KR101085512B1 - System for controlling face velocity of fume hood - Google Patents

Abstract

The present invention relates to a surface wind velocity control system of a fume hood.

The present invention is installed in a laboratory, etc. to set the surface wind speed to the fume hood to maintain a pleasant laboratory working environment by forcibly exhausting gases, such as odors, vapors, and other harmful to the human body, the rotation of the blower to maintain the set surface wind speed By controlling the speed and the opening angle of the damper to control the surface wind speed of the fume hood, the surface wind speed can be maintained regardless of the opening degree of the door of the fume hood. By adjusting the surface wind speed will provide an effect that can be used conveniently.

Fume Hood, Cotton Wind

Description

Fume hood surface wind velocity control system {SYSTEM FOR CONTROLLING FACE VELOCITY OF FUME HOOD}

The present invention relates to a surface wind velocity control system of a fume hood, and more particularly, to a surface wind velocity of a fume hood that enables the user to control the surface wind velocity according to the door opening degree in a fume hood used in a laboratory or the like precisely. It relates to a control system.

In general, fume hoods are installed in places where hazardous chemicals are handled or in laboratories, and are essential equipment for maintaining a pleasant laboratory working environment by forcibly discharging gases, odors, and vapors harmful to humans to the outside. A work plate is provided to form a working space therein, the front door is provided to be opened and closed up and down, and an exhaust duct is provided at the top to exhaust harmful gases generated in the working space.

In this state, the door provided on the front side of the fume hood configured as described above is experimented by using an experiment apparatus placed on a working plate, and the harmful gas generated during the experiment is exhausted to the outside through an exhaust duct.

At this time, the fume hood is designed to convert the displacement of the air according to the opening and closing area of the front door, and automatically adjusts the displacement when the surface wind speed due to opening and closing the door is above or below the set value or when unsafe operation occurs. The state needs control.

However, currently used fume hoods are used as simply exhaust devices without individual control devices to control the surface wind speed, and several fume hoods are connected to one duct, and each fume hood's surface wind speed is damper. It is used in a fixed state by adjusting the opening angle of the, there is a problem that it is difficult to adjust the surface wind speed of the individual fume hood according to the regulations.

Wherein the surface wind speed condition of the fume hood is required to have a wind speed of 0.25 ~ 0.3m / sec when opening the front door, 0.5m / sec when half opening.

Therefore, the conventional fume hood is provided with a control device that can adjust the displacement in accordance with the degree of opening and closing of the door, the control device is a position sensor for detecting the opening position according to the opening and closing degree of the door, harmful gas discharged by the exhaust duct And a damper for adjusting the wind speed of the damper, and a flow rate sensor for detecting the wind speed discharged to the exhaust fan through the exhaust duct according to the degree of opening of the damper, and according to the open position of the position sensor, To detect and control the displacement.

As described above, the conventional fume hood simply calculates an exhaust amount according to the opening / closing degree of the door using an exhaust or a control device, and accelerates or decelerates the exhaust fan so that the exhaust gas is exhausted by the calculated exhaust amount, that is, automatically opens or closes the exhaust amount by opening and closing the door. To control, there is a problem that can not be controlled to a set value that meets the surface wind speed regulation of the fume hood.

An object of the present invention is to enable automatic control of the surface wind velocity of the fume hood according to a set value.

In order to achieve the above object, the present invention provides a fume hood provided with an exhaust duct on a door and an upper portion thereof; A wind speed sensor for detecting a surface wind speed inside the fume hood; A controller for controlling the surface wind speed detected by the wind speed sensor; A damper for adjusting an opening angle according to a control signal of the controller; A blower rotating by a control signal of the controller; And the controller sets the surface wind speed and controls the rotational speed of the blower and the opening angle of the damper so that the surface wind speed detected by the wind speed sensor maintains the set surface wind speed.

The controller is capable of automatic or manual control.

The controller sets an inverter frequency by multiplying the set surface wind speed by a proportional constant, obtains a wind speed error by comparing the set surface wind speed and the surface wind speed detected by the wind speed sensor, and multiplies the wind speed error by a proportional integral (PI) control value. After calculating the frequency variation, the surface wind speed is controlled by a frequency value obtained by adding the calculated frequency variation to the inverter frequency.

The controller inputs an A / D converter for converting an analog signal into a digital signal, a memory for storing an algorithm required for a control operation, a microprocessor for controlling operation with an algorithm stored in the memory, and a surface wind velocity preset to the microprocessor. It is provided with a keypad, a display unit for displaying the operating state of the surface wind speed and the fume hood input by the keypad.

The damper includes a potentiometer for detecting an opening angle, an A / D converter for converting a signal detected by the potentiometer to a digital signal, a microcomputer for receiving and controlling a digitally converted signal from the A / D converter, and the opening. It is provided with a manual switch and a variable resistor to manually operate the angle.

The controller includes connecting the damper and the blower to the RS-485 communication line.

Therefore, according to the present invention, the surface wind speed is set in a fume hood installed in a laboratory or the like to force a gas, odor, steam, etc. harmful to the human body to the outside to maintain a comfortable laboratory working environment, and to maintain the set surface wind speed By controlling the fan speed of the fume hood by adjusting the rotational speed of the blower and the opening angle of the damper, it is possible to maintain the face wind speed regardless of the degree of opening of the fume hood door. The user is provided with an effect that can be conveniently used to adjust the surface wind speed.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of the surface wind speed control system of the fume hood of the present invention, Figure 2 is a block diagram of the surface wind speed control system of the fume hood of the present invention, Figure 3 is a flow chart of the surface wind speed control system of the fume hood of the present invention. .

The present invention includes a fume hood 10, a controller 20, a wind speed sensor 30, a damper 40, and a blower 50.

The fume hood 10 is installed in a place or a laboratory that handles hazardous chemicals to forcibly exhaust the harmful gas to the user to maintain a pleasant laboratory work environment, the fume hood 10 has a working space therein It is formed, the front door 11 is provided to open and close up and down, the rear upper portion is provided with an exhaust duct 12 for discharging harmful gas to the outside.

The controller 20 controls the inner surface wind speed of the fume hood 10, and the controller 20 stores an A / D converter 21 for converting an analog signal into a digital signal and an algorithm necessary for a control operation. A memory 22, a microprocessor 23 that operates by an algorithm stored in the memory 22, a keypad 24 for inputting a predetermined surface wind speed to the microprocessor 23, and an input to the keypad 24 It is provided with a display unit 25 for displaying the surface wind velocity and the operation state of the fume hood (10).

The controller 20 is driven automatically or manually. The controller 20 obtains an inverter frequency by multiplying a frequency corresponding to a set surface wind speed by a proportional constant, and sets the surface wind speed and wind speed sensor 30 to the inverter frequency. The wind speed error is calculated by comparing the wind speeds measured in the above, and the frequency variation is calculated by multiplying the proportional integral (PI) control value by the wind speed error. do.

The display unit 25 includes an LCD for displaying the surface wind speed and a plurality of lamps for displaying an operation state.

The wind speed sensor 30 is installed at an internal location of the fume hood 10 to detect the surface wind speed therein, and the detected surface wind speed is input to the controller 20.

The damper 40 is coupled to the exhaust pipe coupled to the exhaust duct 13 of the fume hood 10 to adjust the opening angle while driving by the control signal of the controller 20, the adjusted opening angle is the controller Potentiometer 41 for detecting the opening angle to transmit to (20), A / D converter 42 for converting the signal detected by the potentiometer 41 into a digital signal, the A / D converter 42 ) Is provided with a microcomputer 43 for receiving and controlling the digitally converted signal and a manual switch 44 and a variable resistor 45 for manually operating the opening angle.

The blower 50 inhales harmful gas of the fume hood 10 and discharges it to the outside, and the blower 50 is coupled to an exhaust pipe coupled to the exhaust duct 12 of the fume hood 10 and the controller. In accordance with the control signal of the (20) is provided with an inverter (INVERTER), the fan motor (FAN MOTOR) is controlled by the blowing speed.

The controller 20, damper 40 and blower 50 are connected by an RS-485 communication line.

According to the present invention configured as described above, the fume hood 10 is installed in a place or a laboratory that handles hazardous chemicals, and the damper 40 and the blower 50 are disposed in the exhaust duct 12 of the fume hood 10. The fume hood 10 and the damper 40, the blower 50 is connected to each other through an RS-485 communication line.

Subsequently, the surface wind speed of the wind speed sensor 30 mounted in the work space of the fume hood 10 is input through the keypad 24 of the controller 20 mounted on the fume hood 10 (step 210).

In this case, the controller 20 displays the set surface wind speed through the display unit 25, and in the microprocessor 23 of the controller 20, the control signal is set by a predetermined algorithm through the memory 22. Is transmitted to the damper 40 and the blower 50 through the RS-485 communication line to control the opening angle of the damper 40 and the rotational speed of the blower 50, the opening of the controlled damper 40 The angle and the rotation speed of the blower 50 are transmitted to the controller 20 through the RS-485 communication line and discharge the harmful gas (step 211).

When the harmful gas is discharged as described above, the controller 20 detects and inputs the surface wind velocity into the workspace of the current fume hood 20 through the wind speed sensor 30 (step 212), and inputs the input surface wind velocity to the controller. In step 20, it is determined whether or not the surface wind velocity is set (step 213).

At this time, if the detected surface wind velocity does not match the set surface wind velocity, the controller 20 transmits a control signal according to the predetermined algorithm to the damper 40 to the microcomputer 43 through the RS-485 communication line, The microcomputer 43 adjusts the opening angle of the damper 40 to be large or small according to the transmitted control signal, and the large or small adjustment of the thermal ram angle is input to the microcomputer 43 through the potential meter 41. The microcomputer 43 transmits to the controller 20 through the RS-485 communication line.

The controller 20 transmits a proportional integral control signal to the inverter 41 of the blower 50 through the RS-485 communication line to adjust the rotation speed of the fan motor 42 quickly or slowly (step 211). And detecting the wind speed change according to the fast and slow rotational speed through the wind speed sensor 30 (step 212), and determining whether the detected wind speed matches the set surface wind speed (step 213). Repeatedly perform the automatic control of the surface wind speed to exhaust the harmful gas.

On the other hand, if the detected surface wind speed is set to match the surface wind speed, the controller 20 determines whether the work is completed (step 214), and if the work is not completed at this time, the surface wind speed is set so that the damper 40 is maintained. ) And the opening angle and rotation speed of the blower 50 are automatically adjusted, and the operation is completed when the operation is completed.

When the fume hood 10 is manually controlled, the controller 20 is set manually, and the variable resistor 45 is manually set by the manual switch 44 of the damper 40 according to the manual operation of the controller 20. The fume hood 10 is controlled by the opening angle of the damper 40 and the rotational speed of the blower 50 by manually setting the rotational speed of the blower 50 by adjusting the opening angle of the damper 40. By exhausting the harmful gas of the operator, it is possible to conveniently use while controlling the amount of harmful gas discharged by the operator.

1 is a block diagram of a surface wind speed control system of the present invention fume hood.

Figure 2 is a block diagram of the surface wind speed control system of the present invention fume hood.

3 is an operation flowchart of the surface wind speed control system of the present invention fume hood.

* Description of the symbols for the main parts of the drawings *

10; Fume hood 11; door

12; Exhaust duct 20; Controller

21; A / D converter 22; Memory

23; Microprocessor 24; Keypad

25; A display unit 30; Wind speed sensor

40; Damper 41; Potentiometer

42; A / D converter 43; Micom

44; Manual switch 45; Variable resistor

50; Blower 51; inverter

52; Fan motor

Claims (6)

A fume hood having a front door and an exhaust duct at the top; A wind speed sensor for detecting a surface wind speed inside the fume hood; A controller for controlling the surface wind speed detected by the wind speed sensor; A damper for adjusting an opening angle according to a control signal of the controller; A blower rotating by a control signal of the controller; And The controller includes setting the surface wind speed, and controlling and controlling the rotational speed of the blower and the opening angle of the damper so that the surface wind speed detected by the wind speed sensor maintains the set surface wind speed. The controller obtains an inverter frequency by multiplying the set surface wind speed by a proportional constant, and compares the set surface wind speed and the surface wind speed measured by the wind speed sensor to obtain a wind speed error, and then multiplies the frequency error by a proportional integral (PI) control value. A surface wind speed control system of a fume hood, characterized in that for calculating the fluctuation, and controlling the surface wind speed by the frequency value of the calculated frequency variation plus the inverter frequency. The method of claim 1, The controller is a fume hood surface wind speed control system capable of automatic or manual control. delete The method of claim 1, The controller may include an A / D converter for converting an analog signal into a digital signal and a memory for storing algorithms necessary for a control operation. A microprocessor for controlling operation with an algorithm stored in the memory, A keypad for inputting a surface wind velocity preset in the microprocessor, Hume hood surface wind speed control system provided with a display unit for displaying the operation state of the surface wind speed and the fume hood input by the keypad. The method of claim 1, The damper is a potentiometer for detecting the opening angle, An A / D converter for converting the signal detected by the potentiometer into a digital signal, A microcomputer that receives and controls the digitally converted signal from the A / D converter, Hume hood surface wind speed control system provided with a manual switch and a variable resistor to manually operate the opening angle. The method of claim 1, And the controller is connected to the damper and the blower by the RS-485 communication line.

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