KR20200027599A - Heat recovery ventilators - Google Patents

Abstract

The present invention relates to a heat-recovering air-purifying system. An objective of the present invention is to recover cooling and heating energy discarded during indoor ventilation to reduce cooling and heating energy required for fresh outside air entering indoor space to have an energy reduction effect, prevent outdoor pollution by a filtering function of a filter unit when discharging indoor polluted air to outside space, and purify outside air entering indoor space to allow stable, sanitary, and pleasant ventilation. To achieve the objective, the heat-recovering air-purifying system exchanges heat between inside air which is indoor polluted air and outside air which is outdoor fresh air to recover heat discarded in ventilation to improve thermal efficiency, and comprises: a heat exchanger (10) having a heat exchange staying space (140) to exchange heat between inside air and outside air; an intake duct (20) forming an intake line on one side of the heat exchanger (10) to suck indoor polluted air to exchange heat; an air supply duct (30) forming an air supply line on the other side of the heat exchanger (10) by inducting outdoor fresh air to exchange heat; and a filter unit (40) formed on the intake line and the air supply line to filter inducted or supplied air to perform a purifying function to allow stable and sanitary use.

Description

Heat recovery air purification system {HEAT RECOVERY VENTILATORS}

The present invention relates to a heat recovery type air purification system, and more specifically, to reduce the cooling and heating energy required for fresh outside air entering the room by recovering the cooling and heating energy that is wasted during indoor ventilation. A heat recovery type air purification system that enables stable and sanitary and comfortable ventilation by purifying the outside air entering the room while preventing outdoor pollution by filtering the filter unit when the indoor air is released to the outside with the effect will be.

In general, as interest in quality in life increases, interest in indoor air quality that spends most of the day is also increasing, and the Ministry of Environment enacted indoor air quality management methods such as multi-use facilities to present indoor air quality standards. As a way to maintain air quality, it is mandatory to install ventilation equipment, so it is necessary to provide the necessary ventilation amount for multiple use facilities.

In addition, polluted air in a confined and cloudy room is the main culprit of our health, and people live 80% or more indoors, but in a highly sealed room to save energy, these indoors are air from the outside. It is difficult to circulate, and it appears that the pollution level is more than 3 times higher than that of outdoor air due to various dust, bacteria, harmful gases, odors, etc .. Is urgently required.

[Reference figure]

In addition, new buildings are airtight and can reduce heat loss by about 25-50%, but the natural ventilation rate is reduced.

Accordingly, these buildings need an economical and effective mechanical ventilation system for discharging indoor air pollutants and excess moisture in addition to supplying fresh air from the outside.

In response to this trend, air-conditioning technologies and facilities are being developed in an interlocking manner, and in the case of small single-family homes, various air conditioners have been released to meet the desire to increase indoor air quality.

In either case, the air conditioner is based on energy saving and requires high purification capacity and ease of maintenance.

In addition, in indoor ventilation and air purification, in the case of old buildings, asbestos is detected more than 5 times the reference value, and the bacterial contamination is high, especially in recent years, due to fine dust, heavy metal components contained in the fine dust are found, etc. And the need for purification emerges.

In addition, according to the indoor air quality survey by the Ministry of Environment (October 2, 2013), 17 places, 77 measured at 17.6%, exceeded the recommended standards such as formaldehyde, toluene, and styrene, which are the main causes of 'birdhouse syndrome' It was found that the indoor air pollution was serious, for example, the highest measured point exceeded 4 times the standard.

In particular, according to the survey of 2,576 out of 14,483 multi-use facilities nationwide in the survey on the air quality in the environment, the daycare center exceeded the maintenance standards at 172, 13% of 1,321 of the corresponding salinity test facilities. It was found that 15 out of 566 out of 15 exceeded the maintenance standards.

In particular, in the case of daycare centers, there are places where floating bacteria are measured up to 7 times, and it can be seen that it is urgent to improve air quality through ventilation.

Looking at the prior art for solving the above problems, the heat recovery ventilation system equipped with a counter-flow heat exchanger of Korean Patent No. 10-1459218 has an axial direction at the end of the front prismatic plate-shaped channel formed by connecting the squares in the transverse direction. In the inner extension line, a back-angled plate-shaped channel having the same shape and length is stacked in a layered manner up and down to form an integral counter-flow heat exchanger with a symmetrical structure, and also wraps the outermost side of the counter-flow heat exchanger. A plurality of blocking plates are integrally formed on the inner extension lines at both ends of the insulating material and the plastic case covered thereon, and the blocking plates are spaced above and below the indoor end of the front square plate type channel and above and below the outdoor end of the rear square plate type channel. The outdoor that flows along the lateral direction of the open space formed by the blocking treatment. Group indoor air to the indoor air supply, and the outlet is a structure that allows the outdoor exhaust, respectively.

In addition, the exhaust fan is installed on both sides to protrude from the outdoor end portion of the plastic case to the side portion of the extension line in the inner direction to force the outdoor exhaust of indoor air, and is installed in the center of the outdoor end of the plastic case. It is a structure for forcing indoor air supply of outdoor air by one air supply type motor fan.

Accordingly, a counter-flow heat exchanger composed of a plate-shaped panel formed of a plurality of squares formed by a single body extending in the lateral direction and the plate-shaped panel installed in an axial direction for a long time is mounted on a heat recovery system to dramatically increase the heat recovery rate and counter flow. By reducing the flow resistance of the air, the power consumption of the motor fan was lowered, and the square plate panel was integrally molded to increase the production cost and durability, and to install a motor fan on the outdoor side to reduce indoor noise.

As another example, in the heat energy recovery type ventilation device of Korean Patent No. 10-1269287, the internal space is divided up and down, and an air supply port communicating with the upper space and an air exhaust port communicating with the lower space are respectively provided, and the upper space and An auxiliary exhaust port for bypassing the exhaust port is provided, and doors for opening and closing control are provided at the air supply and exhaust ports, and a pair of opening and closing doors for selectively changing a flow path is provided at a partition wall partitioning the upper space and the lower space. The main body, an absorption filter installed in a lower space inside the main body to vaporize and cool air flowing into the interior through the exhaust port, and installed in an upper space inside the main body to supply and exhaust air through the supply port and the exhaust port A heat exchanger that heats the air to be exchanged with each other, and a blower fan that discharges the air inside the body to the outside. A water supply pipe supplying water or condensed water to the absorption filter, a control unit installed outside the main body to control the opening and closing operation of the door and the pair of open and close doors, and indoor air installed inside the exhaust port It is composed of a branch door that selectively blocks the air supplied to the interior, and a branch duct that is installed to communicate with the exhaust port and selectively supplies indoor air or outdoor air to the exhaust port by the opening and closing operation of the branch door.

Accordingly, it has been proposed to solve the problem of energy consumption due to the re-operation of the air conditioning system due to the temperature difference between the outdoor air and the indoor air introduced in the process of introducing the outdoor air from which the exhaust heat has been recovered into the room.

As another example, an air purifier having a fine dust purification function of Korean Patent Publication No. 10-2015-105736 has an inlet through which air is introduced and an outlet in which a pen is provided to discharge purified air. The housing body is filled with water, a purification unit installed inside the housing body to purify the incoming air, and a water supply unit to purify foreign substances contained in the moving air by spraying water to the purification unit. , The air supply passage is formed between the water surface filled in the housing body and the lower portion of the purification unit, the purification unit is installed inside the housing main body, and the water supply unit is installed in communication with the housing main body. The discharge pipe for moving the water filled in the body, the pump installed in the discharge pipe, and the water supplied from the pump to the purification unit Made of a pipe for supplying washing, the cleaning pipes, having a particulate matter purifying features to install a pair of the spray nozzle.

In addition, the purification unit is installed inside the housing body and has a purification space therein, and a plurality of through holes are formed in the bottom panel, and the purification space of the purification case is partitioned and divided, and air is disposed in the upper portion of the purification space. A partition wall formed inside the purification case to form an air passage through which the movement is made, a lower partition wall which divides the air transport passage on the bottom surface of the purification case, and at which an end portion is introduced into water filled in the housing body, It consists of at least one purification ball filled in the purification space and formed with a permeable groove, and at least one external purification pin is further formed on an outer surface of the purification ball, and at least one internal purification pin is further formed in the permeation groove. , The external purification pin and the internal purification pin are formed of a synthetic resin material having elasticity, the housing main body A vibration device is further installed, and the vibration device is an eccentric cam sequentially hitting a pair of vibration protrusions formed on the outer surface of the purification case, and a driving motor installed on the inner surface of the housing body to rotate the eccentric cam. The housing body is installed in communication with each other in a pair, and the purification unit and the water supply unit installed in the housing body and the housing body purify fine dust of air flowing in from the outside and then discharged into the room. The other housing body, the purification unit, and the water supply unit inhale the air in the room and purify it, and then discharge it to the outside, thereby purifying the first generated in the room and discharging it to the outside and introducing the external purified air into the interior. The water permeable groove formed in the purification ball is formed in a through structure, and the inner surface of the water permeable groove is formed to be bent. do.

Accordingly, by purifying the fine dust of the air flowing into the housing body by spraying water to supply purified air to the room, and purifying the indoor air to discharge it to the outside, it has an air purification function and a heat exchange function.

However, the conventional air purification system has a problem that the efficiency of heat recovery is low as the recovery rate for waste heat contained in the exhaust air is lower than expected.

In addition, since the heat recovery rate is low, it is difficult to maintain a proper and uniform indoor temperature and humidity in the room, and eventually there is a problem that reliability of the heat recovery type air purification system is deteriorated.

Republic of Korea Patent Publication No. 10-1824875 (2018.02.02. Announcement) Republic of Korea Patent Publication No. 10-1027011 (2011.04.11. Announcement) Republic of Korea Patent Publication No. 10-764550 (2007.10.08. Announcement)

As proposed to solve the above problems, the object of the present invention is to recover the cold and wasted heating energy that is wasted during indoor ventilation, thereby reducing the cooling and heating energy required for fresh outside air that enters the room. A heat recovery type air purification system that provides stable, hygienic and comfortable ventilation by purifying the outside air entering the room while preventing outdoor pollution by filtering the filter unit when the indoor air is discharged to the outside with a saving effect To provide.

The present invention for achieving the above object is in the heat recovery type air purification system to improve the thermal efficiency by recovering the heat that is discarded by heat exchange between the indoor air and the outdoor air, which is the fresh air of the indoor air. , A heat exchanger in which a heat exchange stay space is formed so that the inside and outside air can exchange heat with each other; An intake duct constituting contaminated air in the room on one side of the heat exchanger to configure an intake line to exchange heat; An air supply duct constituting an air supply line to intake fresh air from the outside on the other side of the heat exchanger to exchange heat; And a filter unit configured in the intake and supply line to filter the intake or supply air to perform a purification function to enable stable and hygienic use.

In the present invention, the heat exchanger, the body; An intake pipe configured on one side of the body and configured to have an end of an intake duct and an exhaust fan configured to discharge the inside air sucked through the intake pipe to the outside to form an intake line; A second intake fan configured on the other side of the body and configured to intake outside air, which is outdoor air, and a second exhaust fan having one end connected to the air supply duct to discharge the outside air sucked through the second intake into the room It is configured to form an air supply line; It is preferable to include a heat exchanger residence space that performs heat recovery to maintain the temperature and humidity of the room by mutually exchanging heat as the bet and the outside air stay at the intersection of the intake line and the supply line in the center of the body. .

In the present invention, on one side of the intake duct, it is preferable to include at least one or more intake vents to allow intake of contaminated air in the room.

In the present invention, on one side of the air supply duct, it is preferable to include at least one or more outlets that allow fresh outdoor air to be supplied indoors.

In the present invention, the filter unit, a pre-filter for performing a primary filtration function; An ionizer that ionizes air (+); (+) A dust collecting cell that adsorbs and dissipates the ionized contaminants; A first activation filter performing a primary purification function through an activation material; A photocatalyst filter to remove organic compounds; A second activation filter performing a secondary purification function through an activation material; And a zeolite filter performing an antibacterial function.

In the present invention, on one side of the intake duct or the supply duct, it is preferable to include a check valve to adjust the opening and closing amount according to the air pressure so that uniform air is taken out.

In the present invention, the check valve comprises: a rotation shaft configured to be rotatable on one side of the duct; An opening plate fixed to one side of the rotating shaft and configured to open and close the interior of the duct; At least one stopper configured inside the duct to intermittently open and close the opening and closing plate in a direction that does not interfere with air flow through the duct; And a spring providing an elastic force so that the opening / closing amount of the opening / closing plate can be adjusted according to the air pressure traveling through the duct.

According to the present invention, when the indoor air is ventilated, the cooling and heating energy that is wasted is recovered and the cooling and heating energy required for fresh outside air entering the room is reduced, and the polluted air in the room is released to the outside. By filtering the filter unit, it prevents outdoor pollution and purifies the outside air entering the room, thereby providing stable and hygienic comfortable ventilation.

1 is a conceptual diagram of a heat recovery type air purification system according to the present invention.
2 is a block diagram of the heat exchanger and the intake and supply air ducts according to the present invention.
3 is a block diagram showing an example of a filter unit mounted on a heat exchanger according to the present invention.
4 is an operation diagram of a check valve according to the present invention,
4a is a no-load state, and 4b is an action diagram according to air pressure.

Advantages and features of the present invention, and a method for achieving the same will be apparent with reference to embodiments described below in detail together with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the present embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains. It is provided to completely inform the person having the scope of the invention, and the present invention is only defined by the scope of the claims. The same reference numerals refer to the same components throughout the specification.

Thus, in some embodiments, well-known process steps, well-known structures, and well-known techniques are not specifically described in order to avoid obscuring the present invention.

The terminology used herein is for describing the embodiments, and is not intended to limit the present invention. In the present specification, the singular form also includes the plural form unless otherwise specified in the phrase.

Includes and / or comprising as used herein refers to the presence or addition of one or more other components, steps, operations and / or elements other than the components, steps, operations and / or elements mentioned. Used in a way that does not exclude.

And, “and / or” includes each and every combination of one or more of the mentioned items.

In addition, the embodiments described herein will be described with reference to cross-sectional views and / or schematic drawings, which are ideal exemplary views of the present invention.

Therefore, the embodiments of the present invention are not limited to the specific shapes shown, but also include changes in the shape generated according to the manufacturing process.

In addition, in each of the drawings shown in the present invention, each component may be slightly enlarged or reduced in view of convenience of description.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The heat recovery type air purification system of the present invention includes a heat exchanger 10, an intake duct 20, an air supply duct 30, and a filter unit 40, as shown in FIGS. 1 to 4. .

The heat exchanger 10 induces the fresh air that maintains a constant temperature to be exhausted indoors by mutually exchanging heat between the polluted air and the fresh air in the process of inhaling the indoor polluted air and exhausting the fresh outdoor air. It is a heat recovery type ventilation system.

The heat exchanger 10 includes a body 110 forming an outline.

In addition, the body 110 includes an intake line connected to the intake duct 20 so that contaminated air in the room is intake through the intake duct 20.

The intake line is composed of an intake pipe 122 to which one end of the intake duct 20 is connected, and an exhaust fan 124 that discharges to the outside while allowing the indoor contaminated air to be sucked through the intake pipe 122.

In addition, the body 110 includes an air supply line connected to the air supply duct 30 so that fresh air is supplied indoors through the air supply duct 30.

The air supply line includes a second intake pipe 132 for allowing outdoor air to be inhaled, and a second exhaust fan 134 for supplying fresh outdoor air to the room through the second intake pipe 132. It is composed.

In this case, the air supply duct 30 is connected to the second exhaust fan 134 of the exhaust line.

In addition, a heat exchange space 140 is formed in the body 110 at a portion where the intake line and the air supply line intersect to exchange heat in the intake and exhaust transported along the intake line and the exhaust line.

The heat exchanger 10 is a structure or configuration that performs the same or similar function to a conventional heat recovery type ventilation device that allows heat exchange performance and ventilation performance to exchange heat between indoor and outdoor air. You can use either.

The intake duct 20 forms a flow path for guiding indoor air to be sucked into the heat exchanger 10.

In addition, the intake duct 20 includes an intake port 22 through which contaminated air in the room is inhaled.

The intake port 22 is configured at regular intervals in the intake duct 20, and as it is configured in each section of the room, intakes contaminated air formed in the room so that a purification function can be performed.

Also, the intake port 22 may be any structure or shape that induces indoor air to be smoothly inhaled.

The air supply duct 30 forms a flow path so that fresh air from the outside, that is, fresh air is taken out to the indoor space, so that purification and air conditioning are performed in the indoor space.

In addition, the air supply duct 30 includes an air outlet 32 that induces fresh air to be taken into the indoor space.

The outlet 32 is configured at regular intervals in the air supply duct 30, and as it is configured in each section of the room, the fresh air transported through the air supply duct 30 is guided to be taken out into the room. Purification function and air conditioning function should be performed.

In addition, the outlet 32 may be any structure or shape that induces fresh air to be taken out smoothly into the indoor space.

The filter unit 40 is configured on one side of the intake duct 20 or the air supply duct 30 to perform a function of purifying air.

For example, it is configured on one side of the intake duct 20, and purifies contaminated air intake through the intake duct 20, thereby releasing purified air when discharging to the outside to prevent environmental pollution. To be done.

In addition, a filter unit 40 is configured on one side of the air supply duct 30 to purify fresh outside air taken out through the air supply duct 30 to the air outlet 32 to enable safe and hygienic use.

The filter unit 40 includes a pre-filter 41, an ionizer 42, a dust collecting cell 43, a first activation filter 44, a photocatalyst filter 45, and a second activation filter ( 46), and a zeolite filter 47.

The pre-filter (41) is a filter that performs a primary filtering processing function.

In addition, the pre-filter 41 is configured to a degree capable of removing the fine particles 10 ~ 30㎛, performs a function to support the filtering function for the filters that are subsequently configured to be performed smoothly.

In addition, the pre-filter 41 is one side of the intake duct 20, for example, the intake introduction portion of the intake line of the heat exchanger 10, and one side of the intake line 30, for example, the intake of the air supply line of the heat exchanger 10 It is configured in each, and supports to remove 80% or more of the smoke in the form of tobacco smoke or particulates contained in indoor contaminated air or fresh air.

Of course, the present invention is not limited thereto, and the pre-filter 41 may be configured in a plurality of locations in order to improve the efficiency of filtering as convenience of manufacturing and manufacturing cost are low.

The ionizer 42 converts (+) ions into the polluted air that is sucked in and functions to float electricity.

The dust collecting cell 43 performs an extinguishing function by adsorbing and burning (+) ionized contaminants to remove contaminants.

Accordingly, the ionizer 42 and the dust collecting cell 43 are configured by modularity, thereby exhibiting deodorizing performance by removing contaminants such as polluted air, for example, cigarette smoke.

The first and second activation filters 44 and 46 perform a function of purifying harmful substances contained in contaminated air by the active substances.

In this case, the first and second activation filters 44 and 46 purify the air that is supplied as it is configured in the air supply line to enable stable and hygienic use.

The photocatalyst filter 45 is composed of nano-sized Tio2, activated carbon, and other chemical additives, and exhibits high-performance deodorization performance by removing harmful substances such as organic compounds (Voc).

Principles of photocatalytic purification

The zeolite filter 47 is a filter on which zeolite is adsorbed.

Here, zeolite is a type of feldspar mineral, and is a nano-porous material inside.

In addition, since it is an inorganic substance, the ore itself does not boil when heated, but the water molecules contained therein evaporate and emit water vapor. The appearance of water vapor seems to boil, so it has the meaning of “zeo” (Lithos) in Greek.

In addition, zeolites are widely used in various fields such as catalysts, adsorbents, detergent additives, feed additives, and soil improvers.

In addition, there are two types of zeolites: natural zeolites and synthetic zeolites. When the two categories are combined, a total of 200 types of zeolites exist.

In addition, since the zeolite has an ion-exchange structure, it has a much more stable structure than general types of antibacterial agents, so it can continuously exhibit strong antibacterial effects for a longer time.

In addition, although zeolite is less porous than activated carbon or charcoal currently used as the most adsorbent, activated carbon and charcoal have a property of burning at a high temperature of 400 ° C or higher.

On the other hand, zeolite is a material having an extremely high recyclability as it can be reused as an adsorbent by easily removing impurities adsorbed through heat treatment with the advantage of not burning even at high temperatures.

The filter unit 40 comprises a pre-filter 41, an ionizer 42, a dust collecting cell 43, and a first activation filter 44 sequentially in the intake line, and intake through the intake line To purify the polluted air to be discharged to the outside, the pre-filter (41), the ionizer (42), the dust collecting cell (43), the first activation filter (44), and the photocatalytic filter (45) in the air supply line In addition, the second activation filter 46 and the zeolite filter 47 are sequentially configured to purify the air that is inhaled outdoors and is supplied to the room to enable stable use.

Of course, the above-described configuration of the filter unit 40 of the intake line and the air supply line is an example, and various configuration relationships are provided to improve the purifying performance for air supplied to the room according to the purpose of use and the user's request. Can be selectively configured.

On the other hand, one side or each of the air supply duct 30 or the intake duct 20 includes a check valve 50 to support the heat recovery type air conditioning and purification function is improved by smooth air flow.

The check valve 50 is configured at one end of the air supply duct 30 or the air intake duct 20, for example, at one end side of the heat exchanger 10, fresh air or air intake duct supplied through the air supply duct 30 ( By preventing the polluted air, which is the polluted air intake through 20), from flowing backward, it performs a function of supporting the flow of air smoothly according to the air supply duct 30 or the air intake duct 20.

The check valve 50 includes a hinge shaft 52 configured to be rotatable freely on one side of the duct 20 and 30, an opening / closing plate 54 fixed to one side of the hinge shaft 52, and the duct (20) (30) is configured on one side of the stopper (56) to regulate the direction of rotation of the opening and closing plate (54) and the opening and closing plate (54) according to the intake or supply pressure acting on the duct (20) (30) It includes a spring 58 to adjust the opening and closing amount of.

The hinge shaft 52 is configured on one side of the duct 20 and 30 to perform a function of supporting the opening and closing plate 54 to rotate smoothly.

The opening and closing plate 54 is fixed to one side of the hinge shaft 52 and is configured to interrupt the inside of the ducts 20 and 30, so that the flow of air flowing through the ducts 20 and 30 is controlled. Support to crack down.

In addition, the opening and closing plate 54 is configured to have a certain angle of inclination around the hinge shaft 52, depending on the air pressure without interfering with the flow direction of the air flowing through the duct 20, 30 The opening and closing amount can be easily operated.

The stopper 56 performs a function of supporting the opening / closing plate 54 configured inside the duct 20 and 30 to be rotated only in the positive direction of the air flow direction.

The spring 58 allows the opening and closing amount of the opening / closing plate 54 to be adjusted according to the air pressure, that is, the wind pressure acting on the ducts 20 and 30, while the opening / closing plate 54 is a duct ( 20) (30) to provide an elastic force to maintain the state of interrupting.

Accordingly, the check valve 50 controls the amount of opening and closing according to the air pressure of the contaminated air or the fresh air that is supplied through the intake duct 20 or the supply duct 30 to block the flow of air by blocking the reverse flow. Supports the direction to be kept constant, and when not in use, blocks any air flow in the ducts 20 and 30 to prevent the air from entering the room, thereby maintaining the air purification performance of the room. .

Looking at the operating state of the heat recovery type air purification system configured as described above are as follows.

First, the indoor contaminated air is inhaled through the intake port 22 configured in the intake line, and the indoor air, which is the contaminated air in the room, is sucked into the intake pipe 122 of the heat exchanger 10 configured on one side of the intake line.

In addition, fresh outdoor air, that is, outside air is inhaled through the second intake pipe 132 of the air supply line configured on one side of the heat exchanger 10, and is indoors through the outlet 32 configured on one side of the air supply line. It is aired as.

At this time, in the heat exchanger 10, heat exchange is performed through the internal and external air in the heat exchange retention space 140 through a mutual residence state.

For example, when the outdoor temperature is relatively higher than the indoor temperature, such as in the summer, the air in the low temperature state and the outside air in the high temperature state exchange heat in the heat exchange retention space 140, so that the outside temperature in the relatively high temperature state is a low temperature bet. By lowering the temperature, the thermal efficiency is improved.

In addition, even in the winter, it is possible to obtain an energy saving effect according to a heat recovery function that improves thermal efficiency as heat exchange between the inside and outside air is performed as opposed to the above description.

In particular, the intake line and the supply line, for example, each of the intake pipe 122 and the second intake pipe 132 of the heat exchanger 10 is configured with a filter unit 40, included in the intake air through the intake line Filtered pollutants such as cigarette smoke are filtered to induce fresh bets to be discharged to the outside, and also to filter and purify the outside air taken out through the air supply line to enable stable and hygienic use.

In addition, by configuring the check valve 50 on one side of each of the intake duct 20 and the supply duct 30 constituting the intake line and the supply line, the air pressure intake and supply by the check valve 50 Accordingly, the opening and closing amount of the duct 20 and 30 is adjusted.

The opening / closing amount can be naturally adjusted according to the air pressure acting on the ducts 20 and 30 by the check valve 50 to maintain a uniform air pressure. By blocking the inflow to the, it is possible to use a stable.

What has been described above is only one embodiment for implementing the heat recovery type air purification system, and the present invention is not limited to the above-described embodiment. Those skilled in the art to which the present invention pertains will appreciate that various modifications can be made without departing from the gist of the present invention.

10: heat exchanger 110: body
122: intake pipe 124: exhaust fan
132: second intake pipe 134: second exhaust fan
140: heat exchange residence space 20: intake duct
22: air intake 30: air supply duct
32: outlet 40: filter unit
41: pre-filter 42: ionizer
43: dust collecting cell 44: first activation filter
45: photocatalyst filter 46: second activation filter
47: zeolite filter 50: check valve
52: hinge shaft 54: opening and closing plate
56: stopper 58: spring

Claims (7)

In the heat recovery type air purification system to improve the thermal efficiency by recovering the heat that is discarded due to the heat exchange between the inside air, which is the indoor air and the outside air, which is the fresh air,
A heat exchanger 10 in which a heat exchange staying space 140 is formed so that the inside and outside air can exchange heat with each other;
An intake duct (20) constituting an intake line so that heat is exchanged by inhaling contaminated air in the room on one side of the heat exchanger (10);
An air supply duct (30) constituting an air supply line so that heat exchange is performed by drawing fresh outdoor air into the other side of the heat exchanger (10); And
A filter unit 40 configured in the intake and supply line to filter the air that is inhaled or supplied to perform a purification function to enable stable and hygienic use;
Heat recovery type air purification system comprising a.
The method according to claim 1, The heat exchanger (10),
Body 110 and;
An intake pipe 122 configured at one side of the body 110 and configured at one end of the intake duct 20 and an exhaust fan 124 for discharging the intake air exhausted through the intake pipe 122 to the outdoors It is configured to form an intake line;
A second intake pipe 132 configured on the other side of the body 110 and configured to intake outside air, which is outdoor air, and one end of the air supply to discharge outside air sucked through the second intake pipe 132 into the room. A second exhaust fan 134 connected to the duct 30 is formed to form an air supply line;
A heat exchanger residence space 140 that performs heat recovery to maintain the temperature and humidity of the room by mutually exchanging heat as the bet and the outside air stay at the intersection of the intake line and the supply line in the central portion of the body 110;
Heat recovery type air purification system comprising a.
The method according to claim 1, One side of the intake duct (20),
At least one or more intake vents 22 for allowing indoor air to be polluted;
Heat recovery type air purification system comprising a.
The method according to claim 1, One side of the air supply duct 30,
At least one outlet 32 that allows fresh outdoor air to be supplied indoors;
Heat recovery type air purification system comprising a.
The method according to claim 1, wherein the filter unit 40,
A pre-filter 41 that performs a primary filtration function;
An ionizer 42 that ionizes air (+);
(+) A dust collecting cell 43 that adsorbs and dissipates the ionized contaminants;
A first activation filter 44 performing a primary purification function through an activation material;
A photocatalyst filter 45 to remove organic compounds;
A second activation filter 46 that performs a secondary purification function through the activation material; And
It is composed of at least one or more combinations including a zeolite filter 47 performing an antibacterial function;
Heat recovery type air purification system, characterized in that.
The method according to claim 1, The intake duct 20 or one side of the air supply duct 30,
Check valve 50 to control the opening and closing amount according to the air pressure so that uniform air is taken out;
Heat recovery type air purification system comprising a.
The method according to claim 6, The check valve 50,
A rotation shaft 52 rotatably configured on one side of the duct 20 and 30;
An opening and closing plate 54 configured on one side of the rotation shaft 52 and configured to open and close the inside of the duct 20 and 30;
At least one or more intermittently configured to be opened and closed so that the opening / closing plate 54 can be opened in a direction that is configured inside the duct 20 and 30 and does not interfere with the air flow going through the duct 20 and 30. Stopper 56; And
A spring 58 that provides an elastic force so that the opening / closing amount of the opening / closing plate 54 can be adjusted according to the air pressure traveling through the ducts 20 and 30;
Heat recovery type air purification system comprising a.

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