KR20080078996A - Surface speed display device and exhaust speed display method of exhaust system - Google Patents

Abstract

A face velocity display device of an exhaust apparatus and a face velocity display method are provided to supply a variable airflow control system and a variable airflow control method for managing the environment of a work place and securing the safety of workers by the face velocity display device. A face velocity display system of an exhaust system is composed of: a fume hood(120) equipped with a slide door(124) slidably opened, on the front side and connected to an exhaust duct(130) for exhausting harmful chemical matter or highly contaminated materials; an exhaust fan(110) discharging the harmful chemical matter or highly contaminated materials ejected through the exhaust duct, to the outside; a flow velocity sensor(122) measuring the wind velocity of the harmful chemical matter or highly contaminated materials according to the opening degree of a damper and transmitting a measured wind velocity signal to an individual hood control unit(140); a position sensor(123) measuring the open height of the slide door and transmitting a measured open height signal to the individual hood control unit; and the individual hood control unit calculating the present exhaust amount of the duct by using the wind velocity signal received through the flow velocity sensor, computing an average collection speed by applying an opening area value of the fume hood by using the open height signal received through the position sensor, and displaying the computed value.

Description

Surface speed display system and surface speed display method of exhaust system

1 is a schematic configuration diagram of a surface speed display system of an exhaust system according to an embodiment of the present invention;

2 is a flowchart of a surface speed display method of an exhaust system according to an exemplary embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110: exhaust fan 120: fume hood

121: damper 122: flow rate sensor

123: position sensor 124: slide door

130: exhaust duct 140: individual fume hood control unit

150: central control unit 160: normal hood

170: general hood control unit 180: air supply fan

The present invention relates to a surface speed display system of the exhaust system, more specifically, to the workplace environment management through the surface speed display system, so that workers can always observe the collection speed (surface speed) of the local exhaust system such as fume hood, The surface speed display system of the exhaust system to promote the safety and health protection of workers.

In general, the local exhaust system is applied as a method for reducing the exposure of hazardous substances to workers in the places where hazardous chemicals are handled. In particular, a fume hood in the form of a booth hood is most commonly used in a laboratory.

However, since the power of the exhaust fan is fixed, the following problems occur when the opening area changes due to the opening and closing of the front slide, such as a fume hood, or when the operation rate of individual hoods in the local exhaust system is not constant. .

First, if the front slide is designed in the middle position when designing the displacement of the fume hood, if the front slide is opened above the middle position, it becomes less than the required exhaust volume, and the collection speed (surface speed) is lowered. If it is closed below the middle, there is a problem that it is excessive than the required exhaust amount, which is an unnecessary waste factor of indoor heating and cooling and exhaust fan operating energy.

In case of designing the fume hood, the front slide is in the fully open position when designing the displacement of the fume hood, and if the front slide is closed in the fully open position even if the front slide is a little more than the required exhaust volume, unnecessary waste of indoor air-conditioning and exhaust fan operating energy There was a problem that became a factor.

In addition, when the displacement is designed based on the entire operation of the individual hoods of the local exhaust system, the amount of exhaust from the remaining hoods is excessively larger than the amount of exhaust air required by blocking some individual hoods, thereby eliminating the need for indoor air conditioning and exhaust fan operating energy. There was a problem that wasted.

In addition, it was difficult for the workers to check the collection speed of the local exhaust system at all times, especially when the front part was in the form of a slide like a laboratory fume hood, and the collection speed (surface speed) changed according to the degree of opening and closing. It is true that confirmation is necessary, but not realistically.

The object of the present invention devised to solve the above-mentioned problems is to monitor the environment of the workplace through the surface speed display system, the safety and safety of workers so that workers can always observe the collection speed (surface speed) of the local exhaust system such as a fume hood The present invention provides a variable air volume control system and a variable air volume control method for health protection.

In order to achieve the above object, the surface speed display system of the exhaust system according to the present invention includes an experiment space formed therein, which is opened by a slide door, and includes a hazardous chemical substance or a highly polluted substance exposed to an operator during operation. In the exhaust system, the average surface velocity calculated by calculating the current displacement in the exhaust duct, calculating the opening height of the slide door in front of the fume hood, calculating the opening area of the fume hood, and calculating the average surface velocity is displayed. It is characterized by.

In addition, the surface speed display system of the exhaust system according to the present invention, the slide door is installed in the front slide opening, the fume hood and the exhaust duct connected to the exhaust duct for discharging harmful chemicals or high pollutant, and the exhaust duct By measuring the wind speed of the exhaust fan exhausting harmful chemicals or highly polluted substances to the outside and the harmful chemicals or highly polluted substances discharged through the exhaust fan through the exhaust duct according to the degree of damper opening A flow rate sensor for transmitting the measured wind speed signal to the individual hood control unit, a position sensor for measuring the opening height of the slide door and transmitting the measured opening height signal to the individual hood control unit, and a wind speed signal received through the flow rate sensor Calculate the current displacement in the duct, and in the fume hood through the open height signal received through the position sensor. Applying the opening area values to calculate the average sampling rate and comprises a separate hood control for displaying the calculated value.

In addition, the flow rate sensor is characterized in that for measuring the wind speed of the harmful chemicals or highly polluted material discharged through the exhaust fan by any one of the pitot tube method, venturi tube method and orifice method.

The position sensor may measure the opening height of the slide door by using any one of a rotary sensor method, a potential sensor method, and an optical sensor method.

In addition, the individual hood control unit is characterized in that the current surface speed is lowered below a predetermined range compared to the reference surface speed, a red LED, a yellow LED if exceeding a predetermined range, characterized in that the green LED display within a certain range.

In addition, the surface speed display method of the exhaust system according to the present invention, the experiment space is formed inside, the surface of the fume hood which is opened by the slide door, the hazardous chemicals or highly polluted substances exposed to the worker during operation is discharged In the speed display system, (a) the wind speed is measured in the duct through the flow rate sensor, (b) the current exhaust volume in the duct is calculated by the individual hood control unit by the wind speed signal measured and received by the flow rate sensor and (c) measuring the opening height of the slide door through the position sensor, and (d) applying the opening area value in the fume hood in the individual hood control unit through the opening height signal measured and received through the position sensor to collect the average. Calculating the speed and (e) visually displaying the calculated average capture speed.

In addition, the step (a) is characterized in that it is measured by any one of the pitot tube method, venturi tube method and orifice method.

In addition, the step (c) is characterized in that the opening height of the slide door is measured using any one of a rotary sensor method, a potential sensor method and an optical sensor method.

Hereinafter, a plane speed display system and a plane speed display method of an exhaust system according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic structural diagram of an exhaust system according to an embodiment of the present invention.

Referring to Figure 1, the surface speed display system of the exhaust system according to the present invention, exhaust fan 110, fume hood 120, exhaust duct 130, individual fume hood control unit 140, the central control unit 150 , A general hood 160, a general hood controller 170, and an air supply fan 180.

First, the exhaust fan 110 discharges harmful chemicals or highly polluted substances discharged through the exhaust duct 130 connected to the top of the fume hood 120 and the general hood 160 to the outside.

The fume hood 120 is configured to handle chemicals that normally hinder a working environment and generate harmful gases, odor gas vapors, ie harmful chemicals or highly polluted substances, in a laboratory. It is an essential facility to maintain a pleasant laboratory work environment by discharging.

The fume hood 120 according to the present invention is a fume hood having a booth shape which is generally used in a laboratory, but is not limited thereto and may be configured in various forms.

On the other hand, the fume hood 120 according to the present invention, the slide door 124 is provided with a slide opening on the front, the interior space is connected to the exhaust duct 130 so that harmful chemicals or highly polluted substances are discharged. It is.

In addition, a position sensor 123 is installed inside the fume hood 120 to measure a gage area that varies depending on the degree of opening and closing of the slide door 124.

The position sensor 123 transmits an open height signal to each individual fume hood controller 140 according to whether or not the slide door 124 is opened or closed.

At this time, the position sensor 123 measures the opening height of the slide door 124 using any one of a rotary sensor method, a potential sensor method and an optical sensor method to measure the opening height of the slide door 124, Most preferably, the position sensor 123 according to the present invention is a rotary sensor method.

The flow rate sensor 122 measures wind speeds of harmful chemicals or highly polluted substances discharged through the exhaust fan 110 via the exhaust duct 130 according to the degree of opening of the damper 121 to individually measure the wind speed signals measured. Transmission to the fume hood control unit 140.

At this time, the flow rate sensor 122 measures the wind speed of the harmful chemicals or highly polluted substances discharged through the exhaust fan 110 according to the opening degree of the damper 121 to be described later, pitot tube method, venturi tube method and orifice While measuring by any one of the methods, the flow rate sensor 122 according to the present invention is most preferably measured by the pitot tube method.

Exhaust duct 130 is a duct (duct) that is generally used in the air exhaust system is installed so that harmful chemicals or highly polluted substances in the fume hood 120 by the operation of the exhaust fan 110. .

In addition, the damper 121 controls the wind speed of the harmful chemicals or the highly polluted substances discharged to the exhaust duct 130.

In addition, the damper 121 converts the current wind speed measured by the flow rate sensor 122 into an exhaust amount in the individual fume hood control unit 140 to be described later, and the required exhaust amount of each fume hood 120 in which the current exhaust amount is set is described above. Preferably, the degree of opening is controlled so as to be properly distributed to the hood.

When the general hood 160 detects an on or off state by the general hood control unit 170, the degree of opening is controlled as much as the required exhaust amount which is preset according to the detected state.

In addition, the general hood 160 is preferably provided with a damper 121 and a flow rate sensor 122 between the exhaust duct 130 connected to the upper portion, similar to the fume hood 120 described above.

In addition, the general hood 160 is set in advance in the general hood control unit 170 according to the required amount of necessary exhaust.

In addition, as described above, the flow rate sensor 122 and the damper 121 are installed between the general hood 160 and the exhaust duct 130, and the general hood control unit 170 detects an on or off state of the damper. In this case, the opening degree is controlled so that the current exhaust amount is appropriately distributed to the hood by the predetermined required exhaust amount of the hood according to the detected state.

The individual fume hood control unit 140 calculates a current amount of exhaust in the exhaust duct 130, calculates an average collection speed by applying an opening area value in the fume hood 120, and visually displays the calculated value, and a fume hood. Calculate the opening area of the fume hood by calculating the opening height of the front slide door 124, calculate the displacement required to obtain a constant average surface velocity at the opening of the fume hood, and transmit it to the central control unit 150.

In addition, the individual hood control unit 140 or the general hood control unit 170 is a red LED, if the current surface speed is lower than a predetermined range compared to the reference surface speed, a yellow LED, a green LED within a certain range. It may be displayed or other visual display means.

The central control unit 150 adds the required exhaust amount received from the individual fume hood control unit 140 to set the total required exhaust amount of the exhaust duct, calculates the current total exhaust amount so that the current total exhaust amount is within the set total required exhaust amount range. Control the exhaust fan to raise or lower.

In addition, the central control unit 150 sets all or a part of the sum of the necessary exhaust amounts as the total required air supply amount, converts the current wind speed signal measured by the flow rate sensor 122 into the air supply amount, and the current air supply amount is preset. The operation of the air supply fan 180 is controlled to be raised or lowered to fall within the total required air supply amount range.

The air supply fan 180 is interlocked together according to the operation of the exhaust fan 110 connected to the exhaust duct 130.

In addition, one or more fume hoods 120 may be installed in the exhaust duct 130, that is, the present invention is not limited thereto.

In addition, the individual hood control unit 140 and the general hood control unit 170 may be directly manipulated by the user to completely open the damper 121 of the fume hood 120 and the general hood 160 to maximize the exhaust.

2 is a flowchart of a surface speed display method of an exhaust system according to an exemplary embodiment of the present invention.

Referring to Figure 2, it will be described in detail with respect to the surface speed display method of the exhaust system according to an embodiment of the present invention.

First, the flow rate sensor 122 installed in the fume hood 120 measures the wind speed in the exhaust duct 130.

At this time, the flow rate sensor 122 transmits the measured wind speed signal to each individual fume hood control unit 140.

At this time, the flow rate sensor 122 measures the wind speed of the harmful chemicals or highly polluted substances discharged through the exhaust fan 110, by measuring any one of the pitot tube method, venturi tube method and orifice method, Flow rate sensor 122 according to the invention is measured in a pitot tube method (step S210).

Then, the current amount of exhaust in the exhaust duct 130 is calculated by the individual hood controller 140 through the wind speed signal measured and received through the flow rate sensor 122 (S220).

Then, the open height signal is transmitted to each individual fume hood control unit 140 according to whether the slide door 124 is opened or closed through the position sensor 123.

At this time, the position sensor 123 measures the opening height of the slide door 124 using any one of a rotary sensor method, a potential sensor method and an optical sensor method to measure the opening height of the slide door 124, Position sensor 123 according to the present invention is measured by a rotary sensor method (step S230).

Then, the average collection speed is calculated by applying the opening area value in the fume hood 120 in the individual hood controller 140 through the open height signal measured and received through the position sensor 123 (S240).

The calculated average capture rate is then visually displayed.

At this time, if the individual hood control unit 140 or the general hood control unit 170, the current surface speed is lowered below a certain range compared to the reference surface speed, a red LED, a yellow LED if the predetermined range is exceeded, a green LED within a certain range It may be displayed as, or may be displayed by other visual display means (step S250).

Then, each individual fume hood control unit 140 calculates the opening height of the slide door in front of the fume hood, calculates the opening area of the fume hood, and calculates the displacement required to obtain a constant average surface velocity at the opening of the fume hood. Send to the central control unit 150 (step 260).

At this time, the central control unit 150 sets the total required exhaust amount of the exhaust duct by summing necessary exhaust amounts received from the individual fume hood control units 140, and calculates the current total exhaust amount to set the current total exhaust amount in the total required exhaust amount range. The exhaust fan 110 is controlled to be raised or lowered so as to

Next, the central control unit 150 sets all or a part of the sum of the necessary exhaust amounts as the total required air supply amount, converts the current wind speed signal measured by the flow rate sensor 122 into the air supply amount, and provides the current air supply amount. The operation of the air supply fan 180 is controlled to be raised or lowered so as to fall within the set total required air supply amount range (step S270).

Subsequently, the individual hood controller 140 converts the current wind speed measured by the flow rate sensor 122 of the exhaust duct 130 above each fume hood 120 into an displacement, so that each fume hood having the current displacement is set. An opening degree of each damper 121 is controlled to fall within the required exhaust amount range of the 120 or the general hood 160.

In addition, the air supply fan 180 may be linked together according to the operation of the exhaust fan 110 connected to the exhaust duct 130 (step S280).

In addition, the individual hood control unit 140 and the general hood control unit 170 may be directly manipulated by the user to completely open the damper 121 of the fume hood 120 and the general hood 160 to maximize the exhaust.

The present invention is not limited to the above-described preferred embodiments and can be easily modified by anyone of ordinary skill in the art without departing from the gist of the invention claimed in the claims, Such changes are intended to fall within the scope of the claims.

As described above, the present invention is a variable that promotes workplace environment management, worker safety and health protection through a surface speed display system so that workers can always observe the collection speed (surface speed) of a local exhaust system such as a fume hood. A wind volume control system and a variable wind volume control method can be provided.

Claims (6)

In an exhaust system in which an experiment space is formed inside, opened by a slide door, and discharges harmful chemicals or highly polluted substances exposed to workers during work, A fume hood installed at a front surface of the slide door and connected to an exhaust duct for discharging harmful chemicals or highly polluted substances; An exhaust fan for exhausting harmful chemicals or highly polluted substances discharged through the exhaust duct to the outside; A flow rate sensor for measuring wind speeds of harmful chemicals or highly polluted substances discharged through the exhaust fan through the exhaust duct according to the degree of opening of the damper and transmitting the measured wind speed signals to the individual hood controllers; A position sensor for measuring the opening height of the slide door and transmitting the measured opening height signal to the individual hood controllers; And The current displacement in the duct is calculated through the wind speed signal received through the flow rate sensor, and the average capture speed is calculated by applying the opening area value in the fume hood through the open height signal received through the position sensor. An individual hood controller to display the; Surface speed display system of the exhaust system comprising a. The method of claim 1, The flow rate sensor is characterized in that for measuring the wind speed of the harmful chemicals or highly polluted substances discharged through the exhaust fan by any one of the method of the pitot tube method, venturi tube method and orifice method, the position sensor is And measuring the opening height of the slide door using any one of a rotary sensor method, a potential sensor method, and an optical sensor method for measuring the opening height of the slide door. The method of claim 1, wherein the individual hood control unit, Surface speed display system of the exhaust system, characterized in that the current surface speed is lower than a certain range compared to the reference surface speed red LED, yellow LED if the predetermined range exceeds a certain range, green LED within a certain range. In the fume hood surface speed display system is formed inside the experiment space, opened by the slide door, and discharges harmful chemicals or highly polluted materials exposed to the worker during the operation, (a) measuring wind speed in the duct through a flow rate sensor; (b) calculating the current displacement in the duct by the individual hood control unit based on the wind speed signal measured and received by the flow rate sensor; (c) measuring the opening height of the slide door through the position sensor; (d) calculating an average collection speed by applying an opening area value in the fume hood in the individual hood controller through the opening height signal measured and received by the position sensor; And  (e) visually displaying the calculated average capture speed; Surface speed display method of the exhaust system comprising a. The method of claim 4, wherein step (a) comprises: A surface velocity display method of an exhaust system, characterized in that it is measured by any one of the pitot tube method, venturi tube method and orifice method. The method of claim 4, wherein step (c) comprises: And an opening height of the slide door is measured using any one of a rotary sensor method, a potential sensor method, and an optical sensor method.

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