranged to be movable on the outlet 7 side of the housing 5 of the baghouse 1, which is configured to collect dust in the air through a rule, so as to detect the dust concentration in the air passing through the one or more bag filters 2. have.

Here, the laser dust concentration detector 30 detects the dust concentration by measuring the amount of light reduction according to the amount of dust in the air by using the characteristics of a laser having strong straightness by emitting light having the same wavelength, phase, and traveling direction. Will be used. The method of detecting the dust concentration using such a laser can be easily understood by those skilled in the art, so a detailed description thereof will be omitted.

For example, the dust-containing gas generated in the steel mill maintains a high temperature, and since the dust contains not only high temperature dust but also a large amount of embers, the dust collecting bag inside the bag filter 2 is damaged. . Then, the laser dust concentration detector 50 sequentially inspects the bag filters 2 arranged in a row in the baghouse 1. That is, the laser dust concentration detection unit 50 detects the dust concentration separately by irradiating a laser to the exit side of each of the bag filters 2 arranged in a row.

In addition, the laser dust concentration detector 50 detects the dust concentration for each position that detects the dust concentration by moving the left and right reciprocating through the moving unit in the column direction among the directions in which the bag filters are arranged in a row and a row. The detection unit 10 and the first laser dust concentration detection unit 10 includes a second laser dust concentration detection unit 20 for detecting the dust concentration for each position while reciprocating through the moving unit in an orthogonal direction perpendicular to the movement path. desirable . Thus, the first and second dust concentration detectors 10 and 20 move up and down (y) and left and right (x) to measure the dust concentration for each location.

In addition, the laser dust concentration detection unit 50 absorbs the laser irradiated from the laser irradiation unit (11, 21) and the laser irradiation unit (11, 21) for irradiating the laser while moving through the moving unit along the edge of the baghouse (1). Laser receivers 12 and 22 for detecting the dust concentration. The laser irradiation units 11 and 21 and the laser receivers 12 and 22 detect the dust concentration for each position of the bag filter 2 while moving in synchronization with the moving unit. Here, the moving part may be configured to move on the rail formed at the edge of the baghouse 1, and the configuration of the laser irradiating part and the laser receiving part and the moving part may be easily understood by those skilled in the art. Detailed description will be omitted.

The dust concentration comparison determination unit 30 compares the dust concentration detected by the laser dust concentration detection unit with a preset reference value, and tracks and determines a position having a dust concentration higher than the reference value. Thus, the dust concentration comparison determination unit 30 transmits the determination result (for example, the position value of which the dust concentration is higher than the reference value) to the controller 40. The dust concentration comparison determination unit 30 calculates a position value by sequentially comparing the input dust concentration values.

Here, the reference value is preferably set by measuring the dust concentration of the clean gas measured by passing the impregnated gas through the normal bag filter (2). Normally, the reference value is preferably set to 5 to 10 mg / m 3. For example, since the efficiency of the normal bag filter 2 is 99% or more, if the dust concentration of the front end of the bag filter 2 is 300mg / m 3, after passing through the bag filter 2, about 3mg / m 3 is produced. If the dust concentration value increases and decreases momentarily, it may occur after exhaustion, but if the value continuously exceeds 3mg / ㎥, it may be regarded as an abnormality in the dust bag or a hole.

In addition, the dust concentration comparison unit 30 compares the dust concentration values measured by the first and second laser dust concentration measurement units 10 and 20 with reference values, respectively, and calculates a position that is greater than or equal to the reference value as an x or y orthogonal axis value. It is preferable to output to the control unit 40.

The controller 40 detects the burnout of the bag filter 2 by determining that the bag filter 2 at the position where the dust concentration value is equal to or greater than the reference value is burned based on the determination result of the dust concentration determiner. That is, the controller 40 tracks the bag filter corresponding to the position value having a high dust concentration. Therefore, it is determined that the bag filter of the corresponding position is damaged.

In addition, the controller may track the bag filters disposed at positions crossing each other by matching the position values calculated by the dust concentration comparison unit on the xy orthogonal axis.

For example, when the dust concentration comparison unit 30 has a plurality of bag filters 2 of the baghouse 1 installed, the dust concentration comparison unit 30 may measure the dust concentration values measured by the first and second laser dust concentration measurement units 10 and 20. Compared with the reference value, respectively, the position values at which dust concentrations higher than the reference value are generated are provided to the controller 40. Then, the controller 40 compares the position values and determines that the back filter 2 at the corresponding position is damaged. That is, the controller 40 compares the position values having a high dust concentration with each other and tracks the bag filters at the positions that fit on the upper, lower, left, and right lines. Therefore, it is determined that the bag filter of the corresponding position is damaged.

In addition, the control unit 40 controls the driving of the laser dust concentration detection unit 50 together, it is preferable to periodically drive the laser dust concentration detection unit 50 to the upper and lower sides (x, y) to detect the dust concentration.

In addition, a stack that is discharged to the outside through the discharge port (7) of the dust collector in general constitutes a separate dust measurement means (not shown) to measure the dust concentration of the clean gas. The dust measuring means generates an abnormal signal when the measured dust concentration of the stack is high. In the present invention, when the controller 40 receives such an abnormal signal, the controller 40 may drive the laser dust concentration detector 50 to detect the dust concentration. That is, in general, the bag filter 2 is installed before the final stack, and the concentration of the rear end of the bag filter 2 and the dust concentration of the stack are the same. In general, from the management perspective, this data is available because the stack has a device for measuring dust concentration in real time.

In addition, the bag filter 2 is divided into several sections and managed. In other words, the bag filter which is in a preliminary state is maintained or the bag filter which collected dust is exhausted. Therefore, in the present invention, by detecting the burnout of the bag filter and repairing the bag filter in the preliminary state, it is possible to cope quickly without deteriorating the efficiency of the dust collector.

Hereinafter, a process of detecting a damaged bag filter in a bag filter damage detecting apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings.

5 is a flowchart showing the operation of the apparatus for detecting damage to the bag filter 2 according to the embodiment of the present invention.

Referring to FIG. 5, when the dust concentration discharged from the rear end of the bag filter 2 is increased, the first and second laser dust concentration detection units 20 disposed in the baghouse 1 are moved along the moving path. It is activated.

First, the first laser dust concentration detector 10 moves along the rail installed in the upper baghouse 1 of the bag filter 2 to detect the dust concentration on the y-line (S10). The dust concentration comparison unit 30 compares the dust concentrations on the y-line detected by the first laser dust concentration detector 10 with a reference value (S20), and calculates a position value that is greater than or equal to the reference value (S30).

Next, the second laser dust concentration detector 20 also moves along the rail provided in the upper baghouse 1 of the bag filter 2 to detect the dust concentration on the x-line (S12). The dust concentration comparison determination unit 30 compares the dust concentration on the x-line detected by the second laser dust concentration detection unit 20 with a reference value (S22), and calculates a position value that is equal to or greater than the reference value (S32).

Finally, the controller 40 compares the position values and determines that the back filter 2 at the position where the lines meet each other on the x line and the y line has been damaged, and detects the damaged back filter 2.

For example, the dust concentration of two rows is detected by the first laser dust concentration detector 10 shown in FIG. 4 higher than that of one row, and the dust concentration of three rows is detected by the second laser dust concentration detector 20 higher. If so, it can be predicted that a hole has occurred in the 8th bag filter 2. Then, the control unit 40 displays the damaged bag filter 2 number on each baghouse 1 on the display unit so that the replacement is quickly performed when the preliminary baghouse 1 becomes.

As mentioned above, although embodiment of this invention was shown and demonstrated, this invention is not limited to the specific embodiment mentioned above, Comprising: It is common in the art to which this invention pertains without deviating from the summary of this invention claimed in the Claim. Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the scope of the present invention.

1 is an exemplary view illustrating a conventional dust collector.

2 is a block diagram showing the configuration of a bag filter burnout detection apparatus according to an embodiment of the present invention.

3 and 4 are exemplary views showing an application example of the bag filter burnout detection apparatus according to the present invention.

5 is a flow chart showing the operation flow of the bag filter damage detection apparatus according to an embodiment of the present invention.

* Description of the major symbols in the drawings *

1: baghouse 2: bag filter

5 housing 6 inlet port

7: outlet 10, 20: first and second laser dust concentration detection unit

11, 21: laser irradiation unit 12, 22: laser receiver

30: dust concentration comparison unit 40: control unit

50: laser dust concentration detection unit

Claims (9)

A laser irradiation unit arranged to be movable through a moving unit in a baghouse configured to collect dust in the air through a multi-arranged bag filter to irradiate the multi-arranged laser; And A laser dust concentration detection unit including a laser receiver for absorbing the laser beam irradiated from the laser irradiation unit and detecting a dust concentration in the air passing through the bag filter; A dust concentration comparison unit determining a position of the dust concentration detected by the laser dust concentration detection unit that is equal to or greater than a reference value; And A control unit for detecting a damaged bag filter of the multi-arrayed bag filters based on a determination result of the dust concentration comparison determination unit, The laser irradiation unit and the laser receiver, The bag filter burnout detection device, characterized in that the movable unit is moved in synchronization with each other along the rail disposed on the housing rim of the baghouse. The method according to claim 1, The laser dust concentration detection unit, A first laser dust concentration detector for detecting dust concentrations while the bag filters reciprocate left and right in a column direction among the directions in which the bag filters are arranged in oh and row; And And a second laser dust concentration detector for detecting the dust concentration while reciprocating in the five directions orthogonal to the movement path of the first laser dust concentration detector. The method according to claim 2, The dust concentration comparison determination unit, The bag filter burnout detection apparatus of claim 1, wherein the dust concentration values measured by the first and second laser dust concentration measuring units are compared with a reference value, respectively, to calculate a position greater than or equal to the reference value as an x or y orthogonal axis value. The method of claim 3, The control unit, The bag filter burnout detection apparatus of claim 1, wherein the bag filters disposed at positions crossing each other are mapped to correspond to the position values calculated by the dust concentration comparison unit on an xy orthogonal axis. delete delete A laser dust concentration detection unit arranged to be movable through a moving unit inside a baghouse configured to collect dust in the air through the multi-array bag filter detects dust concentration in the air passing through the multi-array bag filter. First step; A second step of determining, by a dust concentration comparison determination unit, a position that is equal to or greater than a reference value among dust concentrations detected by the laser dust concentration detection unit; And And a third step of detecting, by the controller, a damaged bag filter among the multi-arrayed bag filters based on the determination result of the dust concentration comparison determination unit. The first step is a bag filter burnout detection method, characterized in that the laser irradiator and the laser receiver including a dust concentration detector is movable along the rails disposed along the rail disposed on the housing rim of the baghouse. The method of claim 7, The second step, The dust concentration comparison determination unit compares the dust concentration values measured by the laser dust concentration measurement unit with a reference value, respectively, and calculates a position equal to or greater than the reference value as an x or y orthogonal axis value. The method according to claim 8, The third step, And the control unit tracks the bag filters disposed at positions crossing each other by matching the position values calculated by the dust concentration comparison unit on an xy orthogonal axis.

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