KR19990046544A - Suction and discharge apparatus for experimetal fume hood - Google Patents

Abstract

The present invention relates to a gas intake and exhaust device of an experimental fume hood.

In the present invention, a predetermined experimental space is formed inside the housing, and an open part of the experimental space is provided with a sliding door to open and close, and a suction fan for suctioning and discharging harmful gas in the laboratory space on the upper side of the housing. An installed fume hood, comprising: a sensor mounted in a sliding section of a door at a surface of a housing opposite to a sliding surface of the door; A sensing tool mounted to face the sensor at one side of the sliding surface of the door to operate the sensor; A plurality of resistors electrically connected to each of the plurality of sensors, the plurality of resistors having a progressively small value in the direction in which the door is opened; And a suction fan drive unit electrically connected to the respective sensors and the resistors, the suction fan driving unit configured to receive a detection signal of each sensor to operate the suction fan.

Therefore, the present invention allows the suction power of the suction fan to be changed according to the degree of opening and closing of the door, thereby saving the electric power supplied to the suction fan, and thus the temperature change inside the laboratory is independent of the degree of opening and closing of the door. By minimizing it, it is possible to perform more accurate experiments, as well as to reduce the waste of electrical and chemical fuel for indoor cooling and heating in winter or summer.

Description

Gas intake and exhaust device of experimental fume hood {SUCTION AND DISCHARGE APPARATUS FOR EXPERIMETAL FUME HOOD}

The present invention relates to a gas suction and discharge device (hereinafter, abbreviated as suction and discharge device) of an experimental fume hood, and more specifically, to a change in the degree of opening and closing of a door to block the laboratory from the outside. By changing the suction power of the harmful gas, it is possible to provide the accuracy of the experiment, to minimize the power loss by the suction fan and to reduce the fuel loss of the cold and heater types to maintain the proper temperature in the laboratory. will be.

The experimental fume hood is installed in the laboratories of various research institutes performing chemical experiments, so that experiments in which noxious gas is generated can be performed in the test space inside, and various harmful gases generated at this time This allows the researchers to conduct the experiment outside the laboratory so that the researchers performing the experiment do not suffer any health damage from contact with harmful gases.

In the conventional fume hood, which has appeared for the above reason, an experimental space is formed inside the housing that is the exterior, and suction means for sucking various harmful gases generated when the experiment is performed in the experimental space are mainly located on the upper side of the housing. It is mounted, the door is configured to slide up and down on the open side of the laboratory to block or expose the laboratory to the outside.

In addition, the suction means is naturally connected to the discharge pipe for discharging the harmful gas sucked to the outside of the laboratory.

Such fume hood ensures that the suction and discharge devices are operated at all times to prevent the harmful gas from entering the laboratory during the experiment. Discharged.

However, if the fume hood is used for a long time or the fume hood is used for a long time in order to open the door to supply the laboratory air to the test space as described above, the entire temperature inside the lab suddenly changes and the experiment is obtained by the experiment. Errors can occur in the data.

In addition, when the above-mentioned fume hood is used in winter or summer, a large amount of air in the laboratory is discharged to the outside, and thus the consumption of fuels (electrical and chemical fuels) is reduced in response to the low or high temperature of the heater and the heater. The space inside the laboratory is large, and when using several fume hoods, it is difficult to maintain the temperature of the room with one cold and heater, which causes economic problems of having to separately purchase several cold and heaters.

To summarize the factors of such a problem, regardless of the minimum or complete opening of the door, the motor generating the suction and discharge force of the suction and discharge device is rotated at a higher speed than necessary and rapidly sucks air into the experimental space. This is due to the principle idea that the damage caused by the contact of harmful gases can be reduced.

On the other hand, it causes not only enormous power loss, but also the destruction of proper and comfortable temperatures in the laboratory, causing further health problems and fuel loss.

Therefore, the present invention was devised to solve the above problems, so that the rotational force of the motor is changed according to the degree of opening and closing of the door installed in the experiment space inside the fume hood, the air in the laboratory more than necessary It is an object of the present invention to provide a suction and discharge device that can minimize the temperature change when the door is fully opened or closed by preventing the suction.

1 is a perspective view showing a fume hood according to the present invention.

Figure 2 is a schematic cross-sectional view showing the internal configuration of the fume hood according to the present invention.

Figure 3 is a schematic diagram showing the main configuration of the suction and discharge device according to the present invention.

Figure 4 is a side cross-sectional view showing a sensor and a sensor applied to the suction and discharge device according to the present invention.

5a to 5c is an exemplary view showing a state in which harmful gas is sucked and discharged in the fume hood according to the present invention.

<Explanation of symbols for main parts of the drawings>

10: housing 11: experiment space 12: suction grill

13: door frame 14: door 15: suction fan drive unit

16: suction fan 17: detection port 18: suction line

19: branch plate S1-S5: sensor R1-R5: resistance

In order to achieve the above object, the present invention has the following features.

According to the present invention, a predetermined experimental space is formed inside the housing, and an open part of the experimental space is provided with a sliding door to be opened and closed, and a suction fan is installed at the upper side of the housing to suck and discharge noxious gas in the experimental space. A fume hood, comprising: a sensor mounted in a sliding section of a door at a surface of a housing opposite to a sliding surface of the door; A sensing tool mounted to face the sensor at one side of the sliding surface of the door to operate the sensor; A plurality of resistors electrically connected to each of the plurality of sensors, the plurality of resistors having a progressively small value in the direction in which the door is opened; And a suction fan driving unit electrically connected to the respective sensors and the respective resistors, and configured to receive a detection signal of each sensor to operate the suction fan.

Therefore, in the present invention, the sensor detects the degree of opening and closing of the door, and the signal sensed by the sensor is input to the suction fan driver through a resistance to adjust the suction force of the suction fan.

In addition, the present invention is a predetermined experimental space is formed in the interior of the housing, the fume hood is installed on the upper side of the housing for suction and discharge the harmful gas in the laboratory space, the experimental space in the experimental space 2 It is to be divided into zones, but the area of the rear side is to be divided narrower than the area of the front side, and is installed while maintaining a predetermined distance from the bottom surface of the experimental space, characterized in that it comprises a branch plate installed so that the areas of both sides pass through. .

Therefore, gas lighter than specific air of the gas generated in the test space during the experiment floats upward and is sucked and discharged by the suction fan, and gas lighter than specific air is settled to the bottom surface of the test space by the branch plate. By being sucked through the narrow passage formed, it is eventually sucked into the suction fan and discharged.

Hereinafter, an embodiment of the present invention having the features as described above will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an external configuration of a fume hood to which a suction and discharge device according to the present invention is applied.

Referring to Figure 1, the fume hood according to the present invention is a predetermined experimental space 11 is formed in the interior of the housing 10, the open front of the experimental space 11 can be opened and closed by sliding up and down. One door 14 is installed, and when the door 14 blocks the experiment space 11 in the part of the housing 10 corresponding to the front upper side of the experiment space 11, the air flows into the experiment space 11. A suction grill 12 for sucking the air is mounted.

Here, the suction grill 12 serves as a passage for intake of air, and it is possible to form only a suction hole without the suction grill 12 so that only one passage is formed so that the air can be sucked. do.

Here, in order to open and close the door 14, the door frame body 13 is installed on the left and right sides of the open part of the test space.

2 is a schematic cross-sectional view conceptually illustrating a side cross-sectional view of FIG. 1.

Referring to FIG. 2, a suction fan 16 is installed on the upper side of the housing, and a suction pipe is disposed on the upper surface of the housing 10 to suck air in the experiment space 11 when the suction fan 16 is operated. 18 is installed.

The suction fan 16 is connected to a discharge pipe (not shown) for discharging the sucked air to the outside of the laboratory.

The experimental space 11 is divided into two zones by the branch plate 19, the rear side of the area is divided into narrower than the front side of the area, the branch plate 19 and the predetermined bottom surface of the experimental space (11). It is installed while keeping the distance between the two sides of the passage.

Figure 3 is a schematic diagram showing the electrical wiring state of the suction and discharge device according to the invention and the state they are installed in the door.

Referring to FIG. 3, a sensing opening 17 is mounted at a lower end of the door 14, and a door is provided on a surface of the door frame 13 opposite to a surface of the door 14 on which the sensing opening 17 is mounted. In the section in which 14 is slid up and down, a plurality of sensors (5 in the figure) are mounted at regular intervals.

Each of the sensors S1-S5 is electrically connected to the suction fan driver 15, and resistors R1-R5 are interfering with each other between the suction fan driver 15 and each of the sensors S1-S5. .

Here, each of the resistors R1-R5 has a smaller resistance value as it is mounted closer to the upper side of the experiment space 11, and the uppermost resistor R1 may not be present.

The suction fan driver 15 is electrically connected to the suction fan 16, and the suction fan 16 is mainly used in which an impeller is mounted on the motor, and the suction fan driver 15 drives the motor. What is necessary is just a general drive driver which consists of a combination of electronic and electrical elements.

Figure 4 is a cross-sectional side view showing a sensor and a sensor in the suction and discharge device according to the present invention.

Referring to Figure 4, the sensor (S1-S5) applied to the suction and discharge device according to the present invention is a switch that is moved to the sensing sphere 17 when the magnetic sensing sphere 17 is located in the magnetic field section (M) It is a switch structure comprised of the member 20 and the electrically conductive plate 21 which is energized in contact with this switch member 20.

Here, the configuration of the sensor (S1-S5) as described above is just one example, and if the electrical connection with the resistor (R1-R5), the suction fan drive unit 15 and can detect the detection port 17 of any way. It is okay.

The operation state of the suction and discharge device having the configuration as described above and the action generated at this time will be described in detail with reference to the accompanying drawings.

When the researcher performs the experiment by placing the experimental material on the bottom surface of the experiment space 11, the harmful gas generated at this time is sucked into the suction pipe 18 by the suction fan 16 to discharge the discharge pipe connected to the suction fan 16. Through the outside of the laboratory.

5A to 5C are cross-sectional views illustrating a state in which harmful gas and air are sucked in accordance with the extent to which the researcher opens the door 14 when the harmful gas is sucked and discharged by the suction fan 16 as described above.

FIG. 5A illustrates a state in which the door 14 is completely opened. At this time, the detection port 17 mounted on the door 14 is detected by the sensor S1 at the top of the experiment space 11. The sensed signal is input to the suction fan driver 15 through the resistor R1.

At this time, as in the above description of FIG. 3, the resistance R1 mounted on the sensor S1 has the lowest resistance value or the suction force generated by the suction fan 16 because the resistance R1 does not exist. Is the maximum state.

The reason why the maximum suction force should be generated when the door 14 is fully opened as described above is that when the air in the laboratory flowing into the experiment space 11 is larger than the suction force of the suction fan 16, the inside of the experiment space 11 is increased. Is to prevent the harmful gas from leaking into the laboratory from the experimental space 11 and spreading. If the suction power is the suction force that the suction fan should have in the conventional fume hood and generate the suction force regardless of the open / closed state of the door, Are satisfied.

5B shows a state in which the door 14 is half-opened. At this time, the detection port 17 mounted on the door 14 is detected by the sensor S3, and the suction fan 16 is operated by the same action as described above. Is operated, and the resistance value of the resistor R3 at this time has a higher resistance value than the resistance R1 described above, so that the suction fan 16 is larger than the suction force generated by the suction fan 16 of FIG. 5A. It has a low suction power.

FIG. 5C illustrates a state in which the door 14 is completely closed. At this time, the detection port 17 mounted on the door 14 is detected by the sensor S5 mounted at the bottom of the experiment space 11. In this case, since the resistance R5 has the highest resistance value compared to the above-described resistances R1 and R3, the suction fan 16 has a suction force lower than the suction force generated by the suction fan 16 of FIGS. 5A and 5B. Will have

Here, the suction force of the suction fan 16 in the state in which the door 14 is closed as shown in FIG. 5c is at least sufficient to suck and discharge the air introduced into the experiment space 11 and the air flowing into the suction grill 12. Since the suction force when the door 14 is opened is increased by the gradually decreasing resistance value of the resistors R5-R1 already installed, the basic suction force is set when the door 14 is closed. It is preferable to make a reference.

In addition, since the suction force is changed in response to the opening / closing degree of the door 14 as described above, the temperature change in the experiment space 11 can be reduced to a minimum, which is the largest influence on the suction force of the suction fan 16. It is possible to reduce the electric power supplied to the motor to cause a.

In addition, even when the door 14 is completely closed, the change in temperature is minimized, so that the door 14 may always be closed or only slightly opened when the experiment is performed. It becomes possible.

In addition, the gas generated when performing the experiment in the above operating state is divided into relatively lighter and heavier than the air, the light gas is diffused to the upper side of the experimental space 11 is sucked by the suction fan 16 and The heavy gas is discharged to sink to the bottom of the experiment space 11, the gas sinked to the bottom is sucked into the suction fan 16 through the passage formed into a narrow space by the branch plate 19 is discharged.

The reason why the heavy gas sinking to the bottom is sucked into the suction fan 16 through the passage formed into the narrow space is because the suction force applied in the narrow suction passage is stronger than the wide suction passage when the same suction force is applied, which is already As a well-known fact of fluidology, the present invention applies its principles.

As described above, the present invention allows the suction power of the suction fan to be changed according to the degree of opening and closing of the door, thereby saving electric power supplied to the suction fan, and thus, regardless of the degree of opening and closing of the door. By minimizing the internal temperature change, it is possible to perform more accurate experiments, as well as to reduce the waste of electrical and chemical fuel for indoor cooling and heating in winter or summer.

In addition, the aforementioned splitter plate divides the inside of the experiment space into two zones, but one side is wider and one side is formed with a narrow passage, so that even the heavy gas that has sunk at the bottom of the experimental space can be discharged to increase the suction efficiency of harmful gases. It has the effect of making it possible.

Claims (2)

A predetermined experimental space is formed inside the housing, and an open part of the experimental space is provided with a door that is opened by sliding, and a fume hood having a suction fan installed at an upper side of the housing for suctioning and discharging harmful gas in the laboratory space. In A plurality of sensors mounted in a sliding section of the door at a surface of the housing opposite to the sliding surface of the door; A sensing tool mounted to face the sensor at one side of the sliding surface of the door to operate the sensor; A plurality of resistors electrically connected to each of the plurality of sensors, the plurality of resistors having a progressively small value in the direction in which the door is opened; And Electrically connected to each sensor and each resistor, the gas suction and exhaust device of the experimental fume hood comprising a suction fan drive for operating the suction fan in response to the detection signal of each sensor. In a fume hood provided with a predetermined experimental space in the housing, the suction fan is installed on the upper side of the housing for suction and discharge of harmful gas in the laboratory space, The test space is divided into 2 zones within the test space, but the area at the rear side is divided to be narrower than the area at the front side, and is installed while maintaining a predetermined distance from the bottom surface of the test space so that the areas at both sides pass through. Gas intake and exhaust of the experimental fume hood, characterized in that it comprises a branch plate.