KR101799703B1 - Humidity control device for laboratory chambers - Google Patents

Abstract

The present invention relates to a humidity control device for a laboratory chamber, which by using a humidity control device, supplies air with an adjusted relative humidity into a chamber so as to adjust the humidity in the chamber quickly, and maintains a uniform humidity distribution inside the chamber, thereby maintaining uniform conditions and enhancing reliability of the data of experiments carried out in various humidity conditions. Specifically, the humidity control device comprises: a first conduit line which receives dry air to supply the same in the direction of a laboratory chamber; a second conduit line which receives dry air, and passes the same through a wet air generation unit prior to supplying the same in the direction of the laboratory chamber; a flow rate control unit which controls incoming flow rates of the first conduit line and the second conduit line separately; and a mixing unit which allows the dry air from the first conduit line and the wet air generated from the second conduit line to be mixed together and directly supplied to the laboratory chamber. More specifically, the wet air generation unit comprises: a first container unit which is connected to the second conduit line, allows an end portion of a bubble generation pipe to be immersed in water stored therein, and generates vapors by the supplied dry air to generate the wet air; a second container unit which is connected to the first container unit, and in which condensed water drops are released into an empty space, thereby allowing the remaining wet air in a gas state to be discharged; a coil pipe which is connected to the second container unit, and is formed in the shape of a spring-shaped conduit line; and a temperature control device which includes a water reservoir allowing the first and second container units and the coil pipe to be immersed in water, and controls temperature of the water reservoir.

Description

[0001] Humidity control device for laboratory chambers [0002]

The present invention relates to a humidity control apparatus for a laboratory chamber, in which a relative humidity is controlled in a chamber through a humidity controller so that the humidity of the chamber can be controlled quickly, and the humidity distribution inside the chamber is uniform And to maintain a predetermined condition, thereby increasing the reliability of experimental data in various humidity conditions.

In general, the experimental chamber, which is mainly used for the development of new materials, controls the temperature and humidity, and studies on the characteristics of the material are conducted by checking how the material changes at specific temperature and humidity.

The conventional laboratory chamber is configured to forcibly evaporate water through a humidifier provided in the chamber to adjust the humidity of the inside of the chamber, and then adjust the humidity by a sensor. However, when the humidity is controlled by the humidifier provided in the chamber, since the humidity control is performed at a late time depending on the humidity sensor, the humidity can not be quickly reached under the conditions of the experiment, there was. In addition, the wet air generated from the humidifier does not spread throughout the chamber, so that the humidity distribution can not be maintained uniformly. Therefore, the humidity of the sensor portion and the humidity of the material portion are different.

No. 10-1437631 (apparatus and method for controlling chamber internal temperature using humidity control) as related prior art includes an air flow line through which air is fed into and exhausted from the chamber, and a humidity-temperature A data collecting means for collecting humidity and temperature data from the humidity-temperature sensing means, and a controller for controlling the humidity or temperature inside the chamber by using the humidity and temperature data collected by the data collecting means, A humidifying means for humidifying the inside of the chamber until the temperature inside the chamber reaches a set temperature when the temperature inside the chamber rises according to a command from the control unit; And dehumidifying means for dehumidifying the inside of the chamber until the temperature inside the chamber reaches the set temperature The.

However, since the humidifier used in the prior art is a device for increasing the humidity (i.e., the relative humidity) in the chamber, the humidifier, which is conventionally known as a humidifier, is applied. And there is a structural problem that it is difficult to maintain a uniform humidity distribution throughout the chamber.

As another prior art, Japanese Patent Application No. 10-1151900 (environment test chamber) is provided with a main body in which a space part for receiving a sample is formed, and an environment control part provided in the main body for controlling the temperature and humidity of the space part The environment control unit is provided in an air control room provided at one side of the main body and the air control room is provided with a blowing fan so that the air deformed by the refrigerator, the heater or the humidifier is supplied to the space by the blowing fan .

In the prior art, the wet air generated by the humidifier is supplied to the space portion of the chamber through the blowing fan. However, the wet air supplied is not configured to be accurately controlled to the humidity to be tested, And the amount of humidified air is controlled by checking the measured humidity, so that there is a problem that the humidity control is not easy.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for controlling humidity in a chamber by controlling mixed ratios of dry air and wet air, And the humidity can be adjusted quickly, and the humidity can be easily and finely adjusted.

Another object of the present invention is to provide a humidity control apparatus for a laboratory chamber capable of minimizing the condensation phenomenon and maintaining a constant humidity of the humidified air by generating humidified air at a constant temperature condition, thereby increasing the reliability of experimental data.

The present invention relates to an air conditioning system comprising a first conduit into which dry air is introduced and which is supplied in the direction of an experimental chamber, a second conduit through which dry air flows into the chamber through a humid air generator, And a mixing section for mixing the dry air of the first conduit and the generated wet air of the second conduit so that the mixed air can be directly supplied to the experimental chamber, wherein the wet air generating section comprises: A first container unit connected to the second duct and configured to generate a humid air by generating steam by supplying the dry air to the end of the bubble generating pipe so as to be immersed in the water filled in the first pipe unit, A second container portion in which the water droplets condensed into the empty space are separated and separated and only the wetted air in the remaining gaseous phase is discharged, a coin pipe connected to the second container portion and formed in a spring- And a temperature controller for controlling the temperature of the water tank by forming a water tank so that the container and the coin pipe can be immersed in the water.

And the lower end of the bubble generating tube located in the first container portion is formed with a plurality of fine air holes.

And a position in which the air in the second container portion is introduced is supplied in a vertical direction from an upper center.

In addition, an arc-shaped blocking portion is formed in an upper portion of the air outlet portion of the second container portion so that the condensed water drops can be separated from the gaseous wet air while bumping against the blocking portion.

In the present invention, by controlling the mixing ratio of the dry air and the humidified air to the experimental chamber, the humidity is controlled by supplying the mixed air in a state where the relative humidity is controlled, so that the humidity distribution inside the chamber can be maintained constant, And it is easy to fine-adjust the humidity.

In addition, by producing the wet air at a constant temperature condition, the condensation phenomenon can be minimized and the humidity of the wet air can be kept constant in the process of generating the wet air, thereby improving the reliability of the experimental data.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing the entire configuration of a humidity control apparatus for a laboratory chamber of the present invention
2 is an enlarged view showing the wet air generating unit of the present invention
3 is a perspective view showing a connection structure of the first container portion, the second container portion,
4 is a view showing an embodiment in which a blocking part is further formed inside the second container part according to the present invention
5 to 6 are views showing still another embodiment of the humidity control apparatus of the experimental chamber of the present invention

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

As shown in FIG. 1, the apparatus for controlling humidity of the experimental chamber of the present invention comprises a first conduit 10 in which dry air is largely introduced and supplied in the direction of a laboratory chamber A, A second conduit 20 supplied in the direction of the experimental chamber A through the first conduit 100 and a flow control unit 30 controlling the flow rates of the first conduit 10 and the second conduit 20, And a mixing unit 40 for mixing the dry air of the first conduit 10 and the generated wet air of the second conduit 20 so as to be supplied directly to the laboratory chamber A.

The dry air flowing into the first conduit 10 and the second conduit 20 is air having a humidity of 0% and can be supplied in connection with a container in which dry nitrogen air is compressed. May be supplied through the drying process.

It is preferable that the flow rate regulator 30 is a conventional flow rate regulator called MFC (Mass Flow Controller), and the flow rate regulator 30 is connected to the first channel 10 and the second channel 20 And adjusts the relative humidity of the air flowing into the experimental chamber (A) through flow rate control for the ratio of dry air to wetted air. Since the air having a controlled relative humidity is introduced into the experimental chamber (A), the humidity condition to be tested can be quickly reached and the relative humidity can be finely adjusted.

The experimental chamber A has an inlet port through which the air of the mixing section 40 can be introduced and an outlet port through which the air inside the chamber can be discharged to the outside.

The humid air generating unit (100) of the present invention comprises: As shown in FIGS. 2 to 3, the end of the bubble generating pipe 210 is connected to the second conduit 20 and filled with water, and water vapor is generated by the supplied dry air to generate humid air A second container part 300 connected to the first container part 200 and separated from water droplets condensed into an empty space and discharging only the remaining wet gaseous air, The first and second container units 200 and 300 and the coin pipe 400 may be submerged in water so that the first and second container units 200 and 300 are connected to the second container unit 300 and formed in a spring- And a temperature regulator 500 for regulating the temperature of the water tub 510.

The first container unit 200 forms air bubbles in the pre-filled water along the bubble generating pipe 210 at the center through the second conduit 20 to generate steam, So that the air can be converted into wet air. That is, the bubble generating pipe 210 formed vertically at the center of the first container unit 200 is submerged in the water filled in the first container unit 200 at a predetermined height, and the bubble generating pipe 210, Is formed in a shape having a plurality of fine air holes so that the dry air can be easily converted into the wet air through a plurality of fine air bubbles.

The second container part 300 is provided at the rear end of the first container part 200 and water droplets generated due to the condensation of wet air containing a large amount of water vapor generated in the first container part 200 The second container portion 300 is not filled with anything, and the droplets of the wetted air fall to the bottom of the second container portion 300 due to gravity.

In addition, it is preferable that the second container unit 300 is vertically supplied with wet air from the center of the upper part. This is because the direction of the supply of wet air and the direction in which the water drops fall coincide, So that it can be directly dropped to the lower part. The humid air from which water droplets have been removed is discharged to one side of the upper part of the second container part 300 and supplied to the coin pipe 400.

In addition, when the flow rate of the second conduit 20 is increased, the second container part 300 can not be effectively removed and the water droplets can be discharged immediately. Therefore, as shown in FIG. 4, Shaped blocking part 310 is formed on the upper part of the upper part to be separated from the gaseous wet air as the condensed water droplet hits the blocking part 310. [ At this time, the shape of the discharged pipe is inclined upward, and it is preferable that some water droplets can be dropped to the second container part 300 along the inclined surface in the process of being discharged.

The coin tube 400 is installed at the rear end of the second container part 300 and has a structure formed as a spring-like channel. The entire coin tube 400 is immersed in the water tank 510 of the temperature controller 500 so that the humidified air can flow at a constant temperature along the coin tube 400 and is discharged into the humidified air in a stable state To be supplied to the mixing section (40).

The temperature controller 500 includes a water tank 510 so that the first and second containers 200 and 300 and the coin pipe 400 can be immersed in water, And is adjusted to a specific temperature by the installed temperature adjusting means 520. At this time, it is preferable that a Peltier element (thermoelectric element) having a temperature control range of about -30 ° C to 100 ° C is used as the temperature adjusting means 520. The reason why the first and second container units 200 and 300 and the coin pipe 400 are installed in the water tank 510 of the temperature controller 500 is that the condensation phenomenon generated in the process of generating humid air is a temperature change So that wet air can be generated at a constant temperature. If the temperature is not maintained constant in the process of producing humid air, the condensation phenomenon is increased to cause the water droplets to flow into the test chamber (A), or the humidity of the humidified air is not constant, .

It is preferable that the water tank 510 of the temperature controller 500 maintains a temperature of about 20 ° C or lower, and the temperature can be adjusted to a subzero temperature according to experimental conditions. The water used in the water tank 510 of the temperature controller 500 may be water, but it can be used as a solution such as methanol which does not easily freeze when the experiment is performed under a subzero condition.

In addition, the water tank 510 of the temperature controller 500 may have an open top, but a cover 530 may be further formed on the water tank 510 to reduce external influences.

In the wet air generating unit 100 of the present invention, the dry air supplied through the second duct 20 is converted into wet air through the first container unit 200, and the second container unit 300 The water droplets in the gaseous phase are removed, and finally, the water is discharged through the coin pipe 400 into the stable wet air at a predetermined temperature.

5 to 6 illustrate another embodiment of the humidity control apparatus for a laboratory chamber according to the present invention. In this embodiment, when water droplets remain on the coin tube 400 while the experiment is performed for a long time,

A separate cleaning channel 600 branched from the second channel 20 connected to the discharge port is provided at the rear end of the coin pipe 400 and the second channel 60 Closing valves 610 and 601 'are respectively formed in the cleaning pipe 600 and the cleaning pipe 600 so that the cleaning pipe 600 can be used only when the coin pipe 400 is cleaned, Vent holes 620 are formed to allow air to be discharged to the outside during the cleaning process. The vent hole 620 should be configured to be closed with a plug or closed with a separate valve in the experiment.

The cleaning process of the coin tube 400 will be described with reference to the embodiment described above. First, the opening / closing valve 610 'of the second channel 20 on the mixing unit 40 side is closed and the opening / 610 are opened so that the vent hole 620 can be opened. Then, when high-pressure air is injected into the cleaning pipe 600, the water droplets remaining in the coin pipe 400 with strong air flow into the coin pipe 400 in the direction opposite to the air flow of the wet air, 300) to separate water droplets. At this time, the air introduced into the second container unit 300 is discharged to the vent hole 620.

While the present invention has been described with reference to the exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

A: Experimental chamber 10: First conduit
20: second conduit 30: flow rate regulator
40: mixing section 100: wet air generating section
200: first container portion 210: bubble generating tube
300: second container part 310:
400: Coil tube 500: Temperature controller
510: water tank 520: temperature adjusting means
530: cover 600: cleaning duct
610, 610 ': opening / closing valve 620: vent hole

Claims (4)

A first conduit 10 into which dry air flows and is supplied toward the laboratory chamber A,
A second conduit 20 into which dry air flows and is supplied to the chamber A through a humid air generating unit 100,
A flow rate regulator 30 for controlling the supply flow rates of the first conduit 10 and the second conduit 20,
And a mixing unit 40 for mixing the dry air of the first conduit 10 and the generated wet air of the second conduit 20 to be supplied directly to the laboratory chamber A,
The humidified air generating unit 100 includes:
A first container unit 200 connected to the second conduit 20 and adapted to immerse the end of the bubble generating pipe 210 in the water filled therein to generate water vapor by the supplied dry air to generate wet air, ,
A second container part 300 connected to the first container part 200 and separating the water droplets condensed into an empty space and separating the remaining wet gaseous air,
A coin tube 400 connected to the second container part 300 and formed in a spring-like channel,
And a temperature controller 500 having a water tank 510 and a temperature controller 500 for controlling the temperature of the water tank 510 so that the first and second containers 200 and 300 and the coin tube 400 are immersed in water And a humidity control device for a laboratory chamber The method according to claim 1,
And a lower end of the bubble generating tube (210) located in the first container part (200) is formed with a plurality of fine air holes.
The method according to claim 1,
Wherein a position at which the air in the second container unit (300) is introduced is supplied in a vertical direction at an upper center of the chamber.
The method according to claim 1,
The second container portion 300 is formed with an arc-shaped blocking portion 310 at an upper portion of the air outlet portion so that the condensed water droplets can be separated from the gaseous wet air by colliding with the blocking portion 310 A humidity control device for a laboratory chamber

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