JP2006334445A - Dust collecting equipment and control method of dust collecting airflow amount used therein - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide dust collecting equipment capable of realizing the controll of a proper sucked airflow amount at a low initial cost while minimizing a running cost. <P>SOLUTION: The dust collecting equipment is composed of a dust collecting means, a suction means, the hoods arranged toward a plurality of dust producing positions, the connection ducts for respectively connecting the dust collecting means, the suction means and the hoods, the on-off dampers connected to the ducts at the downstream sides of the respective hoods, a pressure detecting means for detecting the airflow amount sucked by the suction means and a control means for adjusting the airflow amount and the opening degrees of the respective on-off dampers. The control means has an arithmetic means which sets and adjusts the opening degrees of the respective on-off dampers on the basis of the relational characteristics of the opening degrees and airflow amount ratio of the on-off dampers in the respective hoods. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a dust collection facility and a method for controlling the amount of dust collection air used in the facility. More specifically, the present invention relates to a dust collection facility that easily adjusts the suction air volume of a hood arranged toward a plurality of dust generation positions to an appropriate air volume, and a method for controlling the dust collection air volume used in the facility.

  Conventionally, in steelmaking factories, crushing factories, metal processing factories, foundry factories, etc., in order to improve the working environment and prevent pollution from the viewpoint of environmental hygiene, dust and dust (crushed materials) are collected. It is equipped with dust collection equipment that discharges as normal air.

  Such a dust collection facility mainly includes a dust collector, a blower, a hood arranged toward a plurality of dust generation positions, a duct connecting the dust collector, the blower, and each hood, and an opening / closing connected to a duct at a downstream position of each hood. It consists of a damper. In the dust collection facility, the opening of the open / close dampers in each hood is used to efficiently collect dust (dust generation), etc., according to a pattern determined by the predetermined number of openings and opening of the open / close dampers. Is adjusted to control the amount of air sucked by the hood.

  For example, as control for adjusting the air volume of the hood according to the opening degree of the open / close damper, there is a method of setting the opening degree set in advance with respect to the necessary air volume of each hood. However, with this method, there are an enormous number of patterns at the time of suction at a plurality of locations, and adjustments and setting changes at the site are complicated, and optimal settings cannot be made.

  On the other hand, there is a method of using a pressure sensor to automatically adjust the air volume of a damper in a hood by actually measuring it (see Patent Document 1). However, in this method, a pressure sensor must be arranged for each hood, so that not only is the initial cost very expensive, but if air containing a large amount of dust or dust is sucked in, the piping of the sensor May be clogged and the detection capability may be reduced. There is also a problem that it takes too much time for the calculation to converge.

Japanese Patent Laid-Open No. 7-47218

  Accordingly, in view of the above circumstances, the present invention realizes appropriate suction air volume control at a low initial cost and minimizes the running cost, and the dust collection air volume used in the equipment. The purpose is to provide a control method.

  The dust collection equipment of the present invention includes a dust collection means, a suction means, a hood arranged toward a plurality of dust generation positions, a duct connecting the dust collection means, the suction means and each hood, An open / close damper connected to the duct at a downstream position of the hood, a pressure detection means for detecting the air volume sucked by the suction means, and a control means for adjusting the air volume and the opening degree of each open / close damper. The means is characterized in that it has a built-in arithmetic unit for setting and adjusting the opening degree of each open / close damper based on the relationship between the opening degree of the open / close damper and the air flow ratio in each hood.

  The dust collection air volume control method according to the present invention is a method for collecting the dust sucked from a hood arranged toward a plurality of dust generation positions, and for opening and closing dampers connected to a duct at a downstream position of the hood. A method for controlling the amount of dust collected to adjust the opening, the step of detecting the set air volume of each hood, the step of controlling the sum of the set air volumes of each hood to a constant air volume, and the open / close damper in each hood The method includes a step of setting the opening of each open / close damper and a step of adjusting the set opening of the open / close damper based on the relationship between the opening and the air flow ratio.

  According to the present invention, the suction air volume of the hood can be easily set to an appropriate air volume.

  Further, since the open / close damper is only used for balance adjustment of the suction air volume of each hood, the pressure loss due to the restriction of the open / close damper can be minimized. For this reason, the energy saving effect of the inverter of a suction means can be exhibited to the maximum.

  Furthermore, since no pressure sensor is provided in the hood as in the prior art, multistage air volume setting and linear setting can be performed while suppressing initial cost.

  Hereinafter, a dust collection facility of the present invention and a method for controlling the amount of dust collection air used in the facility will be described with reference to the accompanying drawings.

  As shown in FIG. 1, the dust collection facility according to one embodiment of the present invention is composed of at least a dust collection means 1, a suction means 2, a suction unit 3 and a control means 4.

  The dust collecting means 1 is not particularly limited in the present invention. For example, a filter type dust collector in which a number of filter cloths are fixed and suspended in a gas flow path in the casing depending on the type of dust or the like. A centrifugal blower having an electric motor and blades in the casing, an electric dust collector that generates corona discharge in the air between the discharge electrode and the dust collecting electrode, and attaches dust / dust to the dust collecting electrode, etc. Can be selected as appropriate.

  The suction means 2 is not particularly limited in the present invention as long as it can suck air containing dust and the like. For example, a blower or the like can be selected as appropriate. The suction means 2 detects the air volume by measuring the dynamic pressure of the sucked air (gas) by the dynamic pressure sensor which is the pressure detection means 5 provided at the suction port of the suction means 2, Based on the detection signal, the air volume is set by the inverter 6 built in the control means 3 (the air volume necessary for sucking the dust in each suction section (the pitot tube while visually checking the suction status during the trial run). PID (Proportional operation, Integration operation (lntegral), Derivative operation) is controlled so that it becomes the total of the determined values). This is the product of the area and the flow velocity, and the flow velocity can be replaced with pressure, and can be obtained by a predetermined calculation formula.

  In the present invention, the dust collecting means 1 and the suction means 2 are separate devices and connected by the second main duct 9b. However, in the present invention, the present invention is not limited to this. For example, It can also be set as the apparatus which incorporated the suction means in the dust collection means. Further, in the present invention, the dust collecting means 1 is disposed between the suction means 2 and the suction portion 3, but is not particularly limited to this arrangement. It can be selected as appropriate in consideration of the type and performance of the means, the type of dust, the type of the suction means 2, and the like.

  The suction unit 3 includes a hood 7 and an opening / closing damper 8 that are arranged toward a plurality of dust generation positions in a room such as a factory. The hood 7 is connected to the tip of a branch duct 9 c that branches from the first main duct 9 a connected to the dust collecting means 1. The open / close damper 8 is connected to the middle of a branch duct 9 c at a downstream position of the hood 7. The hood 7 is not particularly limited as long as it has a shape capable of efficiently sucking dust. Further, the open / close damper 8 may have a structure composed of, for example, a butterfly damper, a drive motor (or a pneumatic or hydraulic drive) incorporating a controller for exchanging signals with the control means 4.

  The open / close damper 8 is connected to the dust collecting means 1. For example, the inverter-controlled suction means 2 sucks air containing dust from the hood 7 and sends it to the dust collecting means 1. The suction amount of each hood 7 is adjusted by the controller of each open / close damper 8.

  In the present embodiment, the suction portions 3 are arranged at three locations. However, in the present invention, the suction portions 3 are not limited to this, and may be appropriately selected according to the degree of the required environment, for example. Can do.

  The control means 4 includes a calculation unit that sets and adjusts the set air volume of the hood 7 and the opening degree of the open / close damper 8 in the hood 7. In this calculation unit, the opening degree of each open / close damper 8 is set based on the relational characteristic between the opening degree of the open / close damper 8 and the air volume ratio in each hood 7 (the relational characteristic between the opening degree of the open / close damper and the air volume ratio). is doing. The air volume ratio is the ratio between the air volume that can be sucked when the open / close damper 8 is fully opened in the hood 7 and the set air volume of the hood 7 (that is, the ratio of the set air volume to the air volume when the self damper is fully open). As shown in FIG. 2, the relationship between the opening degree of the open / close damper and the air volume ratio is the ratio of the set air volume when the open / close damper is fully opened and the suction air volume is 100%. Therefore, it can be determined by measurement (plot points in the figure). Normally, since the open / close damper 8 is a butterfly damper, the relational characteristic is drawn by a bending straight line having two bending points as shown in FIG. Therefore, in this embodiment, in order to facilitate calculation, the bending point is divided and divided into proportional bands of D, E, F, and G on the airflow ratio axis in the figure, and the relational characteristic is treated as an approximate bending line. ing. Here, with respect to each proportional band, it is obtained by a proportional coefficient (a damper opening deviation / air flow ratio deviation in each proportional band (for example, A / E for proportional band E) in each proportional band. (This is used when the damper opening is determined in the item (6) of the control method described later.) Can be calculated and obtained by a PLC (programmable controller) that performs sequence control using a program built-in method. .

  Therefore, the calculation unit in the present embodiment selects the calculation circuit unit that calculates the air flow ratio and the open / close damper 8 that maximizes the air flow ratio by comparing the air flow ratios of the open / close dampers 8 in the hoods 7 with each other. An arithmetic circuit unit that performs the full opening of the opening degree of the open / close damper 8 that maximizes the flow rate of the open / close damper in the hood 7, and the maximum air flow rate ratio of the open / close damper 8 of the hood 7 and other than the hood 7 The calculation circuit unit for calculating the air volume ratio that is the ratio of the air volume ratio of the open / close damper 7 of each hood 8 and the relational characteristics, and the hood 7 other than the open / close damper 8 of the hood 7 having the maximum air volume ratio are used. And an arithmetic circuit unit for setting the opening degree of the open / close damper 8 of each hood 7 from the air flow ratio of the open / close damper 8.

Next, an embodiment relating to the dust collection air volume control method of the present invention will be described with reference to FIG.
(1) The amount of dust generated from the dust generation object sucked by the hood is not always constant. For example, in the case of a melting furnace, when the material is put into the furnace, when the material is melted, the melted material is tilted. The amount of dust generated varies depending on the state of removal. Therefore, since the necessary suction air volume also changes in each state, it is necessary to change the setting (Note that as a concrete means for changing the setting, a signal (limit switch signal) that can determine the operation state of the furnace or a human condition There is a method of switching a preset air volume value by performing a selection operation with a switch according to the material type). Therefore, first, it is determined whether or not to change the set air volume in each hood (step S1). Here, the dynamic pressure is measured and the air volume is calculated at the suction port of the suction means. The inverter of the suction means performs PID control of the number of rotations of the suction means so that this air volume becomes the set air volume, and performs constant air volume control using the total air volume (target air volume) as a target value. .
(2) Next, when a signal of the set air volume of the open / close damper of each hood is input to the control means, the air volume ratio (simply the self-volume ratio as the ratio of the set air volume when the suckable air volume when the damper is fully opened is 100%) (Referred to as the air volume ratio with respect to the air volume when the damper is fully opened) (step S2).
(3) Next, after comparing the air volume ratios of the open / close dampers in each hood, the open / close damper having the maximum air volume ratio is selected (step S3).
(4) Next, the opening degree of the open / close damper that provides the maximum air flow ratio is set to 100% (step S4).
(5) Next, for the remaining (other) open / close dampers determined not to have the maximum airflow ratio, the ratio of the airflow ratio to the maximum airflow ratio ((the airflow ratio of the open / close damper / maximum airflow ratio in each hood) × 100%) Is calculated again (step S5).
(6) Next, the ratio (air flow rate ratio) calculated in step S5 is applied to the relational characteristic (see FIG. 2) calculation obtained in advance, and the opening degree of the remaining open / close damper is set (step S6). For example, if the calculated air volume ratio is a, a corresponds to the proportional band F in FIG. 2, and therefore the damper opening b can be obtained by the following equation.

  As described above, according to the present embodiment, the relational characteristic in which the opening-air volume ratio of the opening / closing damper for adjusting the air volume is an approximate bending line is used, so that the opening degree of the predetermined opening / closing damper with respect to the target air volume is PLC controlled. It can be determined by the following calculation. Therefore, the opening degree of each open / close damper can be set based on the relationship characteristic and the set air volume necessary for the open / close damper of each hood.

  In addition, by controlling the number of rotations of the suction means with an inverter, the hood open / close damper with the maximum self air volume ratio (the maximum air volume ratio of the set air volume with respect to the air volume when the self damper is fully open) is fully opened during suction at multiple locations. The remaining open / close dampers of the hood can determine the opening degree of the open / close damper from the relationship characteristics after calculating the air volume ratio relative to the air volume ratio of the open / close damper in the fully open hood. The target air volume can be controlled with a constant air volume by an inverter and a dynamic pressure sensor.

  For this reason, it is possible to perform throttling with the opening / closing damper for air volume adjustment while minimizing energy loss.

  Therefore, since the open / close damper is only used for adjusting the balance of the suction air volume of each hood, the pressure loss due to the restriction of the open / close damper can be minimized. For this reason, the energy saving effect of the inverter of a suction means can be exhibited to the maximum.

  In addition, since there is no pressure sensor in the hood as in the past, multi-stage air volume setting (preliminary numerical value for the set air volume is set in accordance with the state of dust generation subject to switching in a pattern, while suppressing initial cost. ) And linear setting (a method that continuously changes the set air volume to follow the required air volume according to the object whose dust volume changes constantly. For example, humans set the volume by manipulating the volume while viewing the dust volume. For example, a method of adjusting the air volume or a method of changing the set air volume in proportion to the temperature when the required air volume changes in proportion to the temperature change of the dust generation target can be performed.

It is a mimetic diagram of dust collection equipment concerning one embodiment of the present invention. It is a figure which shows the relationship characteristic between the opening degree of an opening-and-closing damper and air volume ratio in this invention. It is a flowchart concerning one embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Dust collection means 2 Suction means 3 Suction part 4 Control means 5 Pressure detection means 6 Inverter 7 Hood 8 Opening / closing damper 9a First main duct 9b Second main duct 9c Branch duct

Claims (5)

Connected to dust collection means, suction means, hoods arranged toward a plurality of dust generation positions, ducts connecting the dust collection means, suction means and each hood, and ducts downstream of the hoods Open / close damper, pressure detecting means for detecting the air volume sucked by the suction means, and control means for adjusting the air volume and the opening degree of each open / close damper. A dust collection facility comprising a calculation unit for setting and adjusting the opening degree of each open / close damper based on a relational characteristic between the opening degree of the damper and the air flow ratio. 2. The dust collection facility according to claim 1, wherein the air volume ratio is a ratio of an air volume that can be sucked when the open / close damper is fully opened in the hood and a set air volume of the hood. The calculation unit calculates the ratio of the air volume that can be sucked when the open / close damper is fully opened in the hood and the set air volume of the hood, and the air volume ratio of the open / close damper in each hood. A calculation circuit unit that selects the open / close damper that maximizes the air flow ratio, a calculation circuit unit that fully opens the opening / closing damper of the open / close damper in the hood, and the hood A calculation circuit unit for calculating an air flow ratio that is a ratio of a maximum air flow ratio of the open / close damper of the hood and an air flow ratio of the open / close damper of each hood other than the hood, and a relationship between the opening degree of the open / close damper and the air flow ratio in the hood And a calculation circuit unit for setting an opening degree of the open / close damper of each hood based on an air flow ratio of the open / close damper of each hood other than the open / close damper of the hood having the maximum air flow ratio. . This is a dust collection air volume control method that adjusts the opening of an open / close damper connected to a duct at a downstream position of the hood when collecting dust sucked from a hood arranged toward a plurality of dust generation positions. Based on the characteristics of the relationship between the step of detecting the set air volume of each hood, the step of controlling the sum of the set air volumes of each hood to a constant air volume, and the opening degree of the open / close damper and the air volume ratio in each hood A method for controlling the amount of dust collecting air, comprising: a step of setting the opening degree of each open / close damper and a step of adjusting the opening degree of the set opening / closing damper. The step of calculating the ratio of the air volume that can be sucked when the open / close damper is fully opened in the hood and the set air volume of the hood, which is the air volume ratio, and the air volume ratio of the open / close damper in each hood A step of selecting an open / close damper that maximizes the ratio, a step of fully opening the opening / closing damper of the open / close damper that maximizes the air flow ratio of the open / close damper in the hood, and the maximum air flow ratio of the open / close damper of the hood and other than the hood The hood open / close damper with the maximum air flow ratio is calculated using the step of calculating the air flow ratio, which is the ratio of the air flow ratio of the open / close damper of each hood, and the relationship between the opening degree of the open / close damper and the air flow ratio in the hood. The method for controlling the amount of dust collecting air according to claim 4, further comprising: setting the opening degree of the open / close damper of each hood from the air volume ratio of the open / close damper of each hood.