KR960014091B1 - Humidifier - Google Patents

Abstract

The humidifier is designed to generate ultrafine water drops for dust protection, odor removal and polarizing prevention. The humidifier includes : a coriolis force generator (1); an extractor (2); a humidifier (3); an air inlet (5); an air outlet (6); a high speed air flow generator (7); a screw guide (10); a pump (14); a guide plate (23); and a drain (28).

Description

humidifier

1 is a diagram comparing the sizes of particulates, such as tremors, in the atmosphere.

2 shows an embodiment of the invention.

3 is a view showing the installation of the screw guide.

4 is a two-sided view showing the separation of gas and liquid by the extraction device.

5 is a cross-sectional view of FIG.

6 is a view showing another example of the extraction apparatus.

* Explanation of symbols for main parts of the drawings

1: Coriori force generator 2: Extraction device

3: humidifier 4: air transport pipe

5: inlet port 6: exhaust port

7: High speed air flow generator 8: Outer cylinder

9: inner cylinder 10: screw guide

11: nozzle piping 12: nozzle

13: tank 14: pump

15 cooling coil 16 drain hole

17: cylinder 18: conical tube

19: inlet 20: outlet

22: rectification pipe 23: guide pipe

24: holding 25: cylinder

26: inlet 27: outlet

28: drain

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a humidifier for use in dustproofing, deodorization, and antistatic, and in particular to a humidifier that generates ultra-fine water droplets that are not wetted with an article despite being highly humid.

For example, when humidity is insufficient due to indoor heating, a humidifier maintains an appropriate humidity. Generally, a healthy humidity is known to be 55%.

The method of creating proper humidity includes heater heating type that humidifies with warm moisture, filter type that is humidified by a humid filter, centrifugal spray type that fine mist spreads in all directions, and sprays mist by using ultrasonic vibration. There is an ultrasound.

The filter type is at the bottom, but the others are tabletop.

(Refer to Product Dictionary, Tongyang Economic Daily, P1262P)

Recently, ultrasonic humidifiers are mainly used in general households.

Humidifier of the present invention is to include a humidifier, nebulizer, nebulizer (Nebuliger) and the like used for a specific application in addition to the indoor humidifier as described above.

The mist generated by the above-described apparatus is a particle size of the visible level, and its size contains a large amount of water droplets of 3 µm or more, particularly 10 µm or more.

When the mist generated from the humidifier contains a large amount of water droplets, especially 10 μm, it adheres to the product as it is, soaks paper products and futons, and when attached to electrical appliances, it causes short circuit between parts.

Normally, humidifiers have to refine the mist particles to solve this problem, but the most fundamental problem does not end with not soaking the goods, but when the water used contains contaminants, they are all contaminated. It is contained inside and spreads around.

For example, Table 1 shows a comparison between the commercial water and the components contained in the condensate dispersed by misting the commercial water using an ultrasonic humidifier.

As shown in Table 1, it can be seen that cations (Na, K, Ca, Mg, etc.) and anions (C1-, MO-, SO) contained in commercial water are contained in the condensate as it is.

In this fact, when contaminants or bacteria, bacteria, viruses, and the like shown in FIG. 1 are contained in the water used in the humidifier, these fungi are all accompanied by water droplets, and there is a danger of spreading indoors. This presents a significant problem of the spread of infectious agents in the hospital when using humidifiers in hospitals.

In addition, if contaminants are entrained in misty water droplets and adhered to the article, for example, NaCl or the like precipitates and crystallizes, which causes contamination of the article.

An object of the present invention is to provide a humidifier for diffusing only water into microscopic water droplets without accommodating various contaminants contained in the water.

In order to achieve the above object, the humidifier according to the present invention has a centrifugal force, a Coriolis force generating device and a humidifier having an extracting device. The centrifugal force and Coriori force generating device forms an acid flow in the air stream flowing through the tube. The centrifugal force and the coriory force are applied to the supplied water to divide the water in the swirling air and transport the air force to the extraction device.

The extractor selects the size of the divided droplet particles and extracts and outputs high-humidity air containing ultra-fine droplets of 1 μm or less, particularly 0.1 μm or less.

The humidifier also has a cooler, which cools the tube.

In addition, the centrifugal force and coriori force generators have an air force transport pipe, a screw guide, and a water jet nozzle, and the air force transport pipe receives a stream of air injected from a high velocity airflow source and transports water droplets through air. Induces the air flow inflated into spiral spiral flow and simultaneously acts on the water droplets transported by air force, and the water jet nozzle disposed in the axial direction of the air force transport pipe is the water in the swirl flow of the air flow formed in the air force hydrogen pipe. To spray the water droplets.

The screw guide is a spiral block (***** 條) disposed along the inner circumference of the pneumatic conveying pipe, and the spiral block group induces air flow into the swirling flow to induce centrifugal force and corori force to the water droplets transported by air force. It works to promote its division.

In addition, the air force transport pipe is divided into a droplet generation zone and a splitting action zone, and the droplet generation zone is in front of the air force transport pipe, and the splitting action part is behind the air force transport pipe, and a water spray nozzle and a screw guide are installed in the pipe.

In addition, the air force transport pipe is composed of internal and external double pipes to communicate with each other to form a return flow path of the airflow, the exterior is connected to the high speed air flow source, the inner pipe is connected to the extraction device, and the water injection nozzle is installed in the exterior The generating region is formed, and a screw guide is installed in the inner tube to form a division zone.

The extraction device is a centrifugal force separator. The machine supplied at high speed from the high speed air flow source forms swirl flow in the air force conduit, and water is injected into the swirl flow to break up into water droplets, and the action of kinetic energy, centrifugal force, and coriolis force generated by gas swirl flow At the same time, the division is further promoted.

In addition, if the radius r of the aerodynamic transport pipe, the rotation angle w of the swinging motion, and the mass and velocity of the quality point are m and v, respectively, the kinetic energy of the gas is 1 / 2mv. Centrifugal force mrw The Coriori is given by 2mwv. Coryriority factor (f) is given by f = Ωsinø, which is a factor due to the angular velocity and latitude of the Earth's rotation. However, in the northern hemisphere, the direction of turn is set so that the Kori force moves in the direction of the angular velocity vector of the earth's rotation when the water is turning. By effectively exerting such a choriori force, energy when a drop of water drops hundreds of meters can be obtained at a distance of several centimeters.

In addition to the kinetic energy and centrifugal force of the air flow, the water droplets are subjected to a strong coriolis force, and a large amount of ultra fine droplets having a particle diameter of substantially 1 μm or less, particularly 0.1 μm or less are generated.

Next, when the swirling air flow containing the water droplets is sent to the extraction device to separate the centrifugal force, the high-humidity air containing the ultra-fine water droplets is separated by the air flow and sent out. Since it contains a large amount of ultra-fine droplets of 1 μm or less, especially 0.1 μm or less, it does not accompany contaminants, bacteria, and viruses in the water, and has negative ions and activity to promote pollutants in the air and The effect which suppressed the proliferation of viruses, etc. is acquired.

EXAMPLE

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 2 shows the indoor device type humidifier 3 by assembling the centrifugal force, Coriori force generating device 1, and the extraction device 2. As shown in FIG.

The centrifugal force and corori force generating device 1 has an inlet port 5 and an exhaust port 6 in the pneumatic force transport pipe 4, and a high speed airflow generating device 7 is connected to the inlet port 5, so that the outside air is sucked in. The extraction device 2 is connected to the exhaust port 6 so that the air separated from the liquid is discharged to the discharge port 20.

In the embodiment, the outlet 20 of the extraction device 2 and the intake port of the high speed airflow generation device 7 are opened in the room to form a circulation system.

The centrifugal force and coriori force generating device 1 is a mechanism for miniaturizing water droplets by applying centrifugal force and coriori force to water spouted in a high speed air stream. The inner cylinder 9 is concentrically and concentrically embedded in the outer cylinder 8 of the pneumatic conveying pipe 4 so that one end of the inner cylinder 9 is opened into the outer cylinder 8 and the other end is connected to the extraction device 2. An example is shown.

The inlet port 5 is connected to the outer cylinder 8, and the air flow sucked from the high speed airflow generator 7 is received into the inner cylinder 9 from the end through the outer cylinder 8 while turning, and the inner cylinder 9 After passing through), it is sent to the extraction device (2).

In the embodiment, the screw guide 10 is installed in the inner cylinder 9 along the shaft at least one week from the inner end thereof, and the nozzle pipe 11 is installed over the entire length of the outer circumference of the inner cylinder 9. The pipe 11 is provided with nozzles 12 at appropriate intervals, and a tank 13 filled with water supplied to each nozzle 12 is provided below the outer cylinder 8.

The water in the tank 13 is transported to the nozzle pipe 11 by the pump 14 and is discharged from the nozzle 12 into the outer cylinder 8.

On the other hand, the cooling coil 15 is piped to the inner peripheral surface of the outer cylinder 8.

The cooling coil 15 is a cooler that controls the temperature and humidity of the supply air by cooling the air flow in the outer cylinder 8 by circulating cold water supplied from a separate chiller.

The screw guide 10 is a spiral block group disposed along the inner circumference of the inner cylinder 9 as shown in FIG. 3, and guides the specifications received in the inner cylinder 9 in the tubular direction to force the spiral. To turn.

The screw guide 10 defines the rotational direction of the airflow so that the coriori force is directed in the angular velocity vector direction of the earth's rotation.

In order to effectively generate the coreori force, it is necessary to install the screw guide 10 in the inner cylinder 9 for at least one week.

Moreover, many drain holes 16 are drilled in the inner cylinder 9, and this is made to communicate with the outer cylinder 8. As shown in FIG.

The extraction device 2 is a centrifugal separator that separates gas and liquid, and is provided with a conical tube 18 in the cylindrical body 17.

As shown in FIGS. 4 and 5, the cylindrical body 17 has a cylindrical shape as an outer cylinder of the centrifugal force separating device, and has a gas inlet 19 for the body and an outlet 20 at the top.

There is also a hole in the bottom for drainage.

The exhaust port 6 of the centrifugal force and the coreory force generating device 1 is connected to the suction port 19 formed in the lower portion of the cylindrical body 17, and the air flow is fed to the lower portion of the cylindrical body 17.

In the inlet port 19, the rectifying plate 22 is installed at regular intervals, and at the end of the inlet port 19, a guide plate 23 for guiding the feeding gas in the direction of the inner wall of the cylindrical body 17, as shown in FIG. Erected

The outlet 20 is an exhaust pipe inserted at a predetermined depth from the upper surface of the cylindrical body 17 in the concentric position with the axial center of the cylindrical body 17.

The conical tube 18 faces the larger diameter upward, is fixed to the inner wall of the support 24 and the cylindrical body 17, and is installed in the horizontal position in the lower part of the discharge port 20. As shown in FIG. The embodiment shows an example in which two conical pipes 18 having short heights are installed in two stages, upper and lower, with a predetermined interval.

When the airflow containing water droplets in the extraction device 2 is pressurized at high speed, the airflow is rectified in multiple layers in the rectifying pipe 22 and guided back to the guide plate 23 to raise the swirling flow A in the cylindrical body 17. Is formed to rise along the inner wall of the cylindrical body 17. During the ascent, the water droplets contained in the gas are separated from the gas by hitting the inner wall surface of the cylindrical body 17 by the centrifugal action generated by the signal of the gas, and fall back on the inner wall surface by the own weight and flow back into the tank 13 again. .

Ascending swirl flow A reaches the bottom of the upper surface of the cylindrical body 17, part of which becomes the exhaust flow C and is discharged to the outside through the discharge port 20, and most of the rest is inverted so that the upper side flows back into the conical tube 18. Then, it becomes the downward turning flow B and descends along the inner wall of the conical tube 18.

Since the conical tube 18 has a small diameter at the lower side, the descending swirl flow B gradually increases in speed while descending in the conical tube 18, and thus a strong negative pressure region in the space above the conical tube 18. To form.

In Fig. 4, the pressure of the air flow at the upper inner wall of the cylindrical body 17 is P, the pressure of the air flow at the upper outer wall of the upper cone tube 18 is P, the pressure of the air flow at its inner wall is P, the upper cone. When the pipe 18 sets the pressure of the air flow at the lower inner wall to be P, the magnitude of the relationship becomes P> P> P> P, and a strong suction force is generated in the conical tube 18, and the exhaust flow exhausted from the outlet port 20 is exhausted. The remaining water droplets in A are attracted by the hip pull force and fall in the descending swirl flow B, and only the airflow from which the water droplets have been removed becomes exhaust flow C and is exhausted to the outside through the outlet port 20.

On the other hand, when the downward turning flow B flows into the lower conical tube 18 from the upper conical tube 18, it draws in a portion of the upward turning A and flows into the lower conical tube 18, and from the inlet 19 at the lower end thereof. The mixture is mixed with the newly introduced gas to form a rising swirl flow A again, and the rising is repeated in the cylindrical body 17, and a part thereof is outputted to the exhaust stream C.

Although the above-described structure is excellent in separating gas and liquid, the extraction device 2 is only required to separate the water droplets in the air stream output from the centrifugal force and the coriori force generating device 1. Generally, even the cyclone separator used for dust collectors and the like is fully utilized.

In general, the cyclone separator is a gas inlet 26 of the gas is installed in the body portion of the cylinder 25 as shown in Figure 6, the gas discharge pipe 27 is installed in the upper end, the body 25 is a cylinder body The lower part is conical and the lower end is connected to the drain 28.

When the inlet port 26 is connected to the exhaust port 6 of the centrifugal force and the coriori force generating device 1, and the airflow output from the centrifugal force and the coriori force generating device 1 is received in the cylinder 25, the airflow becomes a cylindrical body ( 25) while turning down the inner wall of the trunk portion, while the water droplets contained in the gas hit the inner wall of the trunk portion by the centrifugal force generated by the rotation in the meantime, the gas is dropped into the drain 28 to remove the gas to the discharge pipe 27 Is released.

In the embodiment, the high speed airflow generation device 7 is operated, and the water in the tank 13 is pumped up to the pump 14 to be injected into the outer cylinder 8 from each nozzle 12 of the nozzle pipe 11. In addition, when spraying water, it is preferable to position each nozzle so that it may spray in a reverse direction with respect to the flow direction of gas. The air sucked from the outside air by the operation of the high speed air flow generating device 7 is sucked into the inlet port 5, and becomes a powerful swirling airflow by the guide plate 29, which moves in the outer cylinder 8 and is ejected in the swirling airflow. The water splits and diffuses into very small droplets and is transported by air force while linearizing the inside of the outer cylinder (8).

The airflow is reversed at the end of the outer cylinder (8) and introduced into the inner cylinder (9), and is continuously transported in the inner cylinder (9) by a pneumatic force while continuously turning along the block of the screw guide (10). Kinetic energy (1 / 2mv Centrifugal force () ) And the coriolis force (2mvw) are added to promote the non-combustibility of water droplets, and the air stream contains a large amount of ultra-fine water droplets of 1 μm or less, especially 0.1 μm or less.

In the case where the screw guide 10 is installed in the inner cylinder 9 for two weeks or more, when the pitch of the screw guide 10 is increased in order from the intake side to the exhaust side, the angular velocity vector w of the swirling air gradually decreases and the centrifugal force is decreased. It is possible to increase the separation efficiency between the gas and the liquid by weakening the excessive force.

The air flow containing the ultra fine water droplets is introduced into the extractor 2 from the exhaust port 6 of the pneumatic force water supply pipe 4 so that the large water droplets remaining in the air stream are removed and the high humidity air containing the ultra fine water droplets is extracted. It is sent out through the outlet 20 of.

In addition, the water droplets flowing down into the outer cylinder 8 through the drain hole 16 of the inner cylinder 9 are loaded into the swirling airflow in the outer cylinder 8 to obtain high energy, and return to the inner cylinder 9 again to split into ultrafine droplets. The water droplets attached to the tube wall of the outer cylinder 8 and the water droplets separated from the extraction device 2 are refluxed into the tank 13.

In addition, the embodiment shows an example in which the screw guide 10 is installed only in the inner cylinder 9, but the screw guide 10 may be installed in the outer cylinder 8 as well.

EXAMPLE

Hereinafter, examples of the present invention are shown.

The humidifier shown in FIG. 2 was operated under the following specification and operating conditions, and the particle size of the water droplets obtained from the discharge port was measured.

1. Air transport pipe

(1) outer cylinder

Tube diameter (2R) = 370ømm

Tube length (L) = 830 mm

Inlet size = 90 × 160㎜

(2) nozzle for external cylinder

Nozzle Piping: = 30ø㎜

Nozzle Outlet Diameter: = 3.5ø㎜

Number of nozzles: = 10

Nozzle installation angle: = 5 degrees

(3) inner tube

Tube diameter (2R) = 160ømm

Tube length (L) = 640 mm

Outlet size = 160ø㎜

(4) Inner Cylinder Guide

Screw Guide: 1 Piece

Pitch (d): 80 mm

(5) extraction device

Outside diameter of cylinder 370ømm

Length of the cylinder 550 mm

2 cone cone

(6) High speed air flow generator (fan)

Air flow rate Max 12m3 / min

0.62KW power

(7) pump

Quantity 30lit / min

0.17KW

The measurement results are shown in Table 2. Table 2 is measured by the Leon Co. particle counter -KCO1A.

Table 3 shows the measurement results by Leon Co., Ltd. particle counter-kc-18.

When commercial water is used in the humidifier of the present invention, Table 4 shows a comparison between the components contained in the commercial water and the components contained in the condensed water of the high humid air obtained from the outlet.

ND: Not detected

According to the present invention as shown in Table 2 to Table 4, high humidified air containing a large amount of ultra fine droplets having a particle diameter of 0.2 μm or less is obtained at the outlet of the humidifier, and is different from the components contained in the water in the tank in the high humidified air. I knew that.

As described above, according to the present invention, highly humid air containing a large amount of ultrafine droplets of 1 μm or less, particularly 0.1 μm or less, is obtained at the outlet of the humidifier, and since the droplets have a small particle size, the product is wetted even if the water droplets adhere to the surface of the article. In addition, almost no components contained in the water used for humidification are discharged, and since the particle size of the droplets is smaller than the size of bacteria or viruses that cause infection in the hospital, there is no danger of spreading these fungi. Rather, it is possible to obtain the effect of uniform sterilization of the surface of the air or the article by anions generated due to the Leonard effect or the Simpson effect.

Claims (5)

In the humidifier with high speed air flow generator, centrifugal force and coriori force generator and extraction device, centrifugal force and coriori force generator have air force transport pipe, water spray nozzle and screw guide, and air force transport pipe is internal and external 2 The air pipes are connected to each other by the central pipe to form a ventilation path.The high speed air flow generator of air is connected to the intake port of the exterior, and the water injection nozzle is installed on the inside, and the screw guide is installed on the inner circumference of the inner pipe and the extraction device on the exhaust port. Humidifier characterized in that the extraction device is to extract the high-humidity air containing ultra-fine water droplets of 1μm or less, in particular 0.1μm or less by selecting the particle diameter of the split water droplets. The humidifier according to claim 1, wherein a cooler is installed in the air transport pipe to cool the inside of the pipe. The humidifier according to claim 1, wherein the water spray nozzle is installed in the exterior of the air force transport pipe to inject water into the swirling air stream to generate water droplets. The method of claim 1, wherein the screw guide is a helical block set axially installed in the inner tube of the pneumatic conveying pipe forcibly directing the air flow to the spiral swirl flow, centrifugal force and corori Humidifier, characterized in that to promote the separation of water by applying a force. The humidifier according to claim 1, wherein the extraction device is a centrifugal force separator, in particular a cyclone separator.