KR101247183B1 - Infrared ray sensor using cabinet laboratory blower driving device and measure of wind direction device - Google Patents

Abstract

PURPOSE: A blower driving and wind direction sensor using an infrared ray sensor for a laboratory cabinet are provided to generate an alarm sound in a microcontroller when an infrared ray signal is blocked according to blocking an infrared ray emitting part and an infrared ray receiving part at the same time by sinking a floating ball when the exhaust fan of a clean bench stops. CONSTITUTION: A blower driving and wind direction sensor using an infrared ray sensor for a laboratory cabinet includes an exhaust fan stop sensor(30). The exhaust fan stop sensor senses the stop of an exhaust fan in the upper part of the exhaust fan of a hood part(20). The exhaust fan stop sensor includes a cylindrical body, an upper net, a lower net, a floating ball, an infrared ray emitting part and an infrared ray receiving part, and a microcontroller(40). The cylindrical body is perpendicularly connected to a bracket(31) of the upper part of the exhaust fan. The upper net and the lower net are finished so that air is ventilated in the upper and lower part of the cylindrical body. The floating ball is made of light material floated by the flow of air inside of the cylindrical body. The infrared ray emitting part and the infrared ray receiving part are mounted to be hidden by a floating ball in the cylindrical body. The microcontroller is connected to the infrared ray emitting part and the infrared ray receiving part, monitors the driving of an exhaust fan by receiving a signal when an infrared ray emitting part and an infrared ray receiving part coincide, and generates an alarm sound when an infrared ray emitting part and an infrared ray receiving part(39) are hidden by a floating ball. [Reference numerals] (AA) Warning sound

Description

Infrared Ray Sensor using cabinet laboratory blower driving device and measure of wind direction device}

The present invention relates to a blower driving and a wind direction detection device of the laboratory cabinet using an infrared sensor, and in detail, when the exhaust fan of the clean bench constituting the laboratory cabinet is stopped, an alarm sound is generated, When the exhaust volume of the putty cabinet is smaller than the air supply volume, the alarm sound is generated when the exhaust wind blows from the canopy.

In general, laboratory cabinets keep the interior of the working chamber aseptic during laboratory studies involving animal tissues, cell cultures, and viruses in biochemistry laboratories, and prevent contaminated air from being released outside the working chamber to protect the safety of the experimenter. It is used to. Such laboratory cabinets include a clean bench and a biologic safety cabinet.

The clean bench is a device that keeps the contaminated workspace clean locally, and is used in related fields such as bioculture, pharmaceuticals, medicine, food, agriculture, and semiconductors, and protects samples from contamination in a sterile environment.

In addition, the Bioracial Separation Cabinet is a biosafety workbench that can safely handle microorganisms up to BLS (Bio safety Lavel) 1 ~ 3, which is dangerous to humans. It also protects the environment and samples, and inside it is equipped with a canopy (canopy) to reduce the risk of contamination of the examination room by passing through the air discharged into the room through the filter.

As shown in FIG. 1, a clean bench constituting such a conventional experimental cabinet includes a working chamber 100 provided with an experimental space therein for performing an experiment; It is provided in the upper region of the working chamber 100 is composed of a hood portion 200 for filtering the harmful air generated inside the laboratory to discharge to the outside.

The working chamber 100 includes a bottom panel 110, a left and right panels 120 and 130, and a rear panel 140, and a glass door 150 is provided to move upward and downward.

The hood part 200 is provided with an exhaust fan 210 for discharging the air generated during the experiment in the working chamber 100 to the outside.

However, such a conventional clean bench is possible to check whether there is an abnormality of the filtering system by detecting the pressure inside the differential pressure gauge 310, check the presence or absence of the driving of the exhaust fan to notify the user in the microcontroller 300, such as an alarm sound. do.

On the other hand, the bioradial safety cabinet is shown in Figure 2, the working chamber 100 is provided with a test space therein for experiments; It is provided in the upper region of the working chamber 100 is composed of a hood portion 200 for filtering the harmful air generated in the laboratory to discharge to the outside.

The working chamber 100 includes a bottom panel 110, a left and right panels 120 and 130, and a rear panel 140, and a glass door 150 is provided to move upward and downward.

The hood portion 200 is provided with a canopy 210 to reduce the risk of contamination by passing the air generated during the experiment in the working chamber 100, the exhaust duct 220 outside the building on the top of the canopy 210 The exhaust fan 230 is mounted on the exhaust duct 220 to discharge the polluted air to the outside.

On the other hand, the upper portion of the working chamber 100 is provided with an air supply fan 240 for supplying external air therein, the air supply fan 240 is connected so that the drive is controlled by the microcontroller 300, exhaust fan ( 230 is mounted outside the building so that the wind speed higher than the wind speed of the air supply fan 240 is maintained so that harmful substances inside the working chamber 100 is discharged to the outside. At this time, the wind speed of the air supply fan 240 is controlled by the micro-control 300 so that 0.53m / sec is maintained, the exhaust fan 230 is set higher than the wind speed of the air supply fan 240 by the program of the building itself. .

In the bioradial safety cabinet configured as described above, since the exhaust fan 230 has a higher wind speed (0.53 m / sec) than the air supply fan 240, the air inside the laboratory is provided through the exhaust duct 220 and the exhaust fan 230. When discharged to the outside, the air supply air (A) is blown into the air balance hole (211) of the canopy 210, the exhaust is normally made.

On the other hand, if the wind speed of the air supply fan 240 is higher than the wind speed of the exhaust fan 230, the exhaust volume is less than the air supply amount, the exhaust air (B) is blown out to the outside of the air balance hole 211 of the canopy 210 is contaminated Air leaks into the lab and is dangerous.

This state is compared with the detection of the differential pressure gauge 310 mounted on the exhaust duct 220 and the wind speed set by the micro control 300 to lower the wind speed of the air supply fan 240 in the micro control 300, and the micro control. If out of the set wind speed range of 300, the microcontroller 300 will notify the user with an alarm sound.

However, the differential pressure gauge detects whether the exhaust fan drive of the clean bench and the exhaust wind speed of the bioracial safety cabinet are lower than the supply wind speed, respectively, and the microcontroller notifies the user with an alarm sound. In addition to the high price of the expensive product, the problem is that the electronic drive is broken.

The present invention has been made to solve such a conventional problem, the object of the present invention is to stop the infrared fan of the clean bench constituting the experimental cabinet by sinking the floating ball constituting the exhaust fan stop detection sensor to block the infrared rays There is no infrared signal on the light-receiving side, and the microcontroller provides an experimental cabinet blower driving apparatus using an infrared sensor configured to generate an alarm sound when there is no infrared signal during operation.

It is another object of the present invention to provide a second infrared light emitting unit and an infrared light receiving unit by the exhaust wind when the exhaust volume of the bioradial safety cabinet constituting the experimental cabinet is less than the air supply and the exhaust wind B is blown from the canopy. In accordance with the present invention, there is provided a blower wind direction detection device for an experimental cabinet using an infrared sensor configured to generate a warning sound from a microcontroller by this signal.

Means for Solving the Problems The present invention includes a working chamber provided with a test space therein for experiments; An experimental cabinet provided in an upper region of the working chamber and comprising a hood part for filtering harmful air generated inside a laboratory to be discharged to the outside, an exhaust fan stop detection for detecting a stop of an exhaust fan on an upper part of an exhaust fan of the hood part It is characterized by mounting a sensor.

In addition, the present invention is provided with an experimental space therein working chamber for performing experiments; In an experimental cabinet provided in the upper region of the working chamber and composed of a hood for filtering out harmful air generated inside the laboratory to the outside, the exhaust volume is less than the air supply by detecting the wind direction of the air supply fan inside the canopy of the hood It is characterized in that the wind direction sensor for detecting the blowing of the exhaust wind (B) outside the air balance hole of the canopy.

According to the present invention, if the exhaust fan of the clean bench constituting the experimental cabinet stops during operation or is driven but is not driven, the floating ball constituting the exhaust fan stop detection sensor sinks and simultaneously the infrared light emitting unit and the infrared light receiving unit. By blocking, the infrared signal cannot be transmitted, and the microcontroller can be configured to generate an alarm sound for simple and reliable checking.

In addition, the present invention is the first infrared rays constituting the wind direction detection sensor by the exhaust wind when the exhaust volume of the bioradial safety cabinet constituting the experimental cabinet is less than the air supply amount and the exhaust wind B is blowing in the canopy. The light emitting unit and the infrared light receiving unit coincide with each other so that an alarm sound is generated by the microcontroller so that simple and reliable inspection can be performed.

1 is a configuration diagram schematically showing a clean bench of a conventional laboratory cabinet.
Figure 2 is a schematic view showing a bioradial safety cabinet of the conventional laboratory cabinet.
Figure 3 is a schematic diagram showing a clean bench of the laboratory cabinet equipped with a blower driving apparatus of the laboratory cabinet using the infrared sensor according to the present invention.
4A and 4B are diagrams illustrating main parts driving states of FIG. 3;
Figure 5 is a schematic view showing a configuration of a bio-racial safety cabinet of the experimental cabinet equipped with an experimental cabinet blower wind direction detection apparatus using an infrared sensor according to the present invention.
6A, 6B, and 6C are diagrams showing the principal part driving states of FIG.

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

3 is a schematic diagram illustrating a clean bench of an experimental cabinet equipped with an experimental cabinet blower driving apparatus using an infrared sensor according to the present invention.

As shown, the clean bench of the laboratory cabinet according to the present invention is provided with a working chamber (10) for experiments provided therein; It is provided in the upper region of the working chamber 10 is composed of a hood portion 20 for filtering the harmful air generated inside the laboratory to discharge to the outside.

The working chamber 10 includes a bottom panel 11, left and right panels 12 and 13, and a rear panel 14, and a glass door 15 is provided at a front thereof so as to be movable up and down.

The hood part 20 includes an exhaust fan 22 through which air generated during the experiment in the working chamber 10 is discharged to the outside.

An exhaust fan stop detection sensor 30 for detecting a stop of the exhaust fan 22 is mounted on an upper portion of the exhaust fan 22 of the hood part 20.

The exhaust fan stop detection sensor 30 includes a cylindrical body 32 mounted in vertical communication with the bracket 31 on the upper side of the exhaust fan 22; An upper mesh 33 and a lower mesh 34 closed by maintaining an appropriate mesh to allow air to flow through the upper and lower portions of the cylindrical body 32; The cylindrical body 32 is made of a floating ball 36 made of a light material (styrofoam, etc.) to rise by the flow of air.

The cylindrical body 32 is equipped with an infrared light emitting unit 38 and an infrared light receiving unit 39 so that the position is blocked by the floating ball 36.

 In this case, when the exhaust fan 42 is normally driven, the floating ball 36 is driven as shown in FIG. 4B by driving the exhaust fan 22 while the floating ball 36 is positioned in the lower net 34 as shown in FIG. 4A. ) Is raised from the lower net 34 and the infrared signal irradiated to the infrared light emitting unit 38 is received by the infrared light receiving unit 39, and the microcontroller 40 recognizes that the exhaust fan 22 is normally driven. Done.

However, if the floating ball 36 is positioned in the lower net 34 as shown in FIG. 4A while the exhaust fan 22 is being driven, the infrared light emitting portion 38 and the infrared light receiving portion 39 are formed by the floating ball 36. The hidden microcontroller 40 detects an abnormal rotation of the exhaust fan and generates an alarm sound.

On the other hand, Figure 5 is a schematic diagram showing the configuration of the laboratory cabinet of the experimental cabinet equipped with a laboratory cabinet blower wind direction detection apparatus using an infrared sensor according to the present invention, which is a clean bench of the laboratory cabinet of Figure 3 The same names and symbols will be used for the same structures.

As shown, the bioradial safety cabinet of the laboratory cabinet according to the present invention, the working chamber 10 is provided with an experimental space therein for experiments; It is provided in the upper region of the working chamber 10 is composed of a hood portion 20 for filtering the harmful air generated inside the laboratory to discharge to the outside.

The working chamber 10 includes a bottom panel 11, left and right panels 12 and 13, and a rear panel 14, and a glass door 15 is provided at a front thereof so as to be movable up and down.

The hood portion 20 is provided with a canopy 50 formed with an air balance hole 51 for reducing the risk of contamination by passing the air generated during the experiment in the working chamber 10, the upper portion of the canopy 50 An exhaust duct 52 is connected to the outside of the building, and an exhaust fan 54 is mounted on an upper portion of the exhaust duct 52 to discharge contaminated air to the outside.

On the other hand, an air supply fan 56 for supplying external air to the upper region of the working chamber 10 is mounted, the air supply fan 56 is connected so that the driving is controlled by the microcontroller 40, exhaust The fan 54 is located outside the building so that the wind speed higher than the wind speed of the air supply fan 56 is maintained so that harmful substances inside the working chamber 10 are discharged to the outside.

At this time, the wind speed of the air supply fan 56 is controlled by the micro control 40 so that 0.53m / sec is maintained, and the exhaust fan 54 is set higher than the wind speed of the air supply fan 56 by the control program of the building itself. do.

The canopy 50 senses the wind direction due to the wind speed of the air supply fan 56 to detect that the exhaust wind B is blown out of the air balance hole 51 of the canopy 50 because the displacement is less than the air supply amount. The wind direction sensor 60 is mounted.

The wind direction sensor 60 has a cylindrical body (62) mounted horizontally in communication with the air balance hole (51) on one side of the canopy (50); A left mesh 63 and a right mesh 64 closed by maintaining a proper mesh to allow air to pass through the left and right sides of the cylindrical body 62; It consists of a film plate 66 mounted as a hinge 66a so as to be rotatable by the flow of air inside the cylindrical body 62.

Signals are transmitted to the left, right, and center regions of the cylindrical body 62, and are selectively shielded by the film plate 66, the first infrared light emitting portion 67, the second infrared light emitting portion 68, and the infrared light receiving portion. 69 are mounted respectively.

That is, the first infrared light emitting portion 67 and the second infrared light emitting portion 68 are respectively mounted on the left and right sides of the cylindrical body 62 around the film plate 66 inside the cylindrical body 62. The infrared light receiving portion 69 is mounted in the central region.

At this time, when the air supply fan 56 and the exhaust fan 54 are in a stopped state, as shown in FIG. 6A, when the film plate 66 is vertically erected, the film plate 66 may be the first and second infrared light emitting parts 67 and 68. ) And the infrared light receiving unit 69 are not blocked at the same time, so that the infrared signal generated by the first infrared light emitting unit 67 and the second infrared light emitting unit 68 is transmitted to the infrared light receiving unit 69.

In addition, when the exhaust fan 54 and the air supply fan 56 are normally driven and the amount of exhaust gas through the duct is larger than the air supply amount, as shown in FIG. 6B, the air supply air A may flow into the air balance hole 51 of the canopy 50. ) And the air inside the contaminated laboratory is discharged through the exhaust duct (52).

At this time, the film plate 66 is rotated to the left centering around the hinge 66a, so that the infrared signal of the second infrared light emitting unit 68 is transmitted to the infrared light receiving unit 69 and the first infrared light emitting unit 67 As the infrared rays are blocked, the signal is received by the microcontroller 40 and compared with its own program to detect that the air supply and exhaust air volumes are normal.

In addition, if the air volume of the exhaust fan 54 is smaller than the air volume of the air supply fan 56 or the exhaust fan 54 is stopped, exhaust air is blown out of the air balance hole 51 of the canopy 50 as shown in FIG. 6C. The air inside the laboratory contaminated by (B) is flowed back into the working chamber 10, and the experimenter is in a dangerous state.

At this time, the film plate 66 is rotated to the right around the hinge 66a, so that the infrared signal of the first infrared light emitting unit 67 is transmitted to the infrared light receiving unit 69 and the second infrared light emitting unit 68 As the infrared signal is blocked, the microcontroller 40 receives the signal and compares it with the wind speed inputted by the microcontroller 40, thereby lowering the wind speed of the air supply fan 56. If the microcontroller 40 is out of the set wind speed range, the microcontroller ( 40) will generate an alarm sound.

The operating state according to the present invention configured as described above will be described schematically.

Referring to the operating state of the clean bench of the experimental cabinet as shown in Figure 3, the experiment is performed in the working chamber 10 constituting the clean bench of the experimental cabinet. When the exhaust fan 22 is stopped during the experiment, the cylindrical body 32 constituting the exhaust fan stop detection sensor 30 mounted on the exhaust fan 22 upper portion of the hood portion 20 as shown in FIG. 4A. The floating ball 36 is positioned in the lower mesh 34, so that the infrared light emitting unit 38 and the infrared light receiving unit 39 are blocked by the floating ball 36 to block the infrared signal.

Then, the microcontroller 40 can determine the state and generate an alarm sound so as to inform the user and take prompt action.

In addition, when the exhaust fan 22 operates normally as shown in FIG. 4B, the floating ball 36 is driven by the exhaust fan 22 while the floating ball 36 is positioned in the lower mesh 34. The infrared signal radiated from the 34 and irradiated from the infrared light emitting unit 38 is received by the infrared light receiving unit 39, and the signal is transmitted to the microcontroller 40 so that the polluted air inside the experiment is normally discharged to the outside. It will be recognized.

On the other hand, it will be described the operating state of the bio-racial separation cabinet of the laboratory cabinet according to the invention shown in FIG.

First, as shown in FIG. 6A, when the exhaust fan 54 and the air supply fan 56 are not driven, the film plate 66 is erected vertically, so that the film plate 66 is the first and second infrared light emitting units 67. (68) and the infrared light receiving unit 69 are not blocked at the same time, the infrared signal generated from the first infrared light emitting unit 67 and the second infrared light emitting unit 68 is transmitted to the infrared light receiving unit 69 to the microcontroller 40 ) Detects that the air supply fan 54 and the exhaust fan 56 are stopped.

As shown in FIG. 6B, the exhaust fan 54 is higher than the wind speed of the air supply fan 56 (0.53 m / sec), so that the air supply air A blows into the air balance hole 51 of the canopy 50 to contaminate the laboratory. When the air inside is normally discharged to the outside through the exhaust duct 52, the film plate 66 is rotated to the left side about the hinge 66a by the air supply air A, and the 2nd infrared light emitting part The infrared signal of the 68 is transmitted to the infrared light receiving unit 69 and the infrared signal of the first infrared light emitting unit 67 is blocked so that the signal is received by the microcontroller 40 and compared with the input program. It is sensed that the air is normally discharged to the outside through the exhaust duct 52.

As shown in FIG. 6C, when the wind speed B of the air supply fan 56 is higher than the wind speed of the exhaust fan 54, the exhaust wind B is blown out of the air balance hole 51 of the canopy 50. Contaminated air flows out of the cabinet, putting the experimenter at risk.

At this time, the film plate 66 is rotated to the right around the hinge 66a by the exhaust wind B, so that the infrared signal of the first infrared light emitting unit 67 is transmitted to the infrared light receiving unit 69 and the second light is emitted. As the infrared signal of the infrared light emitting unit 68 is blocked, the signal is received by the microcontroller 40 and compared with the input wind speed to lower the wind speed of the air supply fan 56, and the input wind speed of the micro control 40 is reduced. If it is out of range, the microcontroller 40 generates an alarm sound so that the user can be promptly taken.

Experimental cabinet blower driving and wind direction check apparatus using the infrared sensor according to the present invention described above is not limited to the above embodiment, the present invention belongs without departing from the gist of the invention claimed in the claims below Anyone with ordinary knowledge in the field will have the technical idea to the extent that various modifications can be made.

10: working chamber 20: hood
22: exhaust fan 30: exhaust fan stop detection sensor
31: bracket 32: cylindrical body
33: upper net 34: lower net
36: injury ball 38: infrared light emitting unit
39: infrared light receiving unit 40: microcontroller
50: canopy 51: air balance hall
54 exhaust fan 56 air supply fan
60: wind direction sensor 62: cylindrical body
63: left mesh 64: right mesh
66 film plate 67, 68 first and second infrared light emitting portion
69: infrared light receiving unit A: air supply wind
B: exhaust wind

Claims (4)

A working chamber 10 provided with an experiment space therein for experimenting;
In the experiment cabinet provided in the upper region of the working chamber 10 consisting of a hood portion 20 for filtering out harmful air generated in the laboratory to the outside,
The exhaust fan stop detection sensor 30 for detecting the stop of the exhaust fan 22 is mounted on the exhaust fan 22 of the hood portion 20,
The exhaust fan stop detection sensor 30
A cylindrical body (32) mounted in vertical communication with the bracket (31) above the exhaust fan (22);
An upper mesh 33 and a lower mesh 34 closed to allow air to flow through the upper and lower portions of the cylindrical body 32;
A floating ball 36 made of a light material which is floated by the flow of air inside the cylindrical body 32;
An infrared light emitting unit 38 and an infrared light receiving unit 39 mounted on the cylindrical body 32 so as to be hidden by the floating ball 36;
It is connected to the infrared light emitting unit 38 and the infrared light receiving unit 39 to receive a signal when the infrared light emitting unit 38 and the infrared light receiving unit 39 coincide with each other to monitor the driving of the exhaust fan 22, and the floating ball 36 Blower of the experimental cabinet using an infrared sensor, characterized in that consisting of a micro-controller 40 for generating an alarm sound when the infrared light emitting unit 38 and the infrared light receiving unit 39 is covered. delete A working chamber 10 provided with an experiment space therein for experimenting;
In the experiment cabinet provided in the upper region of the working chamber 10 and consists of a hood portion 20 for filtering the harmful air generated inside the laboratory to the outside,
The exhaust wind B is blown to the outside of the air balance hole 51 of the canopy 50 by detecting the wind direction of the air supply fan 56 in the canopy 50 of the hood 20 so that the displacement is less than the air supply amount. Equipped with a wind direction sensor 60 for detecting that,
The wind direction sensor 60 is
A cylindrical body (62) mounted horizontally in communication with an air balance hole (51) at one side of the canopy (50);
A left mesh 63 and a right mesh 64 closed to allow air to pass through the left and right sides of the cylindrical body 62;
A film plate (66) rotatably mounted by a flow of air in a central region inside the cylindrical body (62);
The first infrared light emitting unit 67 and the second infrared light emitting unit 68 are mounted on the left, right and center regions of the cylindrical body 62, and mutual signals are transmitted and are selectively covered by the film plate 66. ) And an infrared light receiving unit 69;
When the first infrared light emitting unit 67, the second infrared light emitting unit 68 and the infrared light receiving unit 69 are connected to each other, the first and second infrared light emitting units 67 and 68 and the infrared light receiving unit 69 coincide with each other. The signal is transmitted to monitor the stop state of the exhaust fan 54 and the air supply fan 56, and when the second infrared light emitting unit 68 and the infrared light receiving unit 69 match, the air supply fan 54 is received. Is driven, the wind of the experimental cabinet using an infrared sensor, characterized in that the first infrared light emitting unit 67 and the infrared light receiving unit 69 is configured to include a micro-controller 40 to receive this signal to generate an alarm sound. Direction sensor.
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