KR20230038943A - Work-In Fume hood - Google Patents

Abstract

The present invention relates to a walk-in fume hood, which is installed to form negative pressure by controlling the opening and closing of a damper and the rotational speed of a ventilator so that the air discharged from the fume hood can be discharged while maintaining a constant surface wind speed, wherein two or more walk-in type doors sliding to be opened and closed in a horizontal direction are installed in front of the fume hood, and the doors have a sensing means at the bottom to sense the movement amount of a plurality of doors by a single sensor coming in contact with one side of the doors.

Description

Work-In Fume hood

In the present invention, the air discharged from the fume hood is installed to discharge the air inside the experiment space to form negative pressure by controlling the opening and closing of the damper and the rotation speed of the ventilator so that the air discharged from the fume hood maintains a constant surface wind speed, and is installed in front of the fume hood Two or more doors are installed in a walk-in method that slides open and close in the horizontal direction, and a sensor is installed at the bottom of the door to detect the amount of movement of multiple doors by a sensor contacting one side of the door. A walk-in fume hood equipped with a sensing means It is about.

In general, laboratory benches or lab workstations are installed in laboratories, laboratories, operating rooms, etc., and are used as a means of serving as a kind of work bench when conducting various chemical experiments or organ harvesting. There are a shelf type equipped with a shelf, a sink type equipped with a sink on the top plate, and a fume hood equipped with a hood on the top and a door equipped with a protective window on the front that can be opened and closed.

The fume hood as described above is installed in laboratories of various research institutes conducting chemical experiments or organ harvesting, or in water supply rooms of various hospitals, so that experiments or operations generating harmful gases can be performed in the space inside the work chamber. It is possible to discharge various harmful gases to the outside so that researchers or workers conducting experiments or working do not suffer from health damage due to contact with harmful gases.

In addition, a conventional fume hood has an open door that can be opened and closed on the front of the hood, and a by-pass type grill is installed on the door so that supplementary air can flow in when all doors are closed is installed, an exhaust duct is connected to the hood, and a baffle is installed inside the fume hood to form a uniform exhaust force at the opening to exhaust in the form of a slot, and harmful substances such as fume are removed from the local exhaust system. It is treated through exhaust ducts and air purifiers.

That is, the hood is installed within the affected area to prevent the spread of contaminants such as fumes and harmful substances (hereinafter referred to as 'harmful substances') generated in the laboratory or operating room to the surroundings of the researcher or worker or the laboratory or operating room. It can be said to be the inlet of the local exhaust system to collect hazardous substances directly from the source.

On the other hand, when using the hood as described above, the researcher or worker handles the harmful substance with the door partially open, which is to maintain the wind pressure at the opening surface, in other words, the flow velocity at the maximum for the same air volume.

Further, the hood is simply an exhaust or control device that calculates the exhaust amount according to the degree of opening and closing of the door, and controls the acceleration or deceleration of the exhaust fan so that the exhaust is made with the calculated exhaust amount.

In relation to this technology, the applicant of the present invention has presented a technology of a surface wind speed control system of a fume hood in Patent No. 1065512, and the configuration is as shown in FIG. 1, the fume hood 10, the controller 20, It includes a sensor 30, a damper 40, and a blower 50.

In addition, the fume hood 10 has a work space formed therein, a door 11 is provided to be opened and closed vertically on the front side, and an exhaust duct 12 for discharging harmful gases to the outside is provided on the rear upper portion, The controller 20 controls the surface wind speed inside the fume hood 10, and the controller 20 includes an A/D converter that converts an analog signal into a digital signal and a memory storing an algorithm necessary for control operation, the A microprocessor that operates under the control of an algorithm stored in a memory, a keypad for inputting a predetermined cotton wind speed into the microprocessor, and a display unit for displaying the cotton wind speed input to the keypad and the operating state of the fume hood 10.

However, the fume hood as described above has a configuration in which the degree of opening of the door 11 is constantly opened toward the top or closed toward the bottom, so that the open and closed state of the door 11 can be accurately and quickly grasped. Although the wind speed value can be easily derived, there is a problem in that it is difficult to apply it to the walk-in type fume hood that is opened and closed by sliding in the horizontal direction.

An object of the present invention to improve the conventional problems as described above is to make it possible to calculate an accurate surface air velocity value regardless of the opening direction of the door, and to check the accurate open and closed state regardless of the opening direction of the door. It is to provide a walk-in fume hood that can be manufactured and installed with a simple configuration, and can accurately grasp the amount of opening of multiple doors as a minimum sensor.

In order to achieve the above object, the present invention controls the opening and closing of the damper and the rotation speed of the ventilator so that the air discharged from the fume hood maintains a constant surface wind speed and discharges the air inside the experiment space to form negative pressure. ,

Two or more doors are installed in front of the fume hood in a walk-in method that slides open and close in a horizontal or vertical direction,

The door provides a walk-in fume hood equipped with a sensing means to detect the amount of movement of a plurality of doors by a single sensor contacting one side of the door at the bottom of the door.

In addition, the sensing means of the present invention is composed of a combination of a rack gear provided under one door, a circular gear engaged with the rack gear and installed on another door, and a spring that imparts a certain elasticity to the circular gear. , A walk-in fume hood to which a detection sensor selected from an encoder or a photoelectric sensor is connected to the circular gear is provided.

In addition, the sensing means of the present invention provides a walk-in fume hood further provided with an auxiliary sensor including a laser distance sensor.

In addition, the sensing means of the present invention is composed of a rack gear provided at the lower side of the corresponding door and a circular gear that is always engaged with the rack gear and installed separately from the door, and the circular gear is selected from an encoder or a photoelectric sensor sensor is connected,

The circular gear is a walk-in that is installed to detect the number of rotations of the circular gear as a plurality of detection sensors by connecting the circular gears meshed with each rack gear to one body and rotating the auxiliary rotation plate connected to the circular gear. A fume hood is provided.

In addition, the door of the present invention provides a walk-in fume hood further provided with a stopper on one side of the door to simultaneously move the overlapping doors.

As described above, according to the present invention, it is possible to accurately calculate the surface air velocity value regardless of the opening direction of the door, it is possible to accurately check the open and closed state regardless of the opening direction of the door, and it is possible to manufacture and install with a simple configuration. It is possible, and there is an effect of accurately grasping the opening amount of the plurality of doors with the smallest sensor.

1 is a perspective view showing a conventional fume hood.
2 is a perspective view and a front view showing a walk-in fume hood according to the present invention.
4 is a door open detection state diagram of the walk-in fume hood according to the present invention.
5 is a door open detection state diagram of a walk-in fume hood according to another embodiment of the present invention.
6 is a door open detection state diagram of a walk-in fume hood according to another embodiment of the present invention.
7 is a front view showing a vertical open state of the walk-in fume hood door according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail based on the accompanying drawings.

As shown in FIGS. 2 to 7, the walk-in fume hood 100 of the present invention is configured to open and close the damper 130 and ventilator ( 150) is installed to discharge the air inside the experiment space 180 to form a negative pressure.

In addition, two or more doors 200 in a walk-in method that are opened and closed by sliding in a horizontal or vertical direction are installed in front of the fume hood body 110 .

In addition, at the bottom of the door 200, a sensor 301 in contact with one side of the door 200 senses the relative movement amount of a plurality of doors that move in different directions or only one of them is moved. This is provided integrally.

In addition, the sensing unit 300 applies a certain elasticity to the rack gear 310 provided at the lower side of one door and the circular gear 330 installed in the other door while being engaged with the rack gear and the circular gear. It consists of a combination of springs 350 that do.

At this time, a detection sensor 301 selected from an encoder or a photoelectric sensor for recognizing the amount of rotation as a moving distance is connected to the circular gear 330 .

In addition, the sensing means 300 is further provided with an auxiliary sensor 302 made of a laser distance sensor.

In addition, the detecting means 300 is composed of rack gears 310 respectively provided on the lower side of the corresponding door and circular gears 330 installed separately from the door while meshing with the rack gears.

At this time, a detection sensor 301 selected from an encoder or a photoelectric sensor is connected to the circular gear.

Also, the detecting unit 300 is composed of a rack gear provided at the lower side of the corresponding door and a circular gear installed separately from the door while always meshing with the rack gear.

At this time, a detection sensor 301 selected from an encoder or a photoelectric sensor is connected to the circular gear.

In addition, the plurality of circular gears 330 are installed to rotate simultaneously in one body, and the auxiliary rotating plate 340 is connected to each of the circular gears so that the detection sensor 301 can individually check the plurality of circular gears 330. As the detection sensor 301, it is installed to detect the number of rotations of the individual auxiliary rotation plates that rotate simultaneously with the circular gear to check the movement distance.

In addition, the door 200 has a stopper 290 further provided on one side of the door to move the overlapping doors simultaneously, and is installed to move simultaneously while overlapping with another door when moving one door.

The operation of the present invention composed of the above configuration will be described.

As shown in FIGS. 2 to 7, the walk-in fume hood 100 of the present invention maintains a constant surface wind speed so that the air discharged from the fume hood body 110 forms a negative pressure inside the experiment space 180 The opening and closing of the damper 130 and the number of revolutions of the ventilator 150 are controlled.

In addition, the walk-in fume hood 100 has two or more walk-in doors 200 installed in front of the fume hood body 110 that slide open and close horizontally or vertically, making it easy to use and Regardless of when the 200 is opened, negative pressure can be formed inside the experimental space 180 .

That is, the walk-in fume hood 100 is an open state of the door 200 consisting of two sets, three sets, four sets, etc. that open left or right or left or right both sides or vertically from the front of the fume hood body. is accurately and quickly grasped by the sensing means 300 and controls the opening and closing of the damper 130 and the number of revolutions of the ventilator 150 corresponding thereto.

At this time, the detecting means 300 is a pair of doors moving in different directions or moving in different directions by one sensor in which one side of at least one door 200 is in contact with the bottom or top of the door 200. When one of the doors is moved, the amount of movement is sensed so that the open state of the door can be accurately identified.

In addition, the detecting means 300 includes a rack gear 310 provided on the lower or upper side of one door, a circular gear 330 installed on another door while being engaged with the rack gear, and the circular gear 330 It is composed of a combination of the detection sensor 301 connected to and rotates the circular gear 330 installed on the other door that stops when the one door moves, and when the circular gear 330 rotates, it detects this sensor ( 301) detects and converts the moving distance to determine the degree of opening of one door.

Conversely, when one door stops, the circular gear 330 installed on the other moving door is rotated, and the rotation of the circular gear 330 is detected by the sensor 301 to convert the movement distance. The degree of opening of one door is determined.

At this time, the circular gear is equipped with a spring 350 to impart a certain elasticity to minimize the load according to the movement to increase durability.

In addition, a detection sensor 301 selected from an encoder or a photoelectric sensor for recognizing the amount of rotation as a movement distance is connected to the circular gear 330 so that the rotation of the door can be easily recognized as the movement distance.

In addition, the detecting means 300 is further provided with an auxiliary sensor 320 made of a laser distance sensor to determine the open state when one door and the other door move simultaneously.

In addition, as shown in FIG. 6, a plurality of circular gears 330, which are engaged with each rack gear of both doors, are installed in one body to rotate individually at the same time, and are connected to the circular gears and rotate separately on the same plane. When the rotation plate 340 is connected and the auxiliary rotation plate 340 rotates when each circular gear is rotated, it is sensed as a sensor 301, so that even if either door is opened, the amount of door opening can be determined. .

At this time, an auxiliary sensor 302 made of a laser sensor is installed on one side of one of the doors, and when the other door is opened while the other door is open, the program multiplies the total moving distance of the detection sensor. Even if both doors are opened simultaneously, the open state can be confirmed.

In addition, the door 200 has a stopper 290 further provided on one side of the door to move the overlapping doors simultaneously, and is installed to move simultaneously while overlapping with another door when moving one door.

At this time, after each sensing means installed in each door 200 is individually operated, the moving distance is confirmed by summing them.

100 ... Walk-in fume hood 110 ... Fume hood body
130 ... Damper 150 ... Ventilator
180... lab space 200... door
310 ... rack gear 330 ... circular gear
350...spring

Claims (5)

It is installed to form negative pressure by discharging air inside the experiment space by controlling the opening and closing of the damper and the rotation speed of the ventilator so that the air discharged from the fume hood is discharged at a constant surface wind speed,
Two or more doors are installed in front of the fume hood in a walk-in method that slides open and close in a horizontal or vertical direction,
the door,
a). A detection sensor is provided to detect the degree of opening and adjust the surface wind speed,
b). A walk-in fume hood equipped with a sensing means to detect the amount of movement of a plurality of doors overlapping each other by one sensor contacting one side of the door at the bottom. The method of claim 1, wherein the sensing means is a combination of a rack gear provided at the bottom of one door, a circular gear meshed with the rack gear and installed on another door, and a spring that imparts a certain elasticity to the circular gear. is done,
A walk-in fume hood, characterized in that a detection sensor selected from an encoder or a photoelectric sensor is connected to the circular gear. The walk-in fume hood according to claim 1, wherein the sensing means further includes an auxiliary sensor comprising a laser distance sensor. The method of claim 1, wherein the sensing unit is composed of a rack gear provided at a lower side of the corresponding door and a circular gear engaged with the rack gear and installed separately from the door, wherein the circular gear is selected from an encoder or a photoelectric sensor. A detection sensor is connected,
The walk-in fume hood, characterized in that the plurality of circular gears meshed with each door are installed to rotate simultaneously in one body, and auxiliary rotating plates are respectively connected to the circular gears to be individually confirmed by a detection sensor. The walk-in fume hood according to claim 1, wherein a stopper is further provided on one side of the door to simultaneously move the overlapping doors.

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