KR20170138956A - An air cleaner - Google Patents

Abstract

The present invention relates to an air cleaner, which has a dehumidification function, a humidification function, and a low noise level by rotating a disc without a wing. According to an embodiment of the present invention, the air cleaner includes: a suction unit sucking outer air; a housing having a discharge unit discharging the sucked air; a filter arranged between the suction unit and the discharge unit and purifying the air sucked; a gas pump connected to the discharge unit and discharging the air purified by the filter to the discharge unit by rotation; and a control unit controlling a rotation direction of the gas pump. The gas pump includes: a gas pump base disc supported to rotate by being arranged in the housing; a gas pump disc array in which each segment disc is piled on the gas pump base disc to be spaced from each other, wherein a center area of the each segment disc is open; a rotor including a rotor magnet installed in the gas pump base disc; and a stator including a stator coil installed to face the rotor magnet by being installed in the housing.

Description

An air cleaner

The present invention relates to an air purifier, and more particularly, to an air purifier including a dehumidifying and humidifying function.

All of the existing commercial air cleaners and dehumidifiers circulated the air by rotating the Sikorsky or propeller, so that the noise generated when the sirocco wing or the propeller wing hit the air was inevitable.

In order to avoid noise generation, there is a dehumidifier that excludes the air circulation function, but since the humidity in the air is not forcibly circulated, the dehumidification efficiency is so low that most of the products have failed to be commercialized.

Also, the heating type humidifier does not have a blowing device but the humidification effect is not so good. In case of the ultrasonic humidifier, the blowing device is essential, and the blowing noise problem is commercialized as a very serious condition.

Korean Patent Registration No. KR 10-0908464 (registered on July 13, 2009)

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and an object of the present invention is to provide an air cleaner having a dehumidifying and humidifying function.

According to an embodiment of the present invention, there is provided an air purifier including a suction unit for sucking outside air, a housing having a discharge unit for discharging sucked air, a filter disposed between the suction unit and the discharge unit to purify the sucked air, And a control unit for controlling a rotating direction of the gas pump and a gas pump communicating with the gas pump and discharging the air purified by the filter to the discharge unit by rotation, wherein the gas pump includes a gas pump base Disk, a gas pump disk array in which each segment disk having a center area opened in a state spaced apart from each other on the base pump disk is stacked, and a rotor including a rotor magnet installed in the gas pump base disk, And a stator including a stator coil provided so as to be opposed thereto.

The water pump is rotated in the same direction as the gas pump, and when the gas pump is rotated forward, water is sucked from the water tank to spray water onto the disk array, And may further include a liquid pump that, when rotated, does not spray water onto the disk array.

The liquid pump includes a liquid pump housing including an outlet formed to face the direction of normal rotation of the gas pump, a liquid pump base disk disposed in the liquid pump housing and connected to the same shaft as the gas pump and rotatably supported, And a liquid pump disk array in which each segment disk having a central region opened in a state of being spaced apart from each other is stacked.

And a controller for controlling the temperature of the external air and the humidity of the outside air, wherein the control unit controls the gas pump to rotate in the forward direction when the humidity of the outside air measured by the sensor unit is lower than a predetermined humidity range, And when the humidity of the outside air measured from the sensor unit is higher than the preset humidity range, the gas pump can be rotated in the reverse direction to operate the dehumidification mode for discharging air having a low moisture content. The control unit also measures the relative humidity according to the temperature and operates the gas pump.

And a cooling element disposed between the suction portion and the discharge portion for cooling the moisture in the air to be sucked or for heating the cooled moisture according to the direction of the current applied from the control portion.

And a condensation sensor for measuring a degree of freezing formed in the cooling element. When the degree of freezing measured by the condensation sensor is lower than a predetermined degree of freezing, a current flows in a positive direction in the cooling element to freeze moisture in the air, If the degree of freezing measured in the step of measuring the degree of freezing is higher than the predetermined degree of freezing, a current flows in a reverse direction to the cooling element to melt the freezing water again.

And a sterilizing unit connected to the water tank or the cooling element, for sterilizing water by electrolyzing water present in the water tank or the cooling element.

The water turbidity sensor further includes a water turbidity sensor for measuring the degree of contamination of the water tank or the cooling element, and the control unit can operate the sterilizing unit when the turbidity measured by the water turbidity sensor is higher than a predetermined turbidity.

The air purifier according to an embodiment of the present invention can purify and circulate air in a state in which noise is hardly generated.

1 is a perspective view of an air purifier according to an embodiment of the present invention.
2 is a sectional view of the air cleaner shown in Fig.
FIG. 3 is an exploded perspective view of the interior of the air cleaner shown in FIG. 1; FIG.
4 is an exploded perspective view of the rotor shown in Fig.
5A to 5B are operation diagrams of the liquid pump shown in Fig.
6 is a block diagram showing the control of the control unit.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which: FIG. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

FIG. 1 is a perspective view of an air cleaner according to an embodiment of the present invention, FIG. 2 is a sectional view of the air cleaner shown in FIG. 1, FIG. 3 is an exploded perspective view of the inside of the air cleaner shown in FIG. Fig. 4 is an exploded perspective view of the rotor shown in Fig. 2, Figs. 5a to 5b are operation diagrams of the liquid pump shown in Fig. 2, and Fig. 6 is a block diagram showing control of the controller.

1 to 6, the air purifier 100 according to an embodiment of the present invention can purify contaminated air outside without noise using a BLDC motor, A gas pump 120, a water tank 130, a liquid pump 140, a cooling element 150, a sensor unit 160, and a sensor unit 160. The housing 101, the filter 110, the gas pump 120, And a controller 170.

The housing 101 has a suction portion 101a for sucking outside air and a discharge portion 101b for discharging the sucked air. The inner space of the housing 101 is divided into an intake chamber communicating with the intake portion 101a and an exhaust chamber communicating with the exhaust portion 101b and communicated by the central region of the opened gas pump disk array. The outer shape of the housing 101 may be a rectangular parallelepiped shape as shown in the drawings, but it may be cylindrical. The housing 101 may be manufactured by injecting plastic or by pressing a metal.

The filter 110 is disposed in the housing 101 between the suction portion 101a and the discharge portion 101b and removes foreign matter from the air sucked from the suction portion 101a to purify the air.

The filter 110 may include, for example, a primary filter 110 for filtering particles of a predetermined size to remove large dust particles, a secondary filter 110 for collecting particles of an anion by plasma discharge to remove small dust particles, As shown in FIG.

The gas pump 120 is disposed in the housing 101 to suck the purified air from the filter 110 to discharge the purified air to the discharge portion 101b of the housing 101, And a stator 122 including a stator coil 122a to which a current is applied by interaction so that the rotor 121 and the rotor 121 are rotated.

The rotor 121 includes a gas pump base disk 121a, a gas pump disk array 121b, a spacer (not shown), and a rotor magnet 121c. The gas pump base disk 121a is fixed to the rotary shaft so as to be rotatable and rotated by the action of the stator coil 122a to which the electric current is applied from the external power source. The gas pump base disk 121a can be rotated, for example, from about 10,000 revolutions per minute to about 10,000,000 revolutions per minute. However, the number of revolutions of the gas pump base disk 121a is not limited thereto, and may vary depending on the size of the gas pump base disk 121a.

The gas pump disk array includes a plurality of gas pump segment discs 121b spaced apart from each other and stacked on the gas pump base disk 121a at regular intervals. The gas pump segment disk 121b has an opening in the center area, and the outside air is sucked into the central area as the gas pump segment disk 121b is rotated.

In addition, the gas pump disk array may, for example, be spaced apart by spacers (not shown) disposed between each gas pump segment disk 121b. The gas pump base disk 121a is rotated and the centrifugal force and the boundary layer pulling effect are applied to the air positioned between the respective gas pump segment discs 121b as the gas pump segment discs 121b are spaced apart from each other, Drag Effect) to move the air outward.

Each gas pump segment disk 121b can be fixed to the adjacent gas pump segment disk 121b and the gas pump base disk 121a by fastening means 121d such as bolts.

The gas pump segment disc 121b may be curved at its ends to facilitate suction and discharge of the gas. However, the end portion of the gas pump segment disk 121b is not limited thereto, but may be formed to be angled at a right angle.

Here, the gas pump base disk 121a and the gas pump segment disk 121b may include materials made of a corrosion-resistant material or a special coating.

The rotor magnet 121c is installed on the rotor 121 and interacts with the stator coil 122a. For example, the rotor magnet 121c may be installed on the base pump disk 121a. Here, the rotor magnet 121c may be a permanent magnet, but is not limited thereto and may be constituted by an electromagnet.

The stator 122 is disposed in the housing 101 and includes a stator coil 122a that interacts with the rotor magnet 121c. The stator coil 122a may be formed on a surface facing the rotor magnet 121c and powered.

Here, the gas pump 120 may use a rotary shaft provided on both sides of a commercially available BLDC (Brushless DC) motor.

The water tank 130 is connected to the housing 101 and has an internal space capable of storing water. The water tank 130 communicates with the liquid pump 140 to supply water to the liquid pump 140 when the liquid pump 140 is rotated.

The water tank 130 is connected to the cooling element 150 through a tube pipe 144 or the like so that the liquid can be stored when the water frozen in the cooling element 150 is thawed.

5A to 5B, the liquid pump 140 is connected to the same rotation axis as the gas pump 120 and is rotated in the same direction as the gas pump 120, and may not discharge or discharge water according to the rotation direction .

The liquid pump 140 includes a liquid pump housing 141, a liquid pump base disk 142, and a liquid pump segment disk 143. The liquid pump housing 141 forms an outlet 141a having the same direction as the normal rotation direction of the gas pump 120 so that water is discharged F1 when the gas pump 120 is rotated forward, The air is sucked in the opposite direction (F2) so that water is not discharged. Here, the outlet may be connected to the tube tube 144, which, for example, is sprayed onto the gas pump disk array so that water exiting the liquid pump 140 can be injected into the gas pump disk array.

The liquid pump base disk 142 is connected to the rotating shaft and rotated in the same direction as the gas pump base disk 121a. A plurality of liquid pump segment discs 143 are stacked on a liquid pump base disk 142 to form a liquid pump 140 disk array. The liquid pump segment disk 143 has an open central region connected to the water tank 130 so that the water stored in the water tank 130 is sucked into the central region as the liquid pump segment disk 143 is rotated.

In addition, the liquid pump segment discs 143 may be spaced 1 mm apart, for example, by spacers (not shown) disposed between each liquid pump segment discs 143. Since each liquid pump segment disk 143 is spaced apart from each other, the liquid pump base disk 142 is rotated and the centrifugal force and the boundary layer pulling effect Drag Effect) to move the air outward, but there is no wing to minimize noise generation.

Each liquid pump segment disk 143 can be secured to adjacent liquid pump segment disk 143 and liquid pump base disk 142 by fastening means such as bolts.

The cooling element 150 is disposed between the intake chamber and the exhaust chamber, and can cool the water in the sucked air to freeze, thereby lowering the humidity. The cooling element 150 causes endothermic or exothermic heat by using the Peltier effect in which heat is absorbed or generated by the current. Since the cooling element 150 can switch between the heat absorption and the heat generation according to the current direction, it is possible not only to freeze the moisture in the inhaled air, but also to defrost the frozen water again to water the water tank 130 in the liquid state Can be transported.

The cooling element 150 may be formed, for example, in the shape of a funnel having a central region opened so that purified and dehumidified air can be introduced into the open region.

The sensor unit 160 may include a humidity sensor for measuring the humidity of the outside air, a temperature sensor for measuring the temperature of the outside air, and a pollution degree sensor for measuring the pollution degree of the outside air. The sensor unit 160 measures the humidity, the temperature, and the pollution degree of the outside air and transfers the result to the controller 170.

The control unit 170 can turn on / off the gas pump 120 or vary the rotation direction of the gas pump 120 according to the humidity, temperature, and pollution degree of the outside air.

For example, when the humidity of the outside air measured by the humidity sensor is lower than a preset humidity range, the control unit 170 operates in a humidifying mode in which the gas pump 120 is rotated forward. Since the gas pump 120 discharges the gas regardless of the rotating direction, the gas pump 120 discharges the purified air. Here, as the gas pump 120 is rotated in the forward direction, the liquid pump 140 connected with the same rotation axis is also rotated in the forward direction. When the liquid pump 140 rotates in the forward direction, the water filled in the water tank 130 is sucked and discharged to the outlet of the liquid pump housing 141, so that the water is discharged to the gas pump disk array through the tube pipe 144 connected to the outlet Water is sprayed. As a result, the gas pump 120 discharges highly humid air including droplets of the ultrafine molecules, and thus has a humidifying effect.

The control unit 170 operates in a dehumidification mode in which the gas pump 120 is rotated in the reverse direction if the humidity of the outside air measured by the humidity sensor is higher than the predetermined humidity range in the control unit 170. [ Since the gas pump 120 discharges the gas regardless of the rotating direction, the gas pump 120 discharges the purified air. Here, as the gas pump 120 is rotated in the reverse direction, the liquid pump 140 connected at the same rotational axis is also rotated in the reverse direction. When the liquid pump 140 is rotated in the reverse direction, the direction of the outlet of the liquid pump housing 141 is different from that of the disk array rotational direction of the liquid pump 140, and the water can not be discharged. As a result, the liquid pump 140 idles without pumping water.

In the dehumidifying mode, the cooling element 150 is operated to freeze the moisture contained in the sucked outside air, thereby lowering the humidity of the sucked air. The sucked air is discharged to the outside through the gas pump 120 in a state in which the humidity is low.

At this time, the sensor unit 160 may further include a condensation sensor for measuring the degree of freezing formed in the cooling element 150. In this case, when the degree of freezing measured by the condensation sensor is received and the degree of freezing is lower than the predetermined degree of freezing, the controller 170 flows a current in the forward direction to the cooling element 150 to freeze moisture in the air into the cooling element 150. If the degree of freezing measured by the condensation sensor is higher than the predetermined degree of freezing, a current is flowed in a reverse direction to the cooling element 150 to melt the water that has been frozen in the cooling element 150 and supply the freezing water to the water tank 130 .

The air cleaner may further include a sterilizing unit 180 for sterilizing the water present in the water tank 130 or the cooling element 150. The sterilizing unit 180 electrolyzes water to generate hydrogen, and generates a small amount of ozone to sterilize the water.

The sterilizing unit 180 can operate regardless of whether the gas pump 120 and the liquid pump 140 are driven to sterilize the water. That is, the sterilizing unit 180 can simultaneously sterilize water when the gas pump 120 and the liquid pump 140 are driven, and the gas pump 120 and the liquid pump 140 are stopped to purify the air Water can be sterilized even when it is not used.

The sterilizing portion 180 may be, for example, a non-diaphragm titanium electrode plate. A module in which hydrogen and a small amount of ozone are generated can be used by electrolyzing water by using a platinum-plated titanium plate having ellipses of the same size arranged at regular intervals, .

The sterilizing portion 180 may be another example of a hydrogen patch. The hydrogen patch is formed by including an insulating resin 181 formed in the transverse direction and a platinum wire 182 formed in the longitudinal direction and woven with the insulating resin 181. Here, the horizontal direction and the vertical direction can be reversed.

As another example, the sterilizing unit 180 may be a hydrogen generating apparatus. The hydrogen generating device sterilizes water through hydrogen bubbles generated by electrolysis of water.

The hydrogen generator includes, for example, an electrolysis electrode unit, a porous ceramic catalyst, and a resistance value sensor unit 160. The electrolytic electrode part electrolyzes and sterilizes the water that contacts the hydrogen generator. The porous ceramic catalyst absorbs ozone generated during the electrolysis process to reduce harmfulness. The resistance value sensor unit 160 measures the resistance value of water, measures the concentration of the electrolyte dissolved in the water, and transmits the measured concentration to the control unit 170.

The control unit 170 may adjust the time for varying the voltage according to the received resistance value.

In this case, the sensor unit 160 may further include a water turbidity sensor for measuring the degree of contamination of the water tank 130 or the cooling element 150. The control unit 170 may receive the measured value from the water turbidity sensor and operate the hydrogen generator until the predetermined turbidity is lower than the predetermined turbidity.

The air cleaner 100 may further include a display unit 190. The display unit 190 may be, for example, an LED light emitting device that emits red, blue, or green light. The display unit 190 may emit different colors depending on the state of the outside air measured from the sensor.

For example, the display unit 190 displays yellow when the humidity of the outside air is higher than a predetermined value, displays red when the pollution degree of the outside air is higher than the preset value, and green when the humidity and pollution degree of the outside air is lower than the predetermined value. As shown in FIG.

In addition, the display unit 190 may display not only the LED light emitting device but also the state of the air cleaner 100 or the state of outside air. The display unit 190 may be, for example, an LCD or an OLED, but is not limited thereto.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

Claims (8)

A housing having a suction portion for sucking outside air and a discharge portion for discharging sucked air;
A filter disposed between the suction portion and the discharge portion to purify the sucked air;
A gas pump communicating with the discharge portion and discharging the air purified by the filter to the discharge portion by rotation; And
And a control unit for controlling a rotating direction of the gas pump,
The gas pump includes:
A gas pump base disk disposed in the housing and rotatably supported; a gas pump disk array in which each segment disk having a center area opened in a state of being spaced apart from each other on the gas pump base disk is stacked; A rotor including a rotor magnet;
And a stator disposed in the housing and disposed to face the rotor magnet.
The method according to claim 1,
Water tank to store water; And
When the gas pump is rotated in the forward direction, water is sucked from the water tank to spray water onto the disk array, and when the gas pump is rotated in the reverse direction, the disk array is rotated in the same direction as the gas pump, Further comprising a liquid pump that does not spray water on the air cleaner.
3. The method of claim 2,
The liquid pump
A liquid pump base disk disposed in the liquid pump housing and connected to the same axis as the gas pump and rotatably supported, and a liquid pump base disk disposed in the liquid pump housing, And a liquid pump disk array in which each segment disk having a center area opened with a space therebetween is stacked.
3. The method of claim 2,
Further comprising a sensor unit for measuring the temperature or humidity of the outside air,
Wherein the control unit operates the gas pump in a humidification mode for discharging air having a high moisture content when the humidity of the outside air measured by the sensor unit is lower than a predetermined humidity range,
And when the humidity of the outside air measured by the sensor unit is higher than a preset humidity range, the gas purifier reversely rotates to operate a dehumidifying mode for discharging air having a low moisture content.
3. The method of claim 2,
And a discharge port disposed between the suction portion and the discharge portion,
Further comprising a cooling element for cooling the moisture in the air to be sucked or for heating the cooled moisture in accordance with a current direction applied from the control part.
6. The method of claim 5,
Further comprising a condensation sensor for measuring a degree of freezing formed in the cooling element,
Wherein the controller is configured to cause a current to flow in the forward direction to the cooling element to freeze moisture in the air if the degree of freezing measured by the condensation sensor is lower than a predetermined degree of freezing,
And when the degree of freezing measured by the condensation sensor is higher than a predetermined degree of freezing, a current flows in a reverse direction to the cooling element to melt the iced water again.
6. The method of claim 5,
And a sterilizing unit connected to the water tank or the cooling device for electrolyzing water present in the water tank or the cooling device to sterilize the water.
8. The method of claim 7,
Further comprising a water turbidity sensor for measuring the degree of contamination of the water tank or the cooling element, wherein the control unit operates the sterilizing unit when the turbidity measured by the water turbidity sensor is higher than a predetermined turbidity.

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