KR20230035541A - Humidity control device - Google Patents

Abstract

The present invention provides a hollow fiber membrane dehumidifier and a humidity control device having the same. A dehumidifier, which includes a dehumidifying hollow fiber membrane to remove moisture from the air, and a humidifier, which includes a humidifying hollow fiber membrane to supply moisture to the air, are connected in parallel to adjust the humidity of the air. Accordingly, the hollow fiber membrane humidifier, since a water mist is not generated, is capable of perfect humidification, germ-free humidification (resolving the issue of sterilizers in conventional humidifiers), and instantaneous humidification to provide high humidification efficiency. There is no need to deliberately create hot water for humidification, so the humidity control device does not use additional energy (electricity) to provide hot water. Unlike a refrigeration compression-type dehumidifier, dehumidification using a hollow fiber membrane does not generate heat during the dehumidification process, so even with long-term dehumidification operation, does not increase the indoor temperature, and since a compressor requiring high-pressure air is not needed, power consumption is reduced, thereby allowing for higher energy efficiency compared to conventional dehumidification methods using a refrigerant. Humidification using a hollow fiber membrane contains only moisture absorbed by the hollow fiber membrane, so does not scatter impurities present in the humidifying water into the air along with water particles, thereby producing clean and humidified air. Additionally, since the moisture particles in a gaseous state passing through the hollow fiber membrane are very small, the dispersion range in the air is very wide, so the humidity control device can prevent condensation around humidified air outlets.

Description

Humidity control device {Humidity control device}

The present invention relates to a humidity control device, and relates to a dehumidifier having a hollow fiber membrane for dehumidification as a main component to remove moisture from air to be dehumidified, and a humidifier having a hollow fiber membrane for humidification as a main component to supply moisture to air. It relates to a humidity control device for controlling the humidity of air by connecting in parallel.

In general, users use a humidifier to supply moisture and a dehumidifier to remove moisture to adjust the humidity of a necessary space.

In recent years, a humidity control device having a humidifying function and a dehumidifying function integrated therein has been widely used, so that the user can more easily control the humidity.

A humidifying unit provided in a humidity control device and performing a humidifying function mainly uses a method of humidifying using ultrasonic oscillation and a method of humidifying by evaporating water using a heater.

In addition, the dehumidifying unit that performs the dehumidifying function brings the air to be dehumidified into contact with the surface of the evaporator so that the moisture in the air is condensed on the surface of the evaporator to remove moisture, and a method of removing moisture in the air by operating a heater and air There is a method of absorbing and removing moisture in a dehumidifying agent.

Regarding the prior art, Patent Registration No. 10-0708553 (2007.04.11) may be referred to.

In addition, the most commonly used refrigeration compressor dehumidifier has a complicated structure, consumes excessive power, generates high noise during operation of the air compressor, and has difficulty in handling due to the heavy device.

In addition, when used in summer with high humidity, heat is generated and the air temperature rises, and the air conditioner cools the air to an unnecessarily low temperature to remove moisture, resulting in excessive electricity bills and bad for health. (Air conditioner) There was a problem.

In addition, conventional evaporative humidifiers, steam spray humidifiers, electrode humidifiers, ultrasonic humidifiers, etc., have a white powder phenomenon due to scattering of water particles, concentrated moisture on the floor, condensation around the steam outlet due to water accumulation, and supersaturation It has disadvantages such as generation, etc., and has a problem such as diffusion of impurities in water into the air.

In addition, microorganisms propagate in the water tank and equipment, causing frequent microbial contamination problems such as germs, viruses, and fungi in the steam, which requires a lot of time and effort to clean the water tank and replace the water.

In the present invention, the dehumidification using a hollow fiber membrane does not generate heat during the dehumidification process, unlike the refrigerant compression type dehumidifier, so the room temperature does not rise even after long-term dehumidification operation, and it does not require high-pressure air such as a compressor (compressor). Energy efficiency can be increased compared to the conventional dehumidification method using a refrigerant due to low consumption. Humidification using a hollow fiber membrane only contains moisture that has passed through the hollow fiber membrane, so impurities present in the water for humidification are mixed with water particles. There is no fear of scattering into the air, so clean humidified air can be obtained, and the moisture particles in the gaseous state passing through the hollow fiber membrane are very small, so the range of scattering in the air is very wide, preventing dew condensation around the humidified air outlet. Its purpose is to provide a humidity control device capable of

A humidity control device according to the present invention includes first and second air inlet lines for introducing external air and inducing the introduced air from one side to the other, respectively; a hollow fiber membrane humidifier provided on the first air inlet line and humidifying the air flowing along the hollow of the first hollow fiber membrane membrane provided therein; a water supply unit connected to the hollow fiber membrane humidifier and selectively circulating water through the first hollow fiber membrane; a hollow fiber membrane dehumidifier provided on the second air inlet line and dehumidifying air flowing along the hollow of the second hollow fiber membrane membrane provided therein; a dehumidification blower provided on one side of the hollow fiber membrane dehumidifier and selectively blowing sweep air to the second hollow fiber membrane; and an air supply line supplying air that has passed through the hollow fiber membrane humidifier and the hollow fiber membrane dehumidifier.

At this time, a blowing means provided on the first and second air inlet lines according to the present invention and selectively blowing external air to be supplied to the hollow fiber membrane humidifier and the hollow fiber membrane dehumidifier may be included.

In addition, the hollow fiber membrane humidifier according to the present invention includes a humidifying housing having a space therein, and a first hollow provided in the inner space of the humidifying housing and supplying moisture to the air flowing along the length of the hollow to humidify the air A desert membrane, an air inlet provided at one end of the humidifying housing and through which air to pass through the first hollow fiber membrane is introduced from the outside, and a desert membrane provided at the other end of the humidifying housing, the first hollow fiber membrane membrane An air outlet for discharging the passed air to the outside, a water inlet for supplying water to be absorbed into the first hollow fiber membrane while flowing to the surface of the first hollow fiber membrane, and an air outlet for supplying water to be absorbed into the first hollow fiber membrane. and a water outlet through which the water that is not absorbed by the first hollow fiber membrane is discharged to the outside while flowing.

Here, the hollow fiber membrane humidifier according to the present invention flows the air introduced through the first air inlet line into the hollow of the first hollow fiber membrane membrane, and the water introduced through the water supply unit to the surface of the first hollow fiber membrane membrane , the water absorbed through the surface of the first hollow fiber membrane is eluted as moisture along the hollow of the first hollow fiber membrane, and the eluted moisture is contained in the air flowing along the hollow to achieve humidification.

In addition, the first hollow fiber membrane according to the present invention comprises an annular capillary layer in which finger-shaped capillaries are continuously and repeatedly formed radially, an inner coating layer formed of a film on the inner surface of the capillary layer, and a film on the surface of the capillary layer. It includes an outer film layer formed of.

And the hollow fiber membrane dehumidifier according to the present invention allows the humid dehumidifying target air introduced through the second air inlet line to flow into the hollow of the second hollow fiber membrane membrane, so that the second hollow fiber membrane membrane flows along the hollow dehumidification target Dehumidification is achieved by absorbing moisture in the air, and surfaces facing laterally of the dehumidifying housing are opened to form an opening, and the sweep air introduced through the opening evaporates the moisture absorbed by the second hollow fiber membrane. let it

At this time, the hollow fiber membrane humidifier and the hollow fiber membrane dehumidifier according to the present invention are connected in parallel based on the air supply line, and either the hollow fiber membrane humidifier or the hollow fiber membrane dehumidifier is operated, or both the hollow fiber membrane humidifier and the hollow fiber membrane dehumidifier are operated together. can be driven

And the water supply unit according to the present invention is connected to the hollow fiber membrane humidifier, a water circulation line for circulating water along the line, provided on the water circulation line line, while receiving a corresponding amount of water, a certain amount of water A water storage tank for draining water and a pump provided on the water circulation line and pumping the water drained from the water storage tank to the hollow fiber membrane humidifier.

Effects exhibited by the hollow fiber membrane dehumidifier and the humidity control device having the same according to the present invention are as follows.

By using a humidifier and dehumidifier equipped with a hollow fiber membrane, it is possible to effectively automatically control the humidity of the air, and it is advantageous to reduce CO2 because it can minimize electrical energy, and it is possible to operate automatically, so it can be used for buildings, home appliances, and industrial purposes. Easy to apply.

At this time, when used for buildings or home appliances, it is possible to dehumidify by cooling or solve the problem caused by humidification that generates water droplets, which is a problem of existing humidifiers, so it is energy saving and maintains a pleasant and healthy level of humidity. can

In addition, temperature and humidity can be controlled at low cost (especially expected to be used in smart farms), so it can be deployed for purposes such as papermaking, museums, textile manufacturing, explosion-proof, and the like.

In addition, since water mist is not generated in the hollow fiber membrane humidifier, perfect humidification is possible, aseptic humidification is possible (solving the problem of existing humidifier sterilizers), and a very efficient humidifier capable of instantaneous humidification can be provided, There is no need to deliberately create hot water for humidification, so no separate energy (electricity) is used to provide hot water.

In addition, the dehumidification using a hollow fiber membrane does not generate heat during the dehumidification process, unlike the refrigerant compression dehumidifier, so the room temperature does not rise even after long-term dehumidification operation, and it does not require high-pressure air such as a compressor (compressor), so power consumption is low. It is small and can increase energy efficiency compared to the existing dehumidification method using a refrigerant.

In addition, since only the moisture absorbed by the hollow fiber membrane is contained in the air in the case of humidification using the hollow fiber membrane, there is no concern that impurities present in the water for humidification will be scattered into the air like water particles, and thus clean humidified air can be obtained.

In addition, since moisture particles in the gaseous state passing through the hollow fiber membrane are very small and the range of scattering in the air is very wide, it is possible to prevent dew condensation around the humidified air outlet.

In addition, since dehumidification is possible without lowering the temperature, it is suitable for the process of controlling temperature and humidity.

1 is a reference view showing a hollow fiber membrane dehumidifier using swept air according to a first embodiment of the present invention.
2 is a reference view showing a hollow fiber membrane dehumidifier using sweep air (external air) according to a second embodiment of the present invention.
3 is a reference view showing a hollow fiber membrane dehumidifier having membranes in a layer-by-layer form according to a second embodiment of the present invention.
4 is a reference view showing a hollow fiber membrane dehumidifier having a dehumidification blower according to a second embodiment of the present invention.
5 is a reference view showing a hollow fiber membrane dehumidifier having membranes in a layer-by-layer form and having a dehumidification blowing unit and a heating means according to a second embodiment of the present invention.
6 is a reference view showing a hollow fiber membrane dehumidifier using swept air while forming an annular hollow fiber membrane according to a third embodiment of the present invention.
7 is a reference view showing a humidity control device according to a fourth embodiment of the present invention.
8 is a reference view briefly showing a hollow fiber membrane humidifier according to a fourth embodiment of the present invention.
9 is a photograph showing a cross-section of the hollow fiber membrane of the hollow fiber membrane humidifier according to the fourth embodiment of the present invention.
10 is a reference diagram showing a state of use of a hollow fiber membrane humidifier according to a fourth embodiment of the present invention.
11 is a reference view briefly showing a hollow fiber membrane dehumidifier according to a fourth embodiment of the present invention.
12 is a reference view showing a state of use of the hollow fiber membrane dehumidifier according to the fourth embodiment of the present invention.
13 is an exemplary view showing a state in which a humidity control device according to a fourth embodiment of the present invention is applied to a ventilation system.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to the usual or dictionary meaning, and the inventor appropriately uses the concept of the term in order to explain his/her invention in the best way. Based on the principle that it can be defined, it should be interpreted as meaning and concept consistent with the technical spirit of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all of the technical ideas of the present invention, so at the time of the present application, they are equivalent alternatives that can be replaced. It should be understood that variations may exist.

In the present invention, a dehumidifier having a hollow fiber membrane for dehumidification as a main component that removes moisture from air to be dehumidified and a humidifier having a hollow fiber membrane for humidification as a main component for supplying moisture to air are connected in parallel to dehumidify air. It relates to a hollow fiber membrane dehumidifier for controlling humidity and a humidity control device having the same, which will be described with reference to the drawings.

The hollow fiber membrane dehumidifier 100 according to the first embodiment of the present invention with reference to FIG. 1 includes a dehumidifying housing 110, a hollow fiber membrane 120, an air inlet 130, an air outlet 140, and a sweep air supply unit 150. ), and a sweep air outlet 160. First, the dehumidifying housing 110 has a corresponding length and a space is formed therein so that one side and the other side are open to form a tubular shape having a corresponding length.

At this time, the hollow fiber membrane 120 is provided in the inner space of the dehumidifying housing 110, and the hollow fiber membrane 120 absorbs moisture from the air to be dehumidified flowing along the hollow length to dehumidify the air.

Here, the hollow fiber membrane 120 may have a tubular shape with a hollow inside, a plate shape, and a screen shape.

At this time, the plurality of tubular hollow fiber membranes 120 form a bundle, and absorb moisture from the dehumidifying target air flowing along the longitudinal direction while allowing the dehumidifying target air introduced from the outside to flow along the hollow to dehumidify the target air. to dehumidify

In addition, the plate-type and screen-type hollow fiber membranes 120 are provided in a layer-by-layer form in the inner space of the dehumidifying housing 110, so that the membrane 120 and the membrane 120 are spaced apart. Moisture absorbed by the hollow fiber membrane is evaporated by absorbing the moisture absorbed by the hollow fiber membrane from the air to be dehumidified flowing along the longitudinal direction while the sweep air introduced from the outside flows through the spaces.

In addition, an air inlet 130 is provided at one end of the dehumidifying housing 110, and the air inlet 130 forms an inlet through which air to be dehumidified is introduced and is provided at one end of the dehumidifying housing 110. Then, the air to be dehumidified to pass through the hollow fiber membrane 120 provided in the inner space of the dehumidifying housing 110 is introduced from the outside.

An air outlet 140 is provided at the other end of the dehumidifying housing 110 facing the air inlet 130, and the air outlet 140 forms an outlet through which dehumidified air flows out, and the dehumidifying housing ( 110), so that the dehumidified air passing through the hollow fiber membrane 120 provided in the inner space of the dehumidifying housing 110 flows out.

Here, a sweep air supply unit 150 may be provided adjacent to the air outlet 140 during the length of the dehumidifying housing 110, and the sweep air supply unit 150 flows in the lateral direction of the dehumidifying housing 110. While flowing along the surface of the hollow fiber membrane 120, sweep air that evaporates moisture absorbed by the hollow fiber membrane 110 is introduced from the outside.

In addition, a sweep air outlet 160 is provided adjacent to the air inlet 130 in the length of the dehumidifying housing 110, and the sweep air outlet 160 flows in the lateral direction of the dehumidifying housing 110 and Sweep air containing moisture evaporated from the hollow fiber membrane 120 is allowed to flow out.

In the present invention, it is described that the sweep air supply unit 150 is provided adjacent to the air outlet 140, and the sweep air outlet 160 is provided adjacent to the air inlet 130, but is not limited thereto. The sweep air supply unit 150 may be provided adjacent to the air inlet 130 and the sweep air outlet 160 may be provided adjacent to the air outlet 140 .

Therefore, the hollow fiber membrane dehumidifier 100 according to the first embodiment of the present invention introduces humid air to be dehumidified from the outside through the inlet of the air inlet 130, and the humid air to be dehumidified flows into the dehumidifying housing 110 While flowing along the hollow fiber membrane 120 provided in the inner space of ), it is discharged to the outside through the outlet of the air outlet 140 provided on the other side.

At this time, the hollow fiber membrane 120 absorbs and dehumidifies the moisture of the humid dehumidifying target air flowing along the inside, and the sweep air introduced through the sweep air supply unit 150 is inside the dehumidifying housing 110. While flowing along the surface of the provided hollow fiber membrane membrane 120, the moisture absorbed by the hollow fiber membrane membrane 120 is evaporated and contained, and the sweep air containing the evaporated moisture passes through the sweep air outlet 160 to the outside. leaked out to

Therefore, as the sweep air continuously evaporates and contains the moisture absorbed by the hollow fiber membrane membrane 120, the hollow fiber membrane membrane 120 is dried, and the dried hollow fiber membrane membrane 120 has It can continuously absorb moisture and dehumidify it.

The hollow fiber membrane dehumidifier 100 according to the second embodiment of the present invention with reference to FIGS. 2 to 5 includes a dehumidifying housing 110, a hollow fiber membrane 120, an air inlet 130, an air outlet 140, and a dehumidifying transport. It includes a rich 170. First, the dehumidifying housing 110 has a cylindrical shape having a corresponding length and forming a space therein.

At this time, it is preferable that one side of the dehumidifying housing 110 and the other facing side face are provided in an open type forming an open part 111 open to communicate with the outside, and a hollow fiber membrane membrane is provided in the inner space of the dehumidifying housing 110. A hollow fiber membrane 120 is provided, and the hollow fiber membrane 120 absorbs moisture from the air to be dehumidified flowing along the length of the hollow to dehumidify the air.

Here, the hollow fiber membrane 120 may have a tubular shape with a hollow inside, a plate shape, and a screen shape. It is preferable that a pair of the plate and screen hollow fiber membranes 120 form a set.

At this time, the plurality of tubular hollow fiber membranes 120 form a bundle, and dehumidify the air by absorbing moisture from the dehumidifying target air flowing in the longitudinal direction while flowing the dehumidifying target air introduced from the outside along the hollow. do.

In addition, the plate-type and screen-type hollow fiber membranes 120 are provided in a layer-by-layer form in the inner space of the dehumidifying housing 110, so that the membrane 120 and the membrane 120 are spaced apart. Moisture absorbed by the hollow fiber membrane from the air to be dehumidified flowing along the longitudinal direction is evaporated while the sweep air introduced from the outside flows through the spaces.

In addition, an air inlet 130 is provided at one end of the dehumidifying housing 110, and the air inlet 130 forms an inlet through which air to be dehumidified is introduced and is provided at one end of the dehumidifying housing 110. Then, the air to be dehumidified to pass through the hollow fiber membrane 120 provided in the inner space of the dehumidifying housing 110 is introduced from the outside.

An air outlet 140 is provided at the other end of the dehumidifying housing 110 facing the air inlet 130, and the air outlet 140 forms an outlet through which dehumidified air flows out, and the dehumidifying housing ( 110), so that the dehumidified air passing through the hollow fiber membrane 120 provided in the inner space of the dehumidifying housing 110 flows out.

Therefore, the hollow fiber membrane dehumidifier 100 configured as described above introduces humid air to be dehumidified from the outside through the inlet of the air inlet 130, and the humid air to be dehumidified is provided in the inner space of the dehumidifying housing 110 While flowing along the hollow fiber membrane 120, it is discharged to the outside through the outlet of the air outlet 140 provided on the other side.

At this time, the hollow fiber membrane 120 absorbs and dehumidifies the moisture of the humid dehumidifying target air flowing along the inside, and the sweep flowing from one side to the other side through the opening 111 of the dehumidifying housing 110 While the air flows along the surface of the hollow fiber membrane 120 provided inside the dehumidifying housing 110, the moisture absorbed by the hollow fiber membrane 120 is evaporated and contained, and the sweep air containing the evaporated moisture is leaked out

Therefore, as the sweep air continuously evaporates and contains the moisture absorbed by the hollow fiber membrane membrane 120, the hollow fiber membrane membrane 120 is dried, and the dried hollow fiber membrane membrane 120 has It can continuously absorb moisture and dehumidify it.

In addition, the hollow fiber membrane dehumidifier 100 shown in FIGS. 4 and 5 includes a desiccant blowing unit 170 in the opening 111 on one side or the other side of the dehumidifying housing 110, the dehumidifying blowing unit ( 170) blows sweep air in the lateral direction of the hollow fiber membrane membrane 120 to evaporate and remove the moisture absorbed by the hollow fiber membrane membrane 120 with the sweep air.

At this time, the dehumidifying blower 170 may include a dehumidifying blower 171 driven by power applied from the outside and a blower bracket 172 to which the dehumidifying blower 171 is fixed. The blower bracket 172 is provided to be selectively attached to and detached from the opening part 111 of the dehumidifying housing 110, or is formed extending from the dehumidifying housing 110, so that the blower bracket 172 is connected to the opening part 111 of the dehumidifying housing 110. may be provided integrally with

In addition, an exhaust damper 173 is formed on a side of the opening 111 of the dehumidifying housing 110 opposite to the side provided with the dehumidifying air blowing unit 170 to clean the surface of the hollow fiber membrane 120. Exhaust of the sweep air flowing along can be selectively controlled.

Therefore, the hollow fiber membrane dehumidifier 100 configured as described above introduces humid air to be dehumidified from the outside through the inlet of the air inlet 130, and the humid air to be dehumidified is provided in the inner space of the dehumidifying housing 110 While flowing along the hollow fiber membrane 120, it is discharged to the outside through the outlet of the air outlet 140 provided on the other side.

At this time, the hollow fiber membrane 120 absorbs and dehumidifies the moisture of the humid dehumidifying target air flowing along the inside, and through the opening 111 of the dehumidifying housing 110 by the dehumidifying blower 170 While the sweep air blown from one side to the other side flows along the surface of the hollow fiber membrane 120 provided inside the dehumidifying housing 110, the moisture absorbed by the hollow fiber membrane 120 is evaporated and contained, , the sweep air containing evaporated moisture is discharged to the outside.

Therefore, as the sweep air blown by the dehumidification blower 170 continuously evaporates and contains the moisture absorbed by the hollow fiber membrane membrane 120, the hollow fiber membrane membrane 120 is dried, and the dried hollow fiber membrane membrane (120) can continuously absorb and dehumidify the moisture of the humid air to be dehumidified.

In addition, the dehumidification blower 170 may include a heating means 180 that selectively generates heat on the side of the outlet through which the sweep air is blown.

At this time, the heating means 180 selectively generates heat with power supplied from the outside, and provides heat to the sweep air discharged from the dehumidification blower 170 so that the heated sweep air is transferred to the dehumidifying housing 110. While flowing along the surface of the hollow fiber membrane 120 provided therein, the moisture absorbed by the hollow fiber membrane 120 is evaporated.

Here, the heating means 180 may be provided separately, but heat generated from an electric motor, a pump, a compressor, or the like may be used as a heat source.

For example, the heating unit 180 may be provided as a heat sink, which is mounted at the rear end of the air compressor to dissipate heat in the air discharged from the air compressor through heat exchange with surrounding air, and discharges heat from the air compressor. cooling of the cooled air.

At this time, sweeping air heated by heat dissipation of the heat dissipation plate is blown to the surface of the hollow fiber membrane 120 to improve drying efficiency of the hollow fiber membrane 120 .

The hollow fiber membrane dehumidifier 100 according to the third embodiment of the present invention with reference to FIG. 6 includes a dehumidifying housing 110, a hollow fiber membrane 120, an air inlet 130, an air outlet 140, and a sweep air supply unit 150. ), a sweep air outlet 160, and a dehumidification blower 170. First, the dehumidification housing 110 has a tubular shape having a corresponding length and having a corresponding length with one side and the other side open to form a space therein. achieve

At this time, the hollow fiber membrane 120 is provided in the inner space of the dehumidifying housing 110, and the hollow fiber membrane 120 has a tubular shape with a hollow inside, and a plurality of hollow fiber membranes 120 along the inner space of the dehumidifying housing 110. Arranged in the form of a round ring to form an annular bundle, it absorbs moisture from the air to be dehumidified flowing along the length of the hollow to dehumidify the air to be dehumidified.

Here, a passage through which sweep air flows is provided at the center of the annularly arranged bundle of the hollow fiber membrane membranes 120, and the sweep air introduced into the center of the bundle of the hollow fiber membrane membranes 120 is radially distributed, so that the hollow fiber membrane Moisture absorbed by the membranes 120 is evaporated.

In addition, an air inlet 130 is provided at one end of the dehumidifying housing 110, and the air inlet 130 forms an inlet through which air to be dehumidified is introduced and is provided at one end of the dehumidifying housing 110. Then, the air to be dehumidified to pass through the hollow fiber membrane 120 provided in the inner space of the dehumidifying housing 110 is introduced from the outside.

An air outlet 140 is provided at the other end of the dehumidifying housing 110 facing the air inlet 130, and the air outlet 140 forms an outlet through which dehumidified air flows out, and the dehumidifying housing ( 110), so that the dehumidified air passing through the hollow fiber membrane 120 provided in the inner space of the dehumidifying housing 110 flows out.

Here, a sweep air supply unit 150 may be provided adjacent to the air outlet 140 during the length of the dehumidifying housing 110, and the sweep air supply unit 150 flows in the lateral direction of the dehumidifying housing 110. While flowing along the surface of the hollow fiber membrane 120, sweep air that evaporates moisture absorbed by the hollow fiber membrane 110 is introduced from the outside.

In addition, a sweep air outlet 160 is provided adjacent to the air inlet 130 in the length of the dehumidifying housing 110, and the sweep air outlet 160 flows in the lateral direction of the dehumidifying housing 110 and Sweep air containing moisture evaporated from the hollow fiber membrane 120 is allowed to flow out.

At this time, the sweep air supply unit 150 may be provided with a dehumidification blower 170. The dehumidify blower 170 is centered on the bundle of the annular hollow fiber membranes 120 through the sweep air supply unit 150. By blowing sweep air, the moisture absorbed by the hollow fiber membrane 120 may be evaporated and removed by the sweep air.

In the present invention, it is described that the sweep air supply unit 150 is provided adjacent to the air outlet 140, and the sweep air outlet 160 is provided adjacent to the air inlet 130, but is not limited thereto. The sweep air supply unit 150 may be provided adjacent to the air inlet 130 and the sweep air outlet 160 may be provided adjacent to the air outlet 140 .

Therefore, the hollow fiber membrane dehumidifier 100 according to the third embodiment of the present invention introduces humid air to be dehumidified from the outside through the inlet of the air inlet 130, and the humid air to be dehumidified flows into the dehumidifying housing 110 ) is discharged to the outside through the outlet of the air outlet 140 provided on the other side while flowing along the central passage of the hollow fiber membrane 120 module provided in the inner space of the membrane.

At this time, the hollow fiber membrane 120 absorbs and dehumidifies the moisture of the humid dehumidifying target air flowing along the hollow, and the sweep air introduced through the sweep air supply unit 150 is inside the dehumidifying housing 110. While flowing along the surface of the provided hollow fiber membrane membrane 120, the moisture absorbed by the hollow fiber membrane membrane 120 is evaporated and contained, and the sweep air containing the evaporated moisture passes through the sweep air outlet 160 to the outside. leaked out to

Therefore, as the sweep air continuously evaporates and contains the moisture absorbed by the hollow fiber membrane membrane 120, the hollow fiber membrane membrane 120 is dried, and the dried hollow fiber membrane membrane 120 has It can continuously absorb moisture and dehumidify it.

The humidity control device according to the fourth embodiment of the present invention with reference to FIGS. 7 to 12 includes first and second air inlet lines 10 and 20, a hollow fiber membrane humidifier 200, a water supply unit 300, It includes a hollow fiber membrane dehumidifier 100, a dehumidification blower 170, and an air supply line 30, and the first and second air inlet lines 10 and 20 introduce outside air, and the introduced air are induced from one side to the other, respectively.

At this time, each of the first and second air inlet lines 10 and 20 is a duct through which air flows, and the front end of each of the first and second air inlet lines 10 and 20 removes foreign substances contained in the external air. The hollow fiber membrane humidifier 200 is provided on the first air inlet line 10, and the hollow fiber membrane dehumidifier 100 is provided on the second air inlet line 20. .

In addition, the first and second air inlet lines 10 and 20 are provided with blowing means 11 and 21, respectively, and each of the blowing means 11 and 21 is the hollow fiber membrane humidifier 200 and the hollow fiber membrane External air is selectively blown into the dehumidifier (100).

The hollow fiber membrane humidifier 200 is provided on the line of the first air inlet line 10, and the hollow fiber membrane humidifier 200 flows along the hollow of the first hollow fiber membrane membrane 220 provided therein Humidify the air.

Here, looking at the hollow fiber membrane humidifier 200 in more detail, the hollow fiber membrane humidifier 200 includes a humidifying housing 210, a first hollow fiber membrane 220, an air inlet 230, an air outlet 240, moisture It includes an inlet 250 and a moisture outlet 260. First, the humidifying housing 210 has a corresponding length and a space is formed therein so that one side and the other side are open to form a tubular shape having a corresponding length.

At this time, a first hollow fiber membrane 220 is provided in the inner space of the humidifying housing 210, and the first hollow fiber membrane 220 provides moisture to the air flowing along the hollow length to humidify it.

Here, it is preferable that the first hollow fiber membrane membrane 220 has a tubular shape with a hollow inside. A plurality of tubular first hollow fiber membrane membranes 220 form a bundle, and the inflow from the outside along the hollow While the air is flowing, the air flowing along the longitudinal direction is humidified by containing moisture eluted into the hollow of the first hollow fiber membrane 220 .

Referring to FIG. 9 , the first hollow fiber membrane 220 forms an endothelial layer and a capillary layer on the surface of the endothelial layer. 9 is a photograph showing a cross section of the first hollow fiber membrane membrane, a photograph showing a cross section of the first hollow fiber membrane 220 from the left, and a photograph showing a cross section of the capillary layer of the first hollow fiber membrane 220, This is a photograph showing the inner circumferential surface of the first hollow fiber membrane 220 and a photograph showing the outer surface of the first hollow fiber membrane 220 .

At this time, the capillary layer is formed by radially continuously and repeatedly forming finger-shaped capillaries, and an outer film layer is formed on the surface of the capillary layer.

Therefore, when water flows to the surface of the first hollow fiber membrane membrane 220, the water is absorbed through the outer film layer, and the water absorbed into the outer film layer is transferred to the inner film layer by the capillary phenomenon by the capillary layer, It is eluted as water from the film layer.

In addition, an air inlet 230 is provided at one end of the humidifying housing 210, and the air inlet 230 forms an inlet through which air is introduced and is provided at one end of the humidifying housing 210, Air to pass through the first hollow fiber membrane 220 provided in the inner space of the humidifying housing 210 is introduced from the outside.

An air outlet 240 is provided at the other end of the humidifying housing 210 facing the air inlet 230, and the air outlet 240 forms an outlet through which air flows out, and the humidifying housing 210 provided at the other end of the humidifying housing 210, so that the air passing through the first hollow fiber membrane 220 provided in the inner space of the humidifying housing 210 is discharged to the outside.

Here, a moisture inlet 250 is provided adjacent to the air outlet 240 of the length of the humidifying housing 210, and the moisture inlet 250 flows into the humidifying housing 210, and the humidifying housing While flowing along the surface of the first hollow fiber membrane 220 provided inside the 210, eluting into the hollow of the first hollow fiber membrane 220, the hollow of the first hollow fiber membrane 220 Water (moisture) is introduced from the outside so that the air flowing along the air contains moisture.

In addition, a moisture outlet 260 is provided adjacent to the air inlet 230 in the length of the humidifying housing 210, and the moisture outlet 260 flows through the inside of the humidifying housing 210 while moving through the first hollow Water not absorbed by the desert membrane 220 is allowed to flow out.

The hollow fiber membrane humidifier 200 is connected to the water supply unit 300, and the water supply unit 300 selectively circulates water to the first hollow fiber membrane membrane 220.

At this time, the water supply unit 300 includes a water circulation line 301, a water storage tank 310, and a pump 320, and the water circulation line 301 is a water inlet of the hollow fiber membrane humidifier 200 ( 250) and the water outlet 260 to circulate water along the line to the hollow fiber membrane humidifier 200.

Here, a water storage tank 310 and a pump 320 are provided on the water circulation line 301, and the water storage tank 310 drains a certain amount while accommodating a corresponding amount of water, and the pump 320 The water drained from the water storage tank 310 is pumped to the hollow fiber membrane humidifier 200 .

Therefore, the water supplied to the hollow fiber membrane humidifier 200 is supplied by the water supply unit 300, and the water drained from the water storage tank 310 of the water supply unit 300 is on the water circulation line 301 line. The water that is pressurized by the pump 320 and introduced into the humidifying housing 210 through the water inlet 250 of the hollow fiber membrane humidifier 200, and the water introduced into the humidifying housing 210 is 210 flows along the surface of the first hollow fiber membrane 220 provided inside, is absorbed into the first hollow fiber membrane 220, and turns into moisture through the hollows of the first hollow fiber membrane 220. The moisture eluted into the hollow of the first hollow fiber membrane 220 is contained in the air flowing along the hollow of the first hollow fiber membrane 220 and humidified.

And the water not absorbed by the first hollow fiber membrane membrane 220 flows again to the water circulation line 301 through the water outlet 260 of the hollow fiber membrane humidifier 200, and the water circulation line 301 The water that has flowed to forms a circulation route that is accommodated in the water storage tank 310 of the water supply unit 300 again.

The hollow fiber membrane dehumidifier 100 is provided on the line of the second air inlet line 20 and dehumidifies air flowing along the hollow of the second hollow fiber membrane membrane 120 provided therein.

At this time, the hollow fiber membrane dehumidifier 100 includes a dehumidifying housing 110, a second hollow fiber membrane 120, an air inlet 130, an air outlet 140, and a dehumidifying blower 170. First, the dehumidifying housing (110) forms a cylindrical shape having a corresponding length and forming a space therein.

It is preferable that one side of the dehumidifying housing 110 and the other facing side face are provided in an open type forming an open part 111 open to communicate with the outside, and the second hollow fiber membrane is provided in the inner space of the dehumidifying housing 110. A membrane 120 is provided. The second hollow fiber membrane 120 absorbs moisture from air flowing along the length of the hollow to dehumidify the air.

Here, the second hollow fiber membrane 120 may have a tubular shape having a hollow inside, a plate shape, or a screen shape. The plate and screen second hollow fiber membranes 120 form a pair. it is desirable

At this time, a plurality of the tubular second hollow fiber membranes 120 form a bundle, and dehumidify the air by absorbing moisture from the air flowing along the longitudinal direction while allowing air introduced from the outside to flow along the hollow.

In addition, the plate-type and screen-type second hollow fiber membranes 120 are provided in a layer-by-layer form in the inner space of the dehumidifying housing 110, so that the membrane 120 and the membrane 120 Moisture absorbed by the hollow fiber membrane from the air to be dehumidified along the longitudinal direction is evaporated while the sweep air introduced from the outside flows between the spaced apart spaces between the hollow fiber membranes.

In addition, an air inlet 130 is provided at one end of the dehumidifying housing 110, and the air inlet 130 forms an inlet through which air is introduced and is provided at one end of the dehumidifying housing 110, Air to pass through the second hollow fiber membrane 120 provided in the inner space of the dehumidifying housing 110 is introduced from the outside.

An air outlet 140 is provided at the other end of the dehumidifying housing 110 facing the air inlet 130, and the air outlet 140 forms an outlet through which air flows out, and the dehumidifying housing 110 It is provided at the other end of the dehumidifying housing 110 so that air passing through the second hollow fiber membrane 120 provided in the inner space of the housing 110 flows out to the outside.

Therefore, the hollow fiber membrane dehumidifier 100 configured as described above introduces humid air from the outside through the inlet of the air inlet 130, and the humid air introduced into the second hollow fiber membrane provided in the inner space of the dehumidifying housing 110 While flowing along the membrane 120, it is discharged to the outside through the outlet of the air outlet 140 provided on the other side.

At this time, the hollow fiber membrane 120 absorbs and dehumidifies the moisture of the humid air flowing along the inside, and the sweep air flowing from one side to the other side through the opening 111 of the dehumidifying housing 110 While flowing along the surface of the second hollow fiber membrane membrane 120 provided inside the dehumidifying housing 110, the moisture absorbed by the second hollow fiber membrane 120 is evaporated and contained, and the evaporated moisture is contained. Sweep air is discharged to the outside.

Therefore, as the sweep air continuously evaporates and contains the moisture absorbed by the second hollow fiber membrane 120, the second hollow fiber membrane 120 is dried, and the dried second hollow fiber membrane 120 It can continuously absorb moisture from humid air and dehumidify it.

In addition, a desiccant blowing unit 170 is provided at the opening 111 on one side or the other side of the dehumidifying housing 110, and the dehumidifying blowing unit 170 is located on the side of the second hollow fiber membrane 120. By blowing sweep air in the direction, the moisture absorbed by the second hollow fiber membrane 120 is evaporated and removed by the sweep air.

At this time, the dehumidifying blower 170 may include a dehumidifying blower 171 driven by power applied from the outside and a blower bracket 172 to which the dehumidifying blower 171 is fixed. The blower bracket 172 is provided to be selectively attached to and detached from the opening part 111 of the dehumidifying housing 110, or is formed extending from the dehumidifying housing 110, so that the blower bracket 172 is connected to the opening part 111 of the dehumidifying housing 110. may be provided integrally with

In addition, the dehumidification blowing unit 170 may include the heating means 180, and the heating means 180 is preferably provided as a heat sink, and the heat sink is mounted at the rear end of the air compressor, so that the air compressor Heat in the air discharged from the air is dissipated by heat exchange with ambient air, so that the air discharged from the air compressor is cooled.

At this time, sweep air heated by heat dissipation of the heat dissipation plate is blown to the hollow fiber membrane 120 to improve drying efficiency of the hollow fiber membrane 120 .

Therefore, the hollow fiber membrane dehumidifier 100 configured as described above introduces humid air from the outside through the inlet of the air inlet 130, and the humid air introduced into the second hollow fiber membrane provided in the inner space of the dehumidifying housing 110 While flowing along the membrane 120, it is discharged to the outside through the outlet of the air outlet 140 provided on the other side.

At this time, the second hollow fiber membrane membrane 120 absorbs and dehumidifies the moisture of the humid air flowing along the inside, and the dehumidification blower 170 through the opening 111 of the dehumidifying housing 110 While the sweep air blown from one side to the other side flows along the surface of the second hollow fiber membrane 120 provided inside the dehumidifying housing 110, the second hollow fiber membrane 120 absorbs moisture. The sweeping air containing the evaporated water and the evaporated moisture is discharged to the outside.

Therefore, as the sweep air blown by the dehumidification blower 170 continuously evaporates and contains the moisture absorbed by the second hollow fiber membrane 120, the second hollow fiber membrane 120 is dried and dried. The second hollow fiber membrane 120 may continuously absorb and dehumidify moisture from humid air.

In addition, the air supply line 30 supplies air that has passed through the hollow fiber membrane humidifier 200 and the hollow fiber membrane dehumidifier 100 .

At this time, in the humidity control device according to an embodiment of the present invention, the hollow fiber membrane humidifier 200 and the hollow fiber membrane dehumidifier 100 are connected in parallel based on the air supply line 30, and the hollow fiber membrane humidifier 200 and Either one of the hollow fiber membrane dehumidifiers 100 may be operated, or both the hollow fiber membrane humidifier 200 and the hollow fiber membrane dehumidifier 100 may be operated together.

The humidity control device according to an embodiment of the present invention can be widely used throughout the industry. For example, when used in an oxygen generator, a general oxygen generator generates oxygen using zeolite, and the zeolite is introduced into the device. Oxygen is produced by adsorbing nitrogen from the air and releasing the remaining oxygen.

However, since the zeolite is a hydrophilic material, when air with high humidity is introduced into the device, more moisture than nitrogen is adsorbed, and thus, there is a problem in that oxygen production efficiency is reduced during a season with high humidity such as summer.

Therefore, when the humidity control device according to the present invention is provided on the air inlet side of the oxygen generator, the humidity control device removes moisture from the air before it is introduced into the oxygen generator to lower the humidity, thereby reducing the oxygen production efficiency of the oxygen generator. can be kept constant regardless of the season.

Therefore, the hollow fiber membrane dehumidifier and the humidity control device having the same according to the present invention can effectively automatically control the humidity of air and minimize electrical energy by using the humidifier and the dehumidifier equipped with the hollow fiber membrane membrane, so it is advantageous for CO2 reduction. It is capable of automatic operation, making it easy to apply to buildings, home appliances, and industrial applications.

At this time, when used for buildings or home appliances, it is possible to dehumidify by cooling or solve problems caused by humidification such as water droplets, which is a problem of existing humidifiers, so it is energy-saving and maintains a pleasant and healthy level of humidity. can

In addition, temperature and humidity can be controlled at low cost (especially expected to be used in smart farms), so it can be deployed for purposes such as papermaking, museums, textile manufacturing, explosion-proof, and the like.

In addition, since water mist is not generated in the hollow fiber membrane humidifier, perfect humidification is possible, aseptic humidification is possible (solving the problem of existing humidifier sterilizers), and a very efficient humidifier capable of instantaneous humidification can be provided, There is no need to deliberately create hot water for humidification, so no separate energy (electricity) is used to provide hot water.

In addition, the dehumidification using a hollow fiber membrane does not generate heat during the dehumidification process, unlike the refrigerant compression dehumidifier, so the room temperature does not rise even after long-term dehumidification operation, and it does not require high-pressure air such as a compressor (compressor), so power consumption is low. It is small and can increase energy efficiency compared to the existing dehumidification method using a refrigerant.

In addition, since only the moisture absorbed by the hollow fiber membrane is contained in the air in the case of humidification using the hollow fiber membrane, there is no concern that impurities present in the water for humidification will be scattered into the air like water particles, and thus clean humidified air can be obtained.

In addition, since moisture particles in the gaseous state passing through the hollow fiber membrane are very small and the range of scattering in the air is very wide, it is possible to prevent dew condensation around the humidified air outlet.

In addition, since dehumidification is possible without lowering the temperature, it is suitable for the process of controlling temperature and humidity.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

10: first air inlet line 11, 21: blowing means
20: second air inlet line 30: air supply line
100: hollow fiber membrane dehumidifier 110: dehumidifying housing
111: opening 120, 220: hollow fiber membrane
130: air inlet 140: air outlet
150: sweep air supply unit 160: sweep air outlet
170: dehumidification blower 171: dehumidification blower
172: blower bracket 180: heating means
200: hollow fiber membrane humidifier 210: humidifying housing
230: air inlet 240: air outlet
250: water inlet 260: water outlet
300: water supply unit 301: water circulation line
310: water storage tank 320: pump

Claims (8)

first and second air inlet lines for introducing external air and guiding the introduced air from one side to the other, respectively;
a hollow fiber membrane humidifier provided on the first air inlet line and humidifying the air flowing along the hollow of the first hollow fiber membrane membrane provided therein;
a water supply unit connected to the hollow fiber membrane humidifier and selectively circulating water through the first hollow fiber membrane;
a hollow fiber membrane dehumidifier provided on the second air inlet line and dehumidifying air flowing along the hollow of the second hollow fiber membrane membrane provided therein;
a dehumidification blower provided on one side of the hollow fiber membrane dehumidifier and selectively blowing sweep air to the second hollow fiber membrane; and
A humidity control device having a hollow fiber membrane dehumidifier comprising an air supply line for supplying air passing through the hollow fiber membrane humidifier and the hollow fiber membrane dehumidifier.
The method of claim 1,
It is provided on the first and second air inlet lines, respectively,
A humidity control device having a hollow fiber membrane dehumidifier comprising a blowing means for selectively blowing external air to be supplied to the hollow fiber membrane humidifier and the hollow fiber membrane dehumidifier.
The method of claim 1,
The membrane humidifier
A humidifying housing with a space formed therein;
a first hollow fiber membrane provided in the inner space of the humidifying housing and humidifying the air by supplying moisture from the air flowing along the length of the hollow;
an air inlet provided at one end of the humidifying housing and introducing air to pass through the first hollow fiber membrane from the outside;
an air outlet provided at the other end of the humidifying housing and discharging air passing through the first hollow fiber membrane to the outside;
a water inlet for supplying water to be absorbed into the first hollow fiber membrane while flowing to the surface of the first hollow fiber membrane;
A humidity control device with a hollow fiber membrane dehumidifier comprising a water outlet through which water that is not absorbed by the first hollow fiber membrane flows to the outside while flowing to the surface of the first hollow fiber membrane membrane.
The method of claim 3,
The hollow fiber membrane humidifier
The air introduced through the first air inlet line flows into the hollow of the first hollow fiber membrane membrane, and the water introduced through the water supply unit flows to the surface of the first hollow fiber membrane membrane, thereby forming the first hollow fiber membrane membrane. A humidity control device having a hollow fiber membrane dehumidifier in which water absorbed through the surface of the first hollow fiber membrane is eluted as moisture along the hollow of the first hollow fiber membrane membrane, and the eluted moisture is contained in air flowing along the hollow to achieve humidification.
The method of claim 3,
The first hollow fiber membrane is
An annular capillary layer in which finger-shaped capillaries are continuously and repeatedly formed radially;
An inner coating layer formed of a film on the inner surface of the capillary layer;
Humidity control device having a hollow fiber membrane dehumidifier comprising an outer film layer formed of a film on the surface of the capillary layer.
The method of claim 5,
The hollow fiber membrane dehumidifier
Moist air introduced through the second air inlet line flows into the hollow of the second hollow fiber membrane membrane, and the second hollow fiber membrane absorbs moisture from the air flowing along the hollow to achieve dehumidification. A humidity control device having a hollow fiber membrane dehumidifier in which surfaces facing each other in a lateral direction are opened to form an opening, and sweep air introduced through the opening evaporates moisture absorbed by the second hollow fiber membrane membrane.
The method of claim 1,
The hollow fiber membrane humidifier and hollow fiber membrane dehumidifier
Humidity control device having a hollow fiber membrane dehumidifier connected in parallel based on the air supply line, wherein only one of the hollow fiber membrane humidifier and the hollow fiber membrane dehumidifier is operated, or both the hollow fiber membrane humidifier and the hollow fiber membrane dehumidifier are operated together.
The method of claim 1,
the water supply
a water circulation line connected to the hollow fiber membrane humidifier and circulating water along the line;
a water storage tank provided on the water circulation line and accommodating a corresponding amount of water and draining a certain amount of water;
A humidity control device having a hollow fiber membrane dehumidifier including a pump provided on the water circulation line and pumping the water drained from the water storage tank to the hollow fiber membrane humidifier.

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