KR102280108B1 - Automatic control air supply and exhaust system - Google Patents

Abstract

The present invention relates to an apparatus for controlling a plurality of chambers, respectively, and supplying and exhausting air. More particularly, the present invention relates to an automatic air supply and exhaust control apparatus, which comprises: a supply pipe formed in an inner space of an enclosure, equipped with a first blower, and supplied with outdoor air; an exhaust pipe formed in the inner space of the enclosure and equipped with a second blower, and through which indoor air is discharged; a heat exchanger formed at the intersection of the supply pipe and the discharge pipe; a dehumidifier formed in the supply pipe and installed at the rear end of the heat exchanger; a heating and cooling device formed in the supply pipe and installed at the rear end of the heat exchanger; a filter formed in the supply pipe and installed in front of the heat exchanger; and a sterilizer installed in the front or rear end of the heat exchanger and formed in the supply pipe.

Description

Automatic control air supply and exhaust system

The present invention relates to an automatically controlled air supply/exhaust device for controlling a plurality of rooms, respectively, and for introducing or discharging air into a room.

Patent Document 001 discloses a local air conditioner system comprising at least one indoor unit and an outdoor unit; a remote management system for controlling the local air conditioner system; In the multi-air conditioner integrated management system comprising a network connecting the local air conditioner system and the remote management system, the remote management system reports and receives a program version in use from the local air conditioner system, When the program of the air conditioner system is older than the program of the remote management system, the final version of the program is transmitted to the local air conditioner system, and the local controller connects to the remote management system and reports the version of the program currently in use. a first step; a second step of determining, by the remote management system, whether a program update of the local controller is necessary based on the version information of the program being used in the remote management system; a third step of downloading the final version of the program from the remote management system when it is determined that the program update of the local controller is necessary; After the download of the final version of the program is completed, the connection is terminated, the program is restarted, and a fourth step of operating the local air conditioner system is presented.

Patent Document 002 relates to an indoor air conditioning integrated control system that automatically controls an air conditioner according to various air conditions measured by a sensor to control indoor air in an optimal state, comprising: a sensor unit for measuring indoor air conditions; A control unit that is interlocked with the sensor unit, compares the measured air state with a preset setting range, and transmits a control signal when out of a predetermined range, and operates to reach a preset air condition setting range according to the control signal in conjunction with the control unit Accordingly, a technology including one or more air conditioners for conditioning indoor air is proposed.

Patent Document 003 discloses a plurality of air conditioners that perform indoor air conditioning, and the plurality of air conditioners and the plurality of air conditioners are connected through a network to enable integrated control of each air conditioner through an application program, and update the application program is possible. and a central controller having a slot into which an external memory card can be easily mounted, wherein the central controller is configured to copy data stored in an external memory card mounted in the slot to an internal memory, RAM, with one operation. a first step of separately providing an update button and storing update data in an external memory card to update an application program of a central controller for integrated control of a plurality of air conditioners; a second step of selecting an update button for requesting an update after the external memory card is installed in the slot of the central controller; A technology including a third step of automatically updating data stored in the memory card is copied to an internal memory in RAM (RAM) according to the selection of the update button is proposed.

Patent Document 004 discloses a multi-type air conditioning system, comprising: a cooling unit having at least one compressor, an evaporator, a blowing fan, and an inlet duct integrally, and a main controller to control the cooling operation in an integrated and centralized manner; It consists of a plurality of ducts individually connected between each room equipped with the cooling unit and the room controller, and a damper control member for controlling the amount of cold air by sensing the cooling load generated in the room is located inside the duct. It is equipped, and this damper control member presents a technology to signally connect with the main controller.

US 10-2007-0072262 A (July 04, 2007) US 10-2019-0106608 A (September 18, 2019) US 10-2005-0034416 A (April 14, 2005) US Special 2002-0073861 A (September 28, 2002)

An object of the present invention is to control each of a plurality of rooms, and to inject or discharge air into a room.

In order to solve the problems of the prior inventions, the present invention is formed in the inner space of the housing 100, the first blower 111 is mounted, the supply pipe 110 through which outdoor air is supplied; It is formed in the inner space of the housing 100, the second blower 121 is mounted, the discharge pipe 120 through which the indoor air is discharged; The supply pipe line 110 and the discharge pipe line 120 intersect, the heat exchanger 130 formed at the intersection position; a dehumidifying device 140 formed in the supply pipe 110 and installed at the rear end of the heat exchanger 130; a heating and cooling device 150 formed in the supply pipe 110 and installed at the rear end of the heat exchanger 130; a filter 160 formed in the supply pipe 110 and installed in front of the heat exchanger 130; It is formed in the supply pipe 110, the heat exchanger 130, a sterilizer 170 installed at the front or rear end; consists of a configuration including.

The present invention relates to an automatically controlled supply/exhaust device, and the previously presented supply pipe 110; discharge pipe 120; heat exchanger 130; dehumidifier 140; air conditioning unit 150 ), a filter 160; a sterilizer 170; branched from the supply pipe 110 and the discharge pipe 120 in the invention consisting of a duct 200 that communicates individually with each room; a diffuser 240 mounted in each of the rooms and coupled to the duct 200; An individual controller 250 mounted in each room and controlling the opening and closing of the diffuser 240; is added.

The present invention relates to an automatically controlled supply/exhaust device, and the previously presented supply pipe 110; discharge pipe 120; heat exchanger 130; dehumidifier 140; air conditioning unit 150 );, filter 160; and sterilization device 170; temperature and humidity mounted on the supply pipe 110, the discharge pipe 120, the heating device, the heating and cooling device 150, and the individual controller 250 in the present invention. Sensor 300; Gas state detection sensor 400 mounted on the individual controller 250 and the supply pipe 110 and the exhaust pipe 120; The temperature and humidity sensor 300 and the gas state detection sensor 400 ) and control the operation of the first blower 111 , the second blower 121 , the dehumidifier 140 , the air conditioner 150 , the filter 160 , and the sterilizer 170 . A controller 500; is added.

The present invention relates to an automatically controlled supply/exhaust device, and the previously presented supply pipe 110; discharge pipe 120; heat exchanger 130; dehumidifier 140; air conditioning unit 150 ); a filter 160; a sterilization device 170; a first signal generated from the temperature and humidity sensor 300; a second signal generated from the gas state detection sensor 400; and the a third signal generated by the operation of the first blower 111 , the second blower 121 , the dehumidifying device 140 , and the air conditioning device 150 ; a fourth signal generated by the operation of the indoor temperature control device 600 in communication with the supply pipe 110; A fifth signal generated by the operation of the individual controller 250 is added.

The present invention relates to an automatically controlled supply/exhaust device, and the previously presented supply pipe 110; discharge pipe 120; heat exchanger 130; dehumidifier 140; air conditioning unit 150 );, a filter 160; and a sterilizing device 170; a first storage device 510 built in the main controller 500 and storing data of the first to fifth signals; an analysis device (520) built in the main controller (500) and analyzing a driving pattern from the data of the first storage device (510); a second storage device (530) built into the main controller (500) and storing the analysis result of the analysis device (520); A program generating device 540 that is built in the main controller 500 and generates an automatic operation program of the controller from the data of the second storage device 530; is added.

The present invention relates to an automatically controlled supply/exhaust device, and the previously presented supply pipe 110; discharge pipe 120; heat exchanger 130; dehumidifier 140; air conditioning unit 150 );, a filter 160; and a sterilization device 170; a wired/wireless device 700 that interworks with the main controller 500 and transmits and receives operation signals by wire and/or wirelessly; It is interlocked with the wired/wireless device 700, and a portable terminal 800 having a built-in program for remotely controlling the operation; is added.

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The present invention can control each of the threads as the duct and diffuser are formed with a plurality of threads.

The present invention can supply air to a plurality of chambers at the same time as the distributor is formed.

In the present invention, heat exchange can be achieved by crossing indoor air and outdoor air.

In the present invention, the temperature can be controlled as the air flowing into the room passes through the heat exchanger.

According to the present invention, a dehumidifier is formed in a heat exchanger to control the humidity of air flowing into a room in summer.

The present invention can sterilize bacteria in the air flowing into the room by irradiating ultraviolet rays from the LED to the photocatalytic filter to generate a photocatalytic reaction.

The present invention can generate a driving pattern by storing and analyzing the data of each room.

1 is a cross-sectional view of an automatically controlled supply and exhaust device of the present invention.
Figure 2 is a plan sectional view showing the air supply and exhaust device of each room of the present invention.
3 is a cross-sectional view of the air supply and exhaust device of each room shown in FIG.
Figure 4 is an exemplary view of the supply and exhaust device of the present invention.
FIG. 5 is a front view of the air conditioning system and the dehumidifier shown in FIG. 4 ;
6 is a cross-sectional view of the sterilization apparatus of the present invention.
7 is a cross-sectional view of a supply and exhaust device utilizing a portable terminal of the present invention.
8 is a cross-sectional view of a supply/exhaust device for each room according to another embodiment of the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described in detail in order to explain in detail enough that a person skilled in the art to which the present invention pertains can easily carry out the present invention.

The numbers cited in the examples below are not limited only to the objects of reference, and may be applied to all examples. Objects exhibiting the same purpose and effect as the configuration presented in the examples correspond to equivalent replacement objects. The higher-level concept presented in the examples includes sub-concept objects that are not described.

(Embodiment 1-1) In the present invention, in the automatically controlled supply and exhaust device, the supply pipe 110 is formed in the inner space of the housing 100, the first blower 111 is mounted, and outdoor air is supplied. ; It is formed in the inner space of the housing 100, the second blower 121 is mounted, the discharge pipe 120 through which the indoor air is discharged; The supply pipe line 110 and the discharge pipe line 120 intersect, the heat exchanger 130 formed at the intersection position; a dehumidifying device 140 formed in the supply pipe 110 and installed at the rear end of the heat exchanger 130; a heating and cooling device 150 formed in the supply pipe 110 and installed at the rear end of the heat exchanger 130; a filter 160 formed in the supply pipe 110 and installed in front of the heat exchanger 130; It is formed in the supply pipe 110, the heat exchanger 130, a sterilizing device 170 installed at the front or rear end; includes.

The present invention relates to an automatically controlled supply and exhaust device. Specifically, it is possible to operate the supply/exhaust device by sensing the indoor temperature and harmful gas. In such a supply/exhaust device, a housing 100 in which a plurality of pipelines are formed is formed, and a heat exchanger 130 in which indoor air and outdoor air are circulated is formed in the housing 100 . In addition, a supply pipe 110 and an exhaust pipe 120 are formed on both sides of the heat exchanger 130 , respectively. In this way, the supply and exhaust device is connected to a plurality of rooms, and after sensing the temperature and humidity of each room and harmful gas, the supply and exhaust devices are operated respectively, thereby preventing the loss of energy in heating and cooling in the room. And the first and second blowers are mounted on the supply pipe 110 and the discharge pipe 120 formed in the pit. The first and second blowers may each be formed as separate blowing fans, and as another embodiment, each fan may be mounted on both sides of one motor to drive the two blowers at the same time. In addition, the first blower 111 and the second blower 121 may be formed of any one selected from a centrifugal type and an axial flow type.

In addition, the filter 160 may filter the air supplied through the supply pipe 110 as it is installed in front of the heat exchanger 130 . The filter 160 includes a dust collecting filter for filtering foreign substances, a deodorizing filter for filtering bad odors of air passing through the dust collecting filter, and a pre-filter for removing fine dust from the air passing through the deodorizing filter.

Accordingly, the air supply/exhaust device detects indoor air and outdoor air and drives the enclosure 100 , thereby preventing the loss of indoor heating and cooling energy.

(Embodiment 1-2) The air supply/exhaust device of the present invention according to Embodiment 1-1, wherein the air conditioner 150 is formed in the supply pipe 110 and is formed of a radiator.

(Embodiment 1-3) The air supply/exhaust device of the present invention according to Embodiment 1-2, wherein the air conditioning unit 150 includes a heat medium flow pipe 151 communicating in a zigzag manner.

(Embodiment 1-4) The supply/exhaust device of the present invention according to Embodiment 1-3, wherein the heat medium flow pipe 151 is formed of a plurality of layers.
The present invention relates to a cooling/heating device 150 , and specifically, the cooling/heating device 150 is formed in the supply pipe 110 of the housing 100 to provide a cooling/heating function to the supply/exhaust device. A cooling device is driven to supply cooled air to the supply pipe 110 in summer, and a heating device is driven to supply heated air to the supply pipe 110 in winter. The air conditioning unit 150 controls the temperature according to the indoor set temperature, and is located over the entire cross-sectional area of the supply pipe 110 . In addition, the heating and cooling device 150 is formed in the shape of a radiator, and a dehumidifying device to be described later is attached thereto. The air conditioner 150 communicates in a zigzag manner, and a heat medium flow tube 151 formed of a plurality of layers is formed. In the heat medium flow pipe 151 , Freon gas, water, etc. flow into it, and the temperature is controlled, and the temperature of the room is determined by the air passing through the heat medium flow pipe 151 . In addition, the heat medium flow tube 151 may be a stainless tube or a copper tube having excellent heat transfer, and is formed of a material equivalent to this, and is formed to have corrosion resistance.

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(Embodiment 1-5) The air supply/exhaust device of the present invention according to Embodiment 1-1, wherein the dehumidifier 140 is attached to the air conditioning system;

(Example 1-6) The air supply/exhaust device of the present invention according to Example 1-5, is formed at the lower end of the air conditioner to which the dehumidifier 140 is attached, and a storage body 141 in which moisture is collected; include

(Embodiment 1-7) The supply/exhaust device of the present invention according to Embodiment 1-6, is formed in the storage body 141, and includes a discharge pump 142 for discharging the moisture to the outside.

The present invention relates to a dehumidifying device, and specifically, the dehumidifying device is attached to a heating and cooling device to absorb moisture flowing into a room. The outdoor air in summer is hot and humid, and while the hot and humid air enters the room through the duct 200, moisture contained in the air is collected by the dehumidifier. Such a dehumidifier is a porous material artificially synthesized as a "metal-organic framework", which is abbreviated as "MOF". In addition, the dehumidifier is attached to the air conditioner and adsorbs only moisture when it flows into the room, and the adsorbed moisture is collected by the storage body 141 formed at the bottom of the air conditioner. The moisture collected in the storage body 141 is discharged to the outside by the discharge pump 142 formed in the storage body 141 , and a portion is evaporated by the temperature of the air conditioner.

(Embodiment 1-8) In Embodiment 1-1, the air supply and exhaust device of the present invention includes: an LED 171 for irradiating ultraviolet rays; and a photocatalytic filter 172 disposed adjacent to the LED 171 .

(Embodiment 1-9) The supply/exhaust device of the present invention according to Embodiment 1-8, wherein the LED 171 is formed in an A-type and/or C-type; includes.

(Embodiment 1-10) The air supply/exhaust device of the present invention according to Embodiments 1-9, the photocatalytic filter 172 includes a body 173 having a plurality of air flow holes; and a reaction layer 174 coated on the body 173 surface.

(Example 1-11) The air supply/exhaust device of the present invention according to Example 1-10, wherein the material of the reaction layer 174 is titanium dioxide, and the material of the body 173 is ceramic.

(Example 1-12) The supply/exhaust device of the present invention according to Example 1-11, wherein the titanium dioxide is formed of blue titanium dioxide; includes.

The present invention relates to a sterilizing device 170, and specifically, the sterilizing device 170 is formed of a photocatalytic filter 172 that performs a photocatalytic reaction by ultraviolet rays irradiated from the LED 171. The sterilizer 170 is formed of an LED 171 irradiating A-type and C-type ultraviolet rays and a photocatalytic filter 172 in which a photocatalytic reaction occurs by the LED 171 . The LEDs 171 are formed of UV LEDs 171 , and as a plurality are formed, UV rays are irradiated with the photocatalytic filter 172 . The wavelength of the ultraviolet ray irradiated from the LED 171 includes a band of 200 to 390 nm, and in particular, if the peak wavelength is between 260 and 370 nm, the photocatalytic reaction efficiency can be further increased. And the photocatalytic filter 172 is formed of a body 173 in which a plurality of air flow holes are formed and a reaction layer 174 coated on the surface of the body 173 . At this time, the material of the body 173 is formed of ceramic, and the air flowing into the room through the body 173 sterilizes bacteria, mold, bacteria, etc. by the reaction layer 174 coated on the surface of the body 173 . . At this time, the reaction layer 174 is formed of titanium dioxide (TiO2) and blue titanium dioxide (Blue-TiO2), and the plurality of LEDs 171 sterilize bacteria and the like.

(Embodiment 2-1) The present invention relates to an automatically controlled supply/exhaust device, and in Embodiment 1-1, it is branched from the supply pipe 110 and the discharge pipe 120, and is installed in each room. individually communicating ducts 200; a diffuser 240 mounted in each of the rooms and coupled to the duct 200; It is mounted in each room, and an individual controller 250 for controlling the opening and closing of the diffuser 240; includes.

(Embodiment 2-2) In the supply and exhaust device of the present invention, in Embodiment 2-1, the duct 200 is connected to the supply pipe 110, and includes an input duct 210 for introducing outdoor air; It is connected to the discharge pipe 120, the discharge duct 220 for discharging indoor air; includes.

(Embodiment 2-3) In Embodiment 2-2, the air supply/exhaust device of the present invention is formed in the housing 100 and includes a distributor 230 for connecting a plurality of the ducts 200 .

(Embodiment 2-4) The air supply/exhaust device of the present invention according to Embodiment 2-3, wherein the diffuser 240 includes a first diffuser 241 through which outdoor air flows; and is spaced apart from the first diffuser 241 and a second diffuser 242 through which the indoor air is discharged.

The present invention relates to an automatically controlled supply and exhaust device. Specifically, the duct 200 through which outdoor air is introduced into the room and the indoor air is discharged to the outside, the diffuser 240 formed in the room, and an individual controller 250 for controlling the opening and closing of the diffuser 240 are formed. The duct 200 is formed in plurality to supply or discharge air for each chamber, and is connected to the housing 100 . The duct 200 is connected to the supply pipe 110 to form an input duct 210 for introducing outdoor air and an exhaust duct 220 for discharging indoor air by being connected to the exhaust pipe 120 . At this time. A first diffuser 241 and a second diffuser 242 are respectively formed at the ends of the input duct 210 and the exhaust duct 220, and the diffuser 240 has a valve and a cover, so that the individual controller 250 is is controlled by And the plurality of ducts 200 supply air to each chamber by the distributor 230 attached to the housing 100 or discharge to the outside. As described above, the individual controller 250 for controlling the diffuser 240 can be directly controlled by the user by the temperature control device 600 formed on the wall of the room. At this time, the individual controller 250 may automatically operate the supply/exhaust device by sensing the temperature, humidity, and harmful gas.

Accordingly, the air supply/exhaust device has a characteristic that the indoor air and the outdoor air are exchanged with each other by the individual controllers 250 formed in each room, and are transmitted to the housing 100 through the duct 200 .

(Embodiment 2-5) In the supply and exhaust device of the present invention in Embodiment 2-1, the distributor 230 includes an entry distributor 231 through which entry air is distributed; and a discharge distributor 232 in which exhaust air is integrally concentrated.

(Embodiment 2-6) The air supply/exhaust device of the present invention according to Embodiment 2-5, is formed inside the distributor 230, and includes a guide plate for guiding the flow of air.

(Embodiment 2-7) The supply/exhaust device of the present invention according to Embodiment 2-6, includes a clamp connecting the distributor 230 and the duct 200.

The present invention relates to a distributor 230, and specifically, the distributor 230 is formed on the interior side of the housing 100 to distribute air to each room or to concentrate the air in each room. The distributor 230 is formed by injection molding containing copper powder or coating a polymer thin film containing copper powder indoors and outdoors in order to suppress the occurrence of bacteria. At this time, in addition to the distributor 230, the housing 100 and the duct 200 are also formed by injection molding with copper powder or coating a polymer thin film containing copper powder. The distributor 230 is coupled to the duct 200 delivered from each room, and the duct 200 is formed with an entry pipe through which air enters the room and a discharge pipe 120 through which air is discharged to the outside. And the distributor 230 is coupled to a plurality of ducts 200 at one end and a side, but coupled to the supply pipe 110 and the discharge pipe 120 of the housing 100 at the other end. The distributor 230 has flanges formed at both ends, and faces the flanges formed on the duct 200 and the housing 100 . As described above, the distributor 230 connecting the housing 100 and the duct 200 includes an entry distributor 231 through which outdoor air is distributed and an exhaust distributor 232 through which indoor air is discharged. In the distributor 230 , outdoor air is uniformly distributed or indoor air delivered from each room is concentrated and delivered to the housing 100 . And the distributor 230 is formed with a plurality of guide plates therein, the guide plate is formed in an oblique line to supply or discharge uniform air to each duct 200 or to be in contact with the end of the distributor 230 is not formed. . This is to control the amount of air supplied to each room, and if the damper is shut off, air is induced to the other room.

Therefore, the distributor 230 of the present invention is formed between the housing 100 and the duct 200 of each chamber to distribute the air to a plurality of chambers or to concentrate the air discharged from the plurality of chambers to deliver it to the housing 100 . have characteristics.

(Embodiment 2-8) The supply/exhaust device of the present invention according to Embodiment 2-1, is formed in the duct 200, and includes a heat insulating part 260 for preventing heat loss; and a blower 270 for supplying wind indoors and outdoors.

(Example 2-9) In Example 2-8, the air supply/exhaust device of the present invention comprises: a heat insulator 261 formed in the heat insulating part 260 and attached to the inner circumferential surface of the duct 200; It is formed in the duct 200, the control device 262 for controlling the temperature of the air; includes.

(Embodiment 2-10) The air supply/exhaust device of the present invention according to Embodiment 2-8, wherein the blower 270 includes a speed control device 271 for controlling the speed of the blowing fan.

(Example 2-11) The air supply/exhaust device of the present invention according to Example 2-1, wherein the duct 200 is formed to have a different diameter according to the distance of each room; includes.

The present invention relates to a duct 200, and specifically, the duct 200 extending into each chamber has an insulator 260 and a blower in order to prevent the intensity and heat loss of air lost according to the distance from the housing 100. (270) is formed. The heat insulating part 260 is supplied to the room as the heat insulating material 261 is attached to the inner circumferential surface of the duct 200 to prevent heat loss, and the control device 262 is formed at the position where the duct 200 is connected to the room. Regulates the temperature of the air. In addition, the blower 270 is formed as a blower fan, and is formed in plurality to smoothly induce air inflow and outflow into the room. In detail, the air supplied from the housing 100 is introduced into the room by the blower, but the air cannot be guided through the plurality of ducts 200 or the same wind can be supplied to the ducts 200 that are far away. In order to overcome this, the duct 200 may have a different diameter of the duct 200 according to the distance of each room in order to control the amount of air, and a plurality of blowing fans may be installed in the duct 200 . And the blower 270 is provided with a speed control device 271 for controlling the speed of the blowing fan, respectively, and the speed control device 271 controls a motor that rotates the blowing fan.

(Embodiment 2-12) In the supply and exhaust device of the present invention, in Embodiment 2-1, the duct 200 is formed in a double, and a through hole formed in an oblique line in the duct 200 formed therein; include

(Embodiment 2-13) The air supply/exhaust device of the present invention according to Embodiment 2-12, wherein the through-hole passes through the duct 200 formed on the inside and the outside to guide air. .

The duct 200 is formed of a double duct 200 formed inside and outside, and wind is supplied to the space between the double ducts 200 to more effectively provide air flowing into the room. At this time, the inner duct 200 may have a plurality of through-holes formed in an oblique line to supply wind in a direction in which air travels. And as the duct 200 is formed in a double layer, it is possible to improve the thermal insulation performance of the duct 200 .

(Example 3-1) The present invention relates to an automatically controlled supply/exhaust device, and in Example 2-1, the supply pipe 110, the discharge pipe 120, the heating device, and the heating and cooling device 150 , a temperature and humidity sensor 300 interlocked with the individual controller 250 ; a gas state detection sensor 400 interlocking with the individual controller 250 and the supply pipe 110 and the exhaust pipe 120; Detects the signals of the temperature and humidity sensor 300 and the gas state detection sensor 400, and the first blower 111, the second blower 121, the dehumidifier, the air conditioning unit 150, the filter 160, the sterilization and a main controller 500 for controlling the operation of the device 170 .

(Embodiment 3-2) The supply/exhaust device of the present invention according to Embodiment 3-1, wherein the gaseous state detection sensor 400 detects harmful gas introduced or discharged into the room; includes.

The present invention relates to an automatically controlled supply and exhaust device. Specifically, the temperature and humidity and the harmful gas are sensed in the housing 100 and the individual controller 250 of each room to control the operation of the supply and exhaust device. This supply/exhaust device includes a temperature and humidity sensor 300, a gas state detection sensor 400, and a main controller 500, and the temperature and humidity sensor 300 includes a supply pipe 110, a discharge pipe 120, a heating device, and heating/cooling. The device 150 is interlocked with the individual controller 250 . And the gas state detection sensor 400 detects the harmful gas contained in the air flowing into the room or discharged to the outside to prevent the harmful gas from flowing into the room. At this time, when the heat exchange is performed in the heat exchanger 130 , the harmful gas may be introduced into the room, so that the harmful gas is sensed in the supply pipe 110 and the discharge pipe 120 . In addition, when the individual controller 250 of each room detects harmful gas, the main controller 500 can automatically operate the supply/exhaust device.

(Embodiment 4-1) The present invention relates to an automatically controlled supply and exhaust device. In Embodiment 3-1, the first signal generated by the temperature and humidity sensor 300; and the gas state detection sensor 400 ), a third signal generated by the operation of the first blower 111 , the second blower 121 , the dehumidifying device, and the air conditioning device 150 ; a fourth signal generated by the operation of the indoor temperature control device 600 in communication with the supply pipe 110; and a fifth signal generated by the operation of the individual controller 250 .

(Example 5-1) The present invention relates to an automatically controlled supply/exhaust device, and in Example 4-1, it is built into the main controller 500 and receives the data of the first to fifth signals. a first storage device 510 for storing; an analysis device (520) built in the main controller (500) and analyzing a driving pattern from the data of the first storage device (510); a second storage device (530) built into the main controller (500) and storing the analysis result of the analysis device (520); and a program generating device 540 built in the main controller 500 and generating an automatic operation program of the main controller 500 from the data of the second storage device 530 .

(Embodiment 5-2) The air supply/exhaust device of the present invention according to Embodiment 5-1, wherein the program generating device 540 expresses an operation pattern on an externally formed display device; includes.

The present invention relates to a main controller (500). Specifically, the main controller 500 formed in the housing 100 receives and stores the first to fifth signals, and generates an automatic operation program by analyzing the stored data. The main controller 500 is formed in the housing 100 , the temperature and humidity sensor 300 , the gas state sensor 400 , the first blower 111 , the second blower 121 , the dehumidifier, and the air conditioning unit 150 . ), the temperature controller 600 , and data transmitted from the individual controller 250 may be received. The received first to fifth signals are stored in the first storage device 510 , and the first storage device 510 is formed of big data. Accordingly, a plurality of signals inside each chamber and the housing 100 are stored, and the stored data is analyzed by the analysis device 520 for a driving pattern. The analysis device 520 analyzes a driving pattern of various situations, such as time, date, temperature, and humidity. In detail, the operation pattern of the air supply/exhaust device according to the time, date, temperature, and humidity of each room is analyzed so that the user can live in a comfortable space. The analysis result of the analysis device 520 is stored in the second storage device 530 to prevent overload of the first storage device 510 , and the data stored in the second storage device 530 is stored in the main controller 500 . It is used to improve the air quality of each room. The data stored in the second storage device 530 generates an automatic operation program by the program generating device 540 . The automatic operation program generated by the program generating device 540 determines the user entering each room or circulates air in each room before the user enters the room so that the user enters each room in a comfortable environment. In addition, when the user leaves the room, the amount of driving of the supply/exhaust device may be increased according to the data of the second storage device 530 to solve the inconvenience to the user. In this way, the driving pattern generated by the program generating device 540 may be expressed on an externally formed display device.

Accordingly, the main controller 500 receives the first to fifth signals, stores data, and generates the program generating device 540 by analyzing the stored data.

(Embodiment 6-1) The present invention relates to an automatically controlled supply/exhaust device, and in Embodiment 5-1, the main controller 500 is interlocked and transmits and receives operation signals by wire and/or wirelessly. Wired/wireless device 700; It interworks with the wired/wireless device 700 and includes a portable terminal 800 having a built-in program for remotely controlling the operation.

The present invention relates to a main controller (500). Specifically, the main controller 500 may control the main controller 500 by interworking with a portable terminal 800 such as a mobile phone or a tablet PC. The main controller 500 includes a wired/wireless device 700 that transmits and receives operation signals to receive the first to fifth signals, and the wired device can communicate with the portable terminal 800 . At this time, the air quality of each room can be improved by controlling the main controller 500 by the portable terminal 800 , and the portable terminal 800 has an embedded application that remotely controls the operation of the main controller 500 . As a result, the air state of each room is expressed to control the main controller 500 . In addition, the portable terminal 800 may display a notification with a vibration or a ringtone so that the user can recognize the status of the supply/exhaust device at the same time.

100: housing 110: supply pipe
111: first blower 120: discharge pipe
121: second blower 130: heat exchanger
141: storage
142: discharge pump 150: heating and cooling device
151: heat medium flow tube 160: filter
170: sterilizer 171: LED
172: photocatalytic filter 173: body
174: reaction layer 200: duct
210: input duct 220: exhaust duct
230: distributor 231: entry distributor
232: exhaust distributor 240: diffuser
241: first diffuser 242: second diffuser
250: individual controller 260: insulation
261: insulation 262: regulator
270: blower 271: speed control device
300: temperature and humidity sensor 400: gas state detection sensor
500: main controller 510: first storage device
520: analysis device 530: second storage device
540: program generating device 600: temperature control device
700: wired and wireless device 800: portable terminal

Claims (6)

a supply pipe 110 formed in the inner space of the housing 100, to which the first blower 111 is mounted, and through which outdoor air is supplied;
It is formed in the inner space of the housing 100, the second blower 121 is mounted, the discharge pipe 120 through which the indoor air is discharged;
The supply pipe line 110 and the discharge pipe line 120 intersect, the heat exchanger 130 formed at the intersection position;
a dehumidifying device formed in the supply pipe 110 and installed at the rear end of the heat exchanger 130;
a heating and cooling device 150 formed in the supply pipe 110 and installed at the rear end of the heat exchanger 130;
a filter 160 formed in the supply pipe 110 and installed in front of the heat exchanger 130;
It is formed in the supply pipe 110, the heat exchanger 130, a sterilizing device 170 installed at the front or rear end;
The sterilizer 170 is formed in plurality, the LED 171 for irradiating ultraviolet rays;
and a photocatalytic filter 172 disposed adjacent to the LED 171;
The LED 171 is formed in A-type and C-type,
The photocatalytic filter 172 is formed of blue titanium dioxide, the body 173 having a plurality of air flow holes;
and a reaction layer 174 coated on the surface of the body 173;
a duct 200 that is branched from the supply pipe 110 and the discharge pipe 120 and communicates individually with each room;
a diffuser 240 mounted in each of the rooms and coupled to the duct 200;
an individual controller 250 mounted in each room and controlling the opening and closing of the diffuser 240;
a heat insulating part 260 formed in the duct 200 and preventing heat loss;
Including; a blower 270 for supplying wind indoors and outdoors;
The duct 200 is formed with a different diameter value according to the distance of each room, is formed in a double shape, is formed in an oblique line on the duct formed inside, and the wind penetrates between the ducts formed inside and outside to supply air. Including; through-hole to guide
The heat insulator 260 may include a heat insulator 261 attached to the inner circumferential surface of the duct 200;
It is formed in the duct 200, the control device 262 for controlling the temperature of the air; including;
The blower 270 is an automatic control supply and exhaust device including a;
delete The method according to claim 1,
The supply pipe 110, the discharge pipe 120, the heating device, the heating and cooling device 150, the temperature and humidity sensor 300 interlocked with the individual controller 250;
Gas state detection sensor 400 interlocked with the individual controller 250 and the supply pipe 110 and the exhaust pipe 120;
Detects the signals of the temperature and humidity sensor 300 and the gas state detection sensor 400, and the first blower 111, the second blower 121, the dehumidifier 140, the air conditioner 150, the filter 160 ), the main controller 500 for controlling the operation of the sterilizer 170; Automatic control supply and exhaust device comprising a.
4. The method according to claim 3,
A first signal generated by the temperature and humidity sensor 300;
a second signal generated by the gas state detection sensor 400;
a third signal generated by the operation of the first blower 111 , the second blower 121 , the dehumidifying device 140 , and the air conditioning device 150 ;
a fourth signal generated by the operation of the indoor temperature control device 600 in communication with the supply pipe 110;
A fifth signal generated by the operation of the individual controller 250; automatic control air supply and exhaust device comprising a.
5. The method according to claim 4,
a first storage device (510) built into the main controller (500) and storing data of the first to fifth signals;
an analysis device (520) built in the main controller (500) and analyzing a driving pattern from the data of the first storage device (510);
a second storage device (530) built into the main controller (500) and storing the analysis result of the analysis device (520);
The automatic control air supply and exhaust device including a; is built in the main controller (500), the program generating device (540) for generating an automatic operation program of the controller from the data of the second storage device (530).
6. The method of claim 5,
a wired/wireless device 700 that is interlocked with the main controller 500 and transmits/receives operation signals by wire and/or wirelessly;
The automatic control supply/exhaust device including a; interlocking with the wired/wireless device 700, a portable terminal 800 having a built-in program for remotely controlling the operation.

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