KR102350159B1 - Air purifier - Google Patents

Abstract

An air purification apparatus capable of purifying air is disclosed according to an embodiment of the present disclosure. The air purifier includes a biofilter for purifying air, and includes at least one biofilter unit; an outer frame having a space accommodating the bio-filter unit therein and supporting the bio-filter unit; an environment monitoring unit capable of monitoring an internal and external environment of the air purification device; and an environmental control unit for controlling the air purifier based on the environmental data of the environmental monitoring unit to maintain the vegetation environment of the bio-filter unit, and wherein the bio-filter unit allows the roots of plants for hydroponics to pass through. A planting unit comprising at least one of a hydroponic cultivation bag comprising at least one hole having a size capable of being able to grow and at least one of a vegetation medium in which a plant can grow; a planting frame capable of supporting the planting unit; and a water filter that supplies moisture to the plants and purifies the air.

Description

air purifier {AIR PURIFIER}

The present disclosure relates to a device capable of purifying air, and more particularly, to an air purification device having a biofilter capable of removing fine dust in the air.

Fine dust is a small particle with a diameter of less than 10㎛ or 2.5㎛, 5 or 20 times smaller than the diameter of a human hair. Fine dust composed of various components contains more than 50% of sulfates and nitrates, which are formed by chemical reaction of fossil fuels and air pollutants in automobile exhaust gas or soot from factory chimneys in the air. The particle diameter of fine dust is very small and it penetrates the human body as it is, and the fine dust that penetrates the human body can cause respiratory and allergic diseases. has been designated

While various methods for preventing the generation of such fine dust or removing the generated fine dust have been proposed, a method for removing the fine dust using plants has also been proposed. Fine dust absorbed by the leaves of plants can be removed by being used as metabolites, and fine dust entering the soil containing roots can be decomposed by microorganisms in the roots. In addition, plants can make the environment around the plants pleasant by emitting various substances such as negative ions, fragrance, oxygen, and moisture.

KR 10-1938003

The present disclosure has been made in response to the above-described background art, and is intended to provide an air purification device including a biofilter capable of purifying air.

Disclosed is an air purification apparatus capable of purifying air according to an embodiment of the present disclosure for realizing the above-described problems. The air purifier includes a biofilter for purifying air, and includes at least one biofilter unit; an outer frame having a space accommodating the bio-filter unit therein and supporting the bio-filter unit; an environment monitoring unit capable of monitoring an internal and external environment of the air purification device; and an environmental control unit for controlling the air purifier based on the environmental data of the environmental monitoring unit to maintain the vegetation environment of the bio-filter unit, and wherein the bio-filter unit allows the roots of plants for hydroponics to pass through. A planting unit comprising at least one of a hydroponic cultivation bag comprising at least one hole having a size capable of being able to grow and at least one of a vegetation medium in which a plant can grow; a planting frame capable of supporting the planting unit; and a water filter that supplies moisture to the plants and purifies the air.

Alternatively, the water filter may include: one or more liquid ejection units controlled based on a control signal of the environmental control unit to further purify the air purified by the biofilter into a liquid; a fan for moving the air whose driving speed is controlled based on a control signal from the environment controller; a water filter frame in which the liquid jet unit and the fan are accommodated and having a space through which air can move; a water tank capable of storing the liquid drained from the bio-filter unit; and a water pipe connected from the water tank to the liquid spraying unit to reuse the liquid stored in the water tank to the plants.

Alternatively, the water tank may include a filter for purifying the liquid stored therein; an ultrasonic transducer for dividing the liquid stored therein into small particles; and a pump for delivering the liquid to the conduit.

Alternatively, the liquid comprises water, a nutrient solution or a mixed solution, and the nutrient solution comprises: an essential component comprising macro-elements and trace elements essential for the survival of the plant; And it may include a fertilizer component that can help the growth of the plant.

Alternatively, the filter may include a physical filter made of a porous material; And it may be composed of at least one of a biofilter composed of algae.

Alternatively, the outer frame may include: a duct for supplying purified air to the space to be supplied; and a blower that moves the purified air to the space to be supplied through the duct and whose operating speed is controlled based on a control signal from the environment controller.

Alternatively, the environment monitoring unit may include: a sensor unit configured to sense internal and external environmental information of the air purification device; a communication unit for transmitting the environmental data measured by the sensor unit to at least one of the environment control unit or an external computer; Alternatively, it may include at least one of a camera unit for visually monitoring the state of the bio-filter unit.

Alternatively, the sensor unit may include a temperature and humidity sensor capable of monitoring the temperature and humidity of the bio-filter unit; a light quantity sensor for measuring the light quantity of the bio-filter unit; a fine particle sensor capable of measuring the concentration of fine particles inside and outside the air purification device; an air component measuring sensor capable of measuring an air component inside and outside the air purification device; Alternatively, it may include at least one of an air volume sensor capable of measuring an air volume of at least one of intake and exhaust of the air purification device.

Alternatively, the air purification apparatus may further include a temperature controller configured to control the temperature of the air purification apparatus based on a control signal of the environment controller.

Alternatively, the air purification apparatus may further include a light control unit capable of adjusting the amount of light provided to the bio-filter unit based on a control signal from the environment control unit.

Alternatively, the light control unit may include: a light transmitting unit capable of transmitting external light of the air purification device to the inside of the air purification device; and a light control unit configured to adjust the amount of light of the light transmission unit based on a control signal of the environment control unit.

Alternatively, the light control unit may include a lighting unit capable of supplying light to the inside of the bio-filter unit based on a control signal of the environment control unit.

Alternatively, the air purification apparatus may further include a nutrient solution supply unit capable of supplying the nutrient solution to the bio-filter unit based on a control signal from the environment control unit.

Alternatively, the air component measurement sensor may include an optical type gas sensor that measures the component of the gas by sensing different infrared absorption amounts according to the components of the gas using infrared rays.

Alternatively, the air purification apparatus may further include a HEPA filter unit for allowing the air passing through the air purification apparatus to be purified at least once more.

The present disclosure may provide an air purifying device including a biofilter capable of purifying air.

1 is a perspective view of the air purification apparatus 1000 in which a part of the external frame component 1230 is excluded to explain the internal structure of the air purification apparatus 1000 according to an embodiment of the present disclosure.
2 is an exemplary view of a water filter 300 according to an embodiment of the present disclosure.
3 is a cross-sectional view of the air purification apparatus 1000 including the outer frame component 1230 according to an embodiment of the present disclosure.
4 is a cross-sectional view of the air purification apparatus 1000 including the outer frame component 1230 according to another embodiment of the present disclosure.
5 is a plan view excluding the outer frame component 1230 to show the inside of the air purification apparatus 1000 including the outer frame 1200 according to an embodiment of the present disclosure.
6 is a plan view excluding the outer frame component 1230 to show the inside of the air purification apparatus 1000 including the outer frame 1200 according to another embodiment of the present disclosure.
7 is a plan view excluding the outer frame part 1230 to show the inside of the air purification apparatus 1000 including the outer frame 1200 according to another embodiment of the present disclosure.
8 is a block diagram of a control system of the air purification apparatus 1000 including the environment monitoring unit 1300 and the environment control unit 1400 according to an embodiment of the present disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS Various embodiments are now described with reference to the drawings, wherein like reference numerals are used to refer to like elements throughout. In this specification, various descriptions are presented to provide an understanding of the present disclosure. However, it is apparent that these embodiments may be practiced without these specific descriptions.

1 is a perspective view of the air purification apparatus 1000 in which a part of the external frame component 1230 is excluded to explain the internal structure of the air purification apparatus 1000 according to an embodiment of the present disclosure.

In the air purification apparatus 1000 according to an embodiment of the present disclosure, air including fine particles from the outside may be purified while passing through the biofilter. For example, fine particles may refer to particles having a diameter of 2.5 μm or less to include ultrafine dust.

According to an embodiment of the present disclosure, a planting unit 100 including a biofilter composed of plants, and a water filter 300 including a liquid spraying unit 310 capable of supplying a liquid including moisture and nutrient solution. The bio-filter unit may be composed of at least one or more. In the case of two or more biofilters, the planting unit 100 exposed to the outside may be used with a different function from the planting unit 100 positioned inside the air purification apparatus 1000 . That is, the planting unit 100 located inside is composed of a plant focusing on the air purification function, and the planting unit 100 exposed to the outside is composed of a plant focusing on the aesthetic function rather than the air purification function. have. Accordingly, when the plant of the planting unit 100 exposed to the outside includes a plant that reproduces sexually using spores or pollen, planting materials exposed to the outside to prevent the spread of allergic spores and pollen to the outside A glass barrier may be installed on the unit 100 . The glass blocking film may be configured to include one or more holes through which air may enter on any side other than the side that may block the injection path of spores and pollen of plants. In addition, the glass blocking film may be installed in combination with the planting frame 200 including the planting unit 100 exposed to the outside, or may be configured to be easily separated from the planting frame 200 .

The planting unit 100 according to an embodiment of the present disclosure is composed of a vegetation medium capable of cultivating plants by selecting one of a soil or soilless cultivation method as a method for cultivating a plant constituting the biofilter. can be In the case of soil cultivation, the vegetation medium may be composed of soil, and in the case of soilless cultivation, the vegetation medium may be configured to enable solid medium or hydroponic cultivation. A solid medium is a solid medium in which nutrients are added to non-lipid such as gelatin and agar. Natural organic materials such as peat moss, huntan, rice husk, bark, coco peat, charcoal, and minerals such as rock wool, sand, gravel, vermiculite, and perlite are used. may include, but the present disclosure is not limited thereto. The planting unit 100 may be configured to include, instead of a vegetation medium, one or more holes having a size through which the roots of plants can pass, and a hydroponic cultivation bag composed of one or more so that hydroponic cultivation is possible.

According to an embodiment of the present disclosure, the planting unit 100 is supported by the planting frame 200, and the planting frame 200 and the planting unit 100 are detachable so that the planting unit 100 needs replacement or When cleaning is required, the planting unit 100 may be separated from the planting frame 200 . In addition, the planting frame 200 may include one or more holes larger than the size through which the liquid sprayed by the liquid spraying unit 310 of the water filter 300 can pass on the surface in contact with the planting unit 100 . have. The shape of the hole may be different from each other, and may be composed of a rectangle, a circle, a rhombus, etc., but the present disclosure is not limited thereto. Also, the holes may be arranged irregularly with each other. In addition, the planting frame 200 may include at least one or more bracket structures that can support the planting unit 100 . The planting frame 200 may be made of a metal or alloy material such as a composite plastic or aluminum and stainless steel, which is a material with high strength and rigidity so that deformation and destruction due to temperature or humidity do not occur easily, but the present disclosure is not limited thereto. does not In addition, the planting frame 200 may have a structure detachable from the external frame 1200 or the water filter 300 for hygiene management.

The external frame 1200 according to an embodiment of the present disclosure allows the external air of the air purification apparatus 1000 and the purified air distributed inside the air purification apparatus 1000 through the bio filter unit to be separated from each other. . The size and shape of the bio-filter unit may be determined according to the size and shape of the outer frame 1200 accommodating the bio-filter unit therein. That is, as shown in FIG. 1 , the outer frame 1200 may be configured in a rectangular shape or a cylindrical pipe shape to accommodate one or more biofilter units, but the present disclosure is not limited to the outer frame 1200 . It is not limited to the shape. Also, the size and shape of the bio-filter unit may be configured to be different from that of the external frame 1200 . Accordingly, in order to extend the air movement path inside the air purification apparatus 1000 , at least two biofilter units having different sizes and shapes may be configured. In addition, the two or more bio-filter units may be positioned at positions having different geometric centers from each other. The outer frame part 1230 may be included to form a space blocked from the outside, and the density of carbon dioxide in the space blocked from the outside may be increased. As shown in FIG. 1 , when the planting unit 100 is composed of two or more, it is possible to increase the carbon dioxide absorption of the plant of the planting unit 100 located inside the heavy air purification device 1000 . Accordingly, the oxygen production in the air purification apparatus 1000 may be increased, and thus the produced oxygen may be supplied to the outside. A detailed description of the outer frame component 1230 will be described later with reference to FIGS. 3 to 4 . The outer frame 1200 may be configured to support the water filter 300 and the planting frame 200 , and accordingly, may have a structure coupled to the water filter 300 , and may also be configured according to one or more embodiments. It may have a structure capable of being combined with the planting frame 200 . Various embodiments of the outer frame 1200 are shown below with reference to FIGS. 5 to 7 , and a detailed description thereof will be given later. The outer frame 1200 may be made of a metal material to be resistant to wear and corrosion due to fine particles and to have high durability, but the present disclosure is not limited thereto. The outer frame 1200 may include at least one blower 1220 configured to move the purified air and one or more ducts 1210 through which the air purified by the blower 1220 may move. A detailed description of the duct 1210 and the blower 1220 will be described later with reference to FIG. 3 .

According to an embodiment of the present disclosure, the water filter 300 includes a liquid ejection unit 310 composed of one or more, and the liquid ejection unit 310 purifies the liquid containing moisture or nutrient solution to fine particles in the air. It can be composed of a sprinkler and a spray nozzle device that can spray the size that can be done. The sprayed liquid may be sprayed toward the planting unit 100 and the planting frame 200, and the liquid that has passed through the planting unit 100 and the planting frame 200 is supplied to the plants of the planting unit 100 or a water tank ( 350) can be stored. The water tank 350 may include a filter 351 capable of filtering the stored liquid therein, and may include at least one or more sidewalls inside the water tank 350 . At least one of the sidewalls constituting the water tank 350 may be configured not to be spaced apart from the planting frame 200 to block external air that has not passed through the planting unit 100 . Air purified by the liquid sprayed from the liquid spray unit 310 may be moved through one or more fans 320 positioned between the planting frame 200 and the outer frame 1200 . One or more fans 320 are installed to be located at a position higher than the water level of the water tank 350, and the operating speed of the fan 320 is controlled by the environmental control unit 1400. A detailed description thereof will be described later in FIG. 8 It will be described later with reference.

According to an embodiment of the present disclosure, the air purification apparatus 1000 may further include a HEPA filter unit including at least one HEPA filter so that the air passing through the air purification apparatus 1000 may have an additional air purification process. have. The HEPA filter unit may be located between the planting frame 200 and the water filter 300 or between the water filter 300 and the external frame 1200, and may include at least one.

2 is an exemplary view of a water filter 300 according to an embodiment of the present disclosure.

The water filter 300 according to an embodiment of the present disclosure may include a water filter frame, a liquid jet unit 310 , a fan 320 , and a water tank 350 . The water filter frame includes a water filter second part 332 in which one or more liquid jetting units 310 can be installed, and a water filter first part 331 supporting the water filter second part 332 on both sides. can do. Accordingly, the water filter second part 332 is formed in the form of a beam fixedly supported on both sides by the water filter first part 331, and at least one fan ( 320) can be formed to accommodate the space. In addition, the method of fixing the position of the water filter second part 332 may be achieved through coupling with the external frame 1230, and various embodiments thereof will be described in detail later with reference to FIGS. 5 to 7 . . One or more liquid ejection units 310 installed in the water filter second part 332 eject the liquid to purify the air by adsorbing fine particles. The air purified by the liquid may be located under the water filter second part 332 to be moved by one or more fans 320 , and the distance between the planting unit 100 and the fan 320 is the planting unit 100 . ) and the liquid ejection unit 310 may be positioned to be farther than a distance. The liquid of the liquid jet unit 310 may be a liquid stored in the water tank 350 and may include water, a nutrient solution, or a mixed solution, but the present disclosure is not limited thereto. Nutrient solution may contain essential components including macro-elements and trace elements essential for the survival of plants. Macroelement may be composed of carbon, phosphorus, hydrogen, nitrogen, calcium, etc., which are nutrient components required in large amounts for the survival of plants, but the present disclosure is not limited thereto. Trace elements may be composed of zinc, nickel, boron, copper, etc., which are nutrient components necessary but indispensable for the survival of plants in small amounts, but the present disclosure is not limited thereto. In addition, the nutrient solution may include a fertilizer component that can help the growth of plants. The mixed solution may include water containing one or more of the components presented in the nutrient solution or a liquid containing two or more inorganic and organic components, such as a drug for disinfection. The liquid spray unit 310 may be disposed at a distance through which the planting unit 100 and air can pass, and may be installed at a position where the liquid can be sprayed toward the planting unit 100 . Accordingly, the liquid injection unit 310 may be controlled to supply moisture and nutrient solution to the plants of the planting unit 100 , and also to the environmental control unit 1400 to further purify the air that has passed through the planting unit 100 . controlled by A detailed description thereof will be described later with reference to FIG. 8 .

The water tank 350 according to an embodiment of the present disclosure is located below the liquid spraying unit 310 and the planting unit 100 to store the liquid sprayed by the liquid spraying unit 310 . The water tank 350 may be accommodated in the outer frame 1200 to have a fixed position. The water tank 350 may be made of a material such as ceramic or alloy that may have corrosion resistance and durability against liquid, but the present disclosure is not limited thereto. The filter 351 capable of separating and combining the inside of the water tank 350 and purifying the stored liquid may be composed of a physical filter made of a porous material and a bio filter including algae. Algae is composed of green algae and the like, but the present disclosure is not limited thereto. In addition, the biofilter may be configured in a structure separable from the water tank 350 so that algae can be used as a fuel as biomass or as nano-cellulose, which is an eco-friendly nano material. The liquid purified through the filter 351 is transferred to the pump 352 through the water pipe 340 , and the water pipe 340 is configured to be connected to one surface of the water tank 350 and the liquid injection unit 310 . A detailed description thereof will be described later with reference to FIG. 3 . The filter 351 may serve as one or more sidewalls configured inside the water tank 350 to form a separate space inside the water tank 350 . In addition, the tank 350 in which the liquid is stored may additionally include an ultrasonic transducer therein, so that the liquid divided into small particles by vibration may be ejected into the air. The small particles of the liquid have a size that can float in the air, control the humidity inside the air purifier 1000, and can additionally remove fine particles in the air. In addition, small particles ejected into the air may supply moisture to the plants of the vegetation unit 100 . The ultrasonic transducer has a size and shape that can be included in the water tank 350, and may be configured to include a piezoelectric material to generate ultrasonic waves using a piezoelectricity. The piezoelectric material may include at least one of a lead zirconate titanate (PZT)-based synthetic material and a polycrystalline piezoelectric ceramic material such as BaTiO3. The above description of the piezoelectric material is only an example, and the present disclosure is not limited thereto. The ultrasonic transducer may be composed of at least one multi-layer based on the vibration direction of the piezoelectric material in order to broaden the ultrasonic band. The piezoelectric material layer thus constructed may include an electrode layer in contact with a pair of opposing surfaces of the piezoelectric material layer in order to receive electricity, and the electrode layer may be configured to allow electricity to flow inside the piezoelectric material layer. Accordingly, with respect to the piezoelectric material layer composed of two or more layers, the electrode layer may be additionally formed between the surfaces of the piezoelectric material layers facing each other. In addition, the ultrasonic transducer may be configured such that a diaphragm capable of transmitting ultrasonic vibrations of the piezoelectric material layer to the liquid inside the water tank 350 is in contact with any one electrode. In order to increase the vibration transmission efficiency of the diaphragm, the ultrasonic transducer may be operated in a state fixed to one side of the inside of the water tank 350 , and the vibration speed of the ultrasonic transducer may be controlled by the environment controller 1400 .

3 is a cross-sectional view of the air purification apparatus 1000 including the outer frame component 1230 according to an embodiment of the present disclosure.

The air purification apparatus 1000 according to an embodiment of the present disclosure may include an external frame 1200 and an external frame component 1230 to have a space blocked from the outside of the biofilter unit. Accordingly, the concentration of carbon dioxide included in the air purification apparatus 1000 may increase, and a greenhouse may be formed. When the planting unit 100 is composed of one or more, the planting unit 100 is located in the greenhouse formed therein, so that the vegetation environment of the planting unit 100 can be easily created. One surface of the outer frame part 1230 may be fixedly coupled to the planting frame 200 , the second water filter part 332 , and one surface of the outer frame 1200 , respectively. Accordingly, the space blocked from the outside of the air purification apparatus 1000 may be formed by coupling the outer frame component 1230 and the outer frame 1200 . The outer frame 1200 may include a water pipe 340 therein. Also, the water pipe 340 may be included in the water filter second part 332 , and may be included in the water filter first part 331 not shown in FIG. 3 . The pump 352 and the water tank 350 located inside the outer frame 1200 may be connected to each other through the water pipe 340 , and the pump 352 and the liquid injection unit 310 may also be connected to each other through the water pipe 340 . can Accordingly, the liquid in the water tank 350 may be delivered to the liquid ejection unit 310 through the pump 352 and the water pipe 340 . The space of the water tank 350 to which the water pipe 340 is connected is one of the spaces separated by the filter 351 , and the liquid stored in another space by the operation of the pump 352 passes through the filter 351 . do. The pump 352 may be a submersible pump capable of pumping water, an agricultural irrigation pump, etc., but the present disclosure is not limited thereto. The water tank 350 may be located under the planting frame 200 so that the liquid sprayed by the liquid spraying unit 310 passing through the planting unit 100 is collected, and the planting unit 100 and the planting frame 200 . It may be configured to have a size that can store even a liquid that has not passed through. In order to completely separate the external air and the internal air of the air purification device 1000 , the planting frame 200 including the planting unit 100 exposed to the outside is sized to be in contact with the liquid stored in the water tank 350 . and a shape, but the present disclosure is not limited thereto. In addition, the planting frame 200 may be located at a position capable of contacting the liquid stored in the water tank 350 .

The duct 1210 according to an embodiment of the present disclosure may be configured as the only passage through which the inside of the air purification device 1000 can be connected to the outside, but by the external frame component 1230 configured according to another embodiment It may be excluded or configured as an additional passage. This will be described later with reference to FIG. 4 . The duct 1210 may supply purified air to the outside of the air purification apparatus 1000 . The purified air may be supplied based on the location of the duct 1210 . Accordingly, the space to which the purified air is supplied may be a space to which the purified air is supplied. For example, when the air purifier 1000 is included in the air conditioning system for ventilation inside a building, the space to which the purified air is supplied may be the entire building or a space surrounded by an outer wall, such as a room inside the building. In addition, the target space for supplying the purified air may be outside the building. Air may be moved by the blower 1220 located inside the duct 1210 . The operating speed of the blower 1220 may be controlled based on a control signal of the environmental control unit 1400 that has received the environmental data about the air from the environmental monitoring unit 1300, and for a detailed description thereof, see FIG. 8 later. to be described later.

4 is a cross-sectional view of the air purification apparatus 1000 including the outer frame component 1230 according to another embodiment of the present disclosure.

The external frame part 1230 according to another embodiment of the present disclosure may be configured as shown in FIG. 4 so that the air purification apparatus 1000 including the external frame part 1230 can independently provide purified air. . The outer frame part 1230 may be configured to be fixedly coupled to one surface of the planting frame 200 and the second part of the water filter, and accordingly, the outer frame 1200 is a surface that is not coupled to the external frame part 1230. may include That is, the space blocked from the outside of the air purification apparatus 1000 may be formed by combining the external frame component 1230 , the second water filter component, and the planting frame 200 . The air purified by the liquid jet unit 310 may be moved to the open side of the air purification device 1000 through the fan 320 and may be supplied to the outside. The duct 1210 may be omitted to simplify the configuration of the device, but may be additionally configured to increase the efficiency of the air conditioning system.

5 is a plan view excluding the outer frame part 1230 to show the inside of the air purification apparatus 1000 including the outer frame 1200 according to an embodiment of the present disclosure.

The outer frame 1200 and the water filter first part 331 according to an embodiment of the present disclosure may be fixedly coupled to the planting frame 200, and may be configured to be detachable for cleaning and management. The planting frame 200 and the water filter second part 332 are installed to include a surface facing the outer frame 1200, and the distance between the liquid injection unit 310 and the planting frame 200 or the water filter product The distance between the second part 332 and the outer frame 1200 may be configured to include at least a distance through which air may pass. The bottom surface of the water tank 350 may be configured to have an area greater than the sum of the cross-sectional area of the planting frame 200 and the planting unit 100 . Also, the air purification apparatus 1000 according to an embodiment may include an external frame part 1230 according to an embodiment, or an external frame part 1230 according to another embodiment.

6 is a plan view excluding the outer frame component 1230 to show the inside of the air purification apparatus 1000 including the outer frame 1200 according to another embodiment of the present disclosure.

The outer frame 1200 according to another embodiment of the present disclosure is configured as shown in FIG. 6 , and is fixedly coupled to the water filter first part 331 and the planting frame 200 or configured to be detachable from each other. can be The planting frame 200 and the water filter second part 332 are installed to include a surface facing the outer frame 1200, and the distance between the outer frame 1200 and the water filter second part 332 and the liquid injection The distance between the unit 310 and the planting frame 200, and the bottom surface area of the water tank 350 are the same as those described in FIG. 5, so a detailed description will be omitted. Also, the air purification apparatus 1000 according to another embodiment may include the external frame part 1230 according to the embodiment or the external frame part 1230 according to another embodiment.

7 is a plan view excluding the outer frame component 1230 to show the inside of the air purification apparatus 1000 including the outer frame 1200 according to another embodiment of the present disclosure.

The outer frame 1200 according to an embodiment of the present disclosure is configured as shown in FIG. 6 , and may be configured to be fixedly coupled to the planting frame 200 and the second water filter part 332 or to be detachably attached to each other. have. The planting frame 200 and the water filter second part 332 are installed to include a surface facing the outer frame 1200, and the distance between the outer frame 1200 and the water filter second part 332 and the liquid injection The distance between the unit 310 and the planting frame 200, and the bottom surface area of the water tank 350 are the same as those described in FIG. 5, so a detailed description will be omitted. Also, the air purification apparatus 1000 according to another embodiment may include an external frame part 1230 according to an embodiment or an external frame part 1230 according to another embodiment.

8 is a block diagram of a control system of the air purification apparatus 1000 including the environment monitoring unit 1300 and the environment control unit 1400 according to an embodiment of the present disclosure.

The environmental monitoring unit 1300 according to an embodiment of the present disclosure can measure environmental data including environmental factors for temperature, humidity, and light for plant cultivation and environmental factors for air containing fine particles. The sensor unit 1310 is included, and accordingly, the sensor unit 1310 may include at least one sensor capable of measuring the environment, such as a temperature and humidity sensor, a light amount sensor, a fine particle sensor, an air component measurement sensor, and an air volume sensor. have. The temperature and humidity sensor is a sensor capable of measuring temperature and humidity, and the temperature and humidity sensor is divided into a temperature sensor and a humidity sensor, respectively, or a temperature and humidity sensor configured to measure temperature and humidity by one sensor. The light amount sensor includes a sensor capable of measuring the amount of light generated by all light sources, including natural light sources such as sunlight and artificial light sources caused by lighting. In addition, at least one temperature-humidity sensor and light quantity sensor may be installed inside and outside the bio-filter unit to monitor the temperature and humidity and light quantity inside the plant or the bio-filter unit of the planting unit 100 . The fine particle sensor may measure the concentration of fine particles inside and outside the air purification apparatus 1000 , and the fine particles may be set as particles including at least one criterion for classifying fine dust. In addition, it is possible to classify air pollutants constituting fine dust by measuring the air components inside and outside the air purification device 1000 through the air component measurement sensor, and measure the ratio of air pollutants to air. have. Accordingly, the air component measurement sensor is a semiconductor type, catalytic combustion type, hot wire type, solid electrolyte type, constant potential electrolysis type, non-dispersive infrared type, SAW type, thermoelectric type, depending on the type of gas contamination source to monitor gaseous substances. , a chemiluminescence method, an arc ultraviolet light spectroscopy method, etc. may be included in at least one gas sensor. A semiconductor gas sensor that uses a metal oxide semiconductor as a sensing material, a catalytic combustion gas sensor that is applied to detect combustible gas, and an electrochemical gas sensor that generally consists of an electrolytic chamber and three electrodes (Reference Electrode, Counter Electrode, and Working Electrode) , a resonator sensor that measures the degree to which a change in resonant frequency occurs according to the adsorption/desorption of gas by the sensing material formed on the resonator, a semiconductor nanowire-based FET gas sensor that depends on the resistance change when the sensing material is exposed to a target gas (MOSFET) is a gas sensor that uses a change in electrical signal according to the adsorption/desorption of gas using a sensing material. An optical type gas sensor for electrically measuring a change in light absorption according to a gas may include a non-dispersive infrared (NDIR) type gas sensor. The NDIR sensor uses an infrared bandpass filter existing between the infrared light source and the infrared sensor, and based on the electrical signal of the infrared sensor that decreases according to the decrease in the amount of light reaching the infrared sensor according to the degree of absorption of infrared light in the characteristic gas. The gas concentration can be measured.

According to an embodiment of the present disclosure, the optical type gas sensor may detect the type and concentration of a specific polluting gas and a malodorous gas. Certain polluting and malodorous gases may contain gases that are harmful to the human body and a characteristic foul odor that can be detected by breathing. Accordingly, the optical type gas sensor is a nitrogen compound, sulfur compound, lower fatty acids, carbonyl compound, esters, phenol cresols, alcohols, hydrocarbons, polluting gas containing components included in chlorine compounds and odor gas It can detect the type and detect the concentration of the gas. Concentrations of the polluting gas and the odor gas measured through the optical gas sensor may be transmitted to the environment controller 1400 . The environment control unit 1400 may generate a signal for generating a notification requesting replacement of the biofilter unit when the concentration of at least one exceeds a preset threshold value based on the received pollutant gas and the type of pollutant gas. . The threshold value preset in the environment controller 1400 may be a value for a concentration that is input in advance based on one or more gas types. A signal for generating a notification requesting replacement of the biofilter unit may be transmitted to the external computer 1800 through the environment control unit 1400 . For example, the threshold value for the concentration of ammonia corresponding to the nitrogen compound may be set in advance by being input to the environment control unit 1400 as 5 ppm. In addition, the threshold value for the concentration of methyl mercaptan corresponding to the sulfur compound may be set in advance by inputting into the environment control unit 1400 as 0.01 ppm. When the gas detected by the optical gas sensor contains ammonia and the concentration of ammonia is 4.9 ppm, the environment controller 1400 may generate a signal for generating a notification requesting replacement of the biofilter unit. The generated signal is transmitted to the external computer 1800 through the environment control unit 1400 , and the external computer 1800 may generate a notification requesting replacement of the bio-filter unit. The notification may include audible and visual messages including an alarm sound and a message displayed on the screen.

The description of the above-described gas sensor is only an example, and the present disclosure is not limited thereto. The air volume sensor is used to measure the air volume of the fan 320 of the water filter 300 and the blower 1220 of the duct 1210 or measure the air volume of the air intake and exhausted to the air purification device 1000 . Accordingly, at least one air volume sensor may be installed in the air purification apparatus 1000 .

The environment monitoring unit 1300 according to an embodiment of the present disclosure may include at least one camera unit 1330 to visually monitor internal and external states of the air purification apparatus 1000 . In particular, at least one camera unit 1330 may be installed therein to maintain cleanliness inside the air purification apparatus 1000 . In addition, in order to visually monitor the plant state of the planting unit 100 , at least one camera unit 1330 may be installed in the air purification apparatus 1000 .

The environment monitoring unit 1300 according to an embodiment of the present disclosure may also include a communication unit 1320 to transmit the environmental data measured by the sensor unit 1310 and the camera unit 1330 to the environment control unit 1400 . can Accordingly, the environment control unit 1400 comprehensively determines and processes one or more environmental data received through the communication unit 1320 to create a vegetative environment of the air purification apparatus 1000 or reduce the concentration of external fine dust. Commands can be sent to multiple devices.

For example, in order to create a vegetation environment suitable for the plants of the planting unit 100 , data of the temperature and humidity sensor and the light quantity sensor of the sensor unit 1310 may be transmitted to the environment control unit 1400 . The environment control unit 1400 receives temperature, humidity, and light amount data through the communication unit 1320, respectively, and sets temperature and humidity and light amount data according to the vegetation environment of the planting unit 100 to the temperature and humidity and light amount data, respectively. can be compared.

Based on the temperature and humidity data according to an embodiment of the present disclosure, the environmental control unit 1400 includes a heat generating device and a cooling device, and the temperature control unit 1500 configured to increase or decrease the temperature inside and outside the air purification device 1000 . It is possible to generate a control signal that can control the The temperature controller 1500 may include at least one of a thin film heating element using carbon nanotubes (CNT) and an air heating type (PCT) heating element. In addition, based on the temperature and humidity data, to generate a control signal to control the operating speed of the fan 320 and the blower 1220 to adjust the temperature, and to adjust the temperature and humidity of the liquid injection unit 310 It is possible to generate a control signal to control the injection amount.

Based on the light amount data according to an embodiment of the present disclosure, the environment controller 1400 may generate a control signal capable of adjusting the amount of light provided to the biofilter unit, and may transmit the control signal to the light controller 1600 . have. The light controller 1600 may include a light transmission unit capable of transmitting the light received from the external light source of the air purification apparatus 1000 to the inside of the air purification apparatus 1000 . For example, the light transmitting unit may include a light tube capable of transmitting light from the outside of the air purification apparatus 1000 to the inside, but the present disclosure is not limited thereto. The external light source may include the sun as a natural light source or external lighting as an artificial light source. In addition, the light control unit 1600 includes a light control unit capable of adjusting the amount of light of the light transmission unit, and is transmitted to the inside of the air purification apparatus 1000 based on the control signal of the environment control unit 1400 through the light control unit. It may be configured to control the amount of light. For example, the light control unit may control the amount of light transmitted from the light transmission unit by adjusting an area in which the light transmitting unit in the form of a light tube is exposed to an external light source. In addition, the light control unit 1600 may include a lighting unit capable of supplying light to the inside of the biofilter unit based on a control signal of the environment control unit 1400 as an internal light source as well as an external light source. The lighting unit includes at least one or more LED lighting devices for plant cultivation, or one or more light source devices capable of providing light to the plants of the vegetation unit 100, in the form of bars and plates or one or more bulbs. may be configured, but the present disclosure is not limited thereto.

Environmental data on fine particles outside and inside the air purification apparatus 1000 according to an embodiment of the present disclosure are measured by the fine particle sensor and the air component measurement sensor of the sensor unit 1310, and based on the environmental data Control signals for controlling the fan 320 and the blower 1220 and the liquid ejection unit 310 are generated in the environment control unit 1400 . Accordingly, the air volume sensor of the sensor unit 1310 measures air volume data according to the operation of the fan 320 and the blower 1220 , and transmits the air volume data to the environment controller 1400 through the communication unit 1320 . For more detailed description, for example, when the concentration of external fine particles in the air purification device is high, the environmental control unit 1400 may need to increase the operating speeds of the fan 320 and the blower 1220 to provide more purified air. have. Accordingly, data on high-concentration fine particles measured by the fine particle sensor and the air component measurement sensor are transmitted to the environment control unit 1400 through the communication unit 1320, and the environment control unit 1400 is measured by the air volume sensor A control signal may be generated to increase the operating speed of the fan 320 and the blower 1220 based on the data on the current air volume. In addition, even if a high concentration of external fine particles passes through the bio filter of the planting unit 100 , it may pass through the water filter 300 while maintaining a higher concentration of fine particles than before. Accordingly, data on the fine particles measured by the fine particle sensor and the air component measurement sensor inside the air control device 1000 are transmitted to the environment control unit 1400 through the communication unit 1320, and the liquid injection unit 310 It is possible to generate a control signal to increase the injection amount of The air purification apparatus 1000 may include a nutrient solution supply unit 1700 to additionally supply a nutrient solution to the liquid contained in the water tank 350 . Accordingly, the nutrient solution supply unit 1700 may be controlled by the environment control unit 1400 to adjust the concentration of the nutrient solution supplied to the water tank 350 . In this case, the environment control unit 1400 is based on the pre-input data on the plants of the vegetation unit 100 and the time that the liquid including the nutrient solution is sprayed through the liquid spray unit 310 of the nutrient solution supply unit 1700 . The time for supplying the nutrient solution to the water tank 350 may be calculated. In addition, the environment control unit 1400 determines that the time the liquid in the water tank 350 is supplied to the plants through the liquid injection unit 310 is set based on the time when the nutrient solution in the nutrient solution supply unit 1700 is supplied to the water tank 350 . can

Environmental data measured by the sensor unit 1310 and the camera unit 1330 of the environment monitoring unit 1300 according to an embodiment of the present disclosure may be transmitted to the external computer 1800 through the communication unit 1320. . Accordingly, environment data may be recorded and stored through the external computer 1800 .

Descriptions of the presented embodiments are provided to enable those of ordinary skill in the art to use or practice the present disclosure. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the present disclosure. Thus, the present disclosure is not intended to be limited to the embodiments presented herein, but is to be construed in the widest scope consistent with the principles and novel features presented herein.

Claims (15)

An air purifier comprising:
a bio filter unit comprising at least two bio filter units including a first bio filter unit exposed to the outside for purifying air and a second bio filter unit positioned inside the air purification device;
an outer frame having a space accommodating the bio-filter unit therein and supporting the bio-filter unit;
an environment monitoring unit including a sensor unit to monitor an internal and external environment of the air purification device; and
an environment control unit configured to control the air purification device based on the environmental data of the environment monitoring unit to maintain the vegetation environment of the biofilter unit;
including,
Each of the bio-filter parts composed of the two or more,
A planting unit comprising at least one of a hydroponic cultivation bag comprising at least one hole having a size through which the roots of plants for hydroponic cultivation can pass, or a vegetation medium for air purification and plant cultivation;
a planting frame capable of supporting the planting unit; and
a water filter that supplies moisture to the plants and purifies the air;
including, and
The planting unit of the first bio-filter part is a first planting unit including a first plant for aesthetics,
The planting unit of the second bio-filter unit is a second planting unit including a second plant for air purification,
The planting frame of the first bio-filter unit is detachably coupled to a glass blocking film including at least one air hole,
The sensor unit includes a fine particle sensor capable of measuring the concentration of fine particles inside and outside the air purification device,
The water filter includes a water tank capable of storing the liquid drained from the bio-filter unit,
the water bath comprises an ultrasonic transducer that oscillates ultrasonically to split the liquid into a size that can float in the air to further remove fine particles in the air;
The vibration speed of the ultrasonic transducer is controlled by the environment control unit,
air purifier.
The method of claim 1,
The water filter is
one or more liquid ejection units controlled based on a control signal of the environmental control unit to further purify the air purified by the bio-filter into a liquid;
a fan for moving the air whose driving speed is controlled based on a control signal from the environment controller;
a water filter frame in which the liquid jet unit and the fan are accommodated and having a space through which air can move; and
a water pipe connected from the water tank to the liquid spraying unit to reuse the liquid stored in the water tank to the plants;
further comprising,
air purifier.
3. The method of claim 2,
The water tank is
a filter for purifying the liquid stored therein; and
a pump for delivering the liquid to the conduit;
further comprising,
air purifier.
4. The method of claim 3,
The liquid is
containing water, a nutrient solution or a mixture, and
The nutrient solution is
essential components including macro-elements and trace elements essential for the survival of the plant; and
Fertilizer components that can help the growth of the plant;
containing,
air purifier.
4. The method of claim 3,
The filter is
Physical filter made of porous material; and
biofilter composed of algae;
consisting of at least one of
air filter
The method of claim 1,
The outer frame is
a duct for supplying purified air to the supply target space; and
a blower for moving the purified air to the space to be supplied through the duct and controlling an operating speed based on a control signal from the environment control unit;
containing,
air purifier.
The method of claim 1,
The environmental monitoring unit,
a communication unit for transmitting the environmental data measured by the sensor unit to at least one of the environment control unit or an external computer; or
a camera unit for visually monitoring the state of the bio-filter unit;
further comprising at least one of
air purifier.
8. The method of claim 7,
The sensor unit is
a temperature and humidity sensor capable of monitoring the temperature and humidity of the bio-filter unit;
a light quantity sensor for measuring the light quantity of the bio-filter unit;
an air component measuring sensor capable of measuring an air component inside and outside the air purification device; or
an air volume sensor capable of measuring an air volume of at least one of intake and exhaust air of the air purification device;
further comprising at least one of
air purifier.
The method of claim 1,
a temperature control unit configured to control a temperature of the air purification device based on a control signal of the environment control unit;
further comprising,
air purifier.
The method of claim 1,
a light control unit capable of adjusting the amount of light provided to the bio-filter unit based on a control signal of the environment control unit;
further comprising,
air purifier.
11. The method of claim 10,
The light control unit,
a light transmitting unit capable of transmitting external light of the air purification device to the inside of the air purification device; and
a light adjusting unit for adjusting the amount of light of the light transmitting unit based on a control signal of the environment controller;
containing,
air purifier.
11. The method of claim 10,
The light control unit,
an illumination unit capable of supplying light to the inside of the bio-filter unit based on a control signal of the environment control unit;
containing,
air purifier.
The method of claim 1,
a nutrient solution supply unit capable of supplying a nutrient solution to the bio-filter unit based on a control signal from the environment control unit;
further comprising,
air purifier.
9. The method of claim 8,
The air component measurement sensor,
Including an optical type gas sensor for measuring the component of the gas by sensing a different amount of infrared absorption according to the component of the gas using infrared rays,
air purifier.
The method of claim 1,
a HEPA filter unit for purifying the air passing through the air purifier at least once more;
further comprising,
air purifier.

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