KR20210125305A - Residential ventilation system, and ventilating method thereof - Google Patents

Abstract

The present invention relates to a residential ventilation system and a ventilation method thereof. According to the present invention, the ventilation system realized two dampers required to bypass a heat exchange unit in normal ventilation with a single damper and has all of an outside air port (OA), an exhaust air port (EA), a supply air port (SA), and a return air port (RA) formed on one surface on the outer surface of a housing, a bypass flow path communicating with the return air port and the supply air port and formed in an internal space, and a damper arranged on the bypass flow path to directly discharge air sucked from the return air port to the exhaust air port through the bypass flow path without passing through the heat exchange unit by an open operation of the damper in a normal ventilation mode to prevent ventilation control for realizing normal ventilation from being complex and reduce part use amounts to reduce manufacturing costs.

Description

Residential ventilation system and ventilation method thereof

The present invention relates to a residential ventilation system and a ventilation method therefor.

In general, if the interior of a building is not well ventilated with the outside, carbon dioxide and the like increase and it is impossible to maintain a comfortable state, so it is necessary to ventilate the interior. If you open a window to ventilate, not only external pollutants such as fine dust flow in, but also internal heat loss occurs.

In order to satisfy both ventilation and heat loss prevention, a ventilation (air conditioning) system is used that forcibly cross-flows indoor air and outdoor air, and enables circulation of heat exchangers or clean air and energy saving in the process.

1 is a view showing the conceptual structure and operation process of a general heat recovery ventilation system.

Referring to FIG. 1, in the heat recovery ventilation system, a ventilation port (RA) and an air supply port (SA) are arranged on one side, and an outdoor port (OA) and an exhaust port (EA) are arranged on the other side opposite to one side. .

In the center of the interior, a total heat exchange element (HE: Heat Exchanger) that exchanges heat between the air sucked through the outside and the air sucked through the ventilation is arranged.

The ventilation operation consists of a total heat ventilation mode in which the air sucked into the ventilation port (RA) is discharged to the exhaust port (EA) via the total heat exchange element (HE), and the total heat exchange element (HE) is bypassed and discharged to the exhaust port (EA). This is done in normal ventilation mode.

The ventilation system of this structure requires two dampers to implement the bypass operation, which is an economizer function. That is, the damper 1 for passing the total heat exchange element HE and the damper 2 for bypassing the total heat exchange element HE are disposed on the suction path of the ventilation port RA.

In the total heat ventilation mode, when damper 1 is opened and damper 2 is closed, the air sucked into the ventilation port (RA) passes through the open damper 1 through the total heat exchange element (HE) to the exhaust port (EA). is discharged with

In the normal ventilation mode, when the damper 1 is closed and the damper 2 is opened, the air sucked into the ventilation port RA is discharged to the exhaust port EA through the open damper 2 via the bypass flow path.

As described above, in a general heat recovery ventilation system, in order to implement ventilation, the control of operating two dampers is complicated, and there is a problem in that the cost increases according to the increase in the small amount of parts along with the consumption of electricity.

Korean Patent Publication No. 10-2072071 (Registration Date: January 23, 2020) Japanese Laid-Open Patent Publication No. 2004-3869 (published on January 08, 2004) Japanese Laid-Open Patent Publication No. 2008-45794 (published on February 28, 2008) Japanese Laid-Open Patent Publication No. 2002-147803 (published date: May 22, 2002) Japanese Laid-Open Patent Publication No. 2005-188915 (published on July 14, 2005) Japanese Laid-Open Patent Publication No. 1996-114335 (published on May 07, 1996) Japanese Laid-Open Patent Publication No. 2011-12846 (published date: January 20, 2011) Japanese Laid-Open Patent Publication No. 2003-314856 (published on: November 06, 2003)

It is an object of the present invention to provide a ventilation system for residential use in which ventilation control for realizing normal ventilation is not complicated, and the manufacturing cost can be reduced by reducing the small amount of parts.

It is also an object of the present invention to provide a residential ventilation method that can increase the efficiency of normal ventilation by concentrating the flow of flow due to an increase in flow resistance in the normal ventilation mode.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned may be understood by the following description, and will be more clearly understood by the examples of the present invention. Moreover, it will be readily apparent that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

The residential ventilation system according to the present invention implements two dampers necessary for bypassing the heat exchange unit during normal ventilation with only one damper, so that the air sucked from the ventilation port is By discharging directly to the exhaust port through the bypass flow path without passing through the heat exchange unit, ventilation control for implementing normal ventilation is not complicated, and the manufacturing cost can be reduced by reducing the small amount of parts.

In addition, in the residential ventilation system according to the present invention, the external air outlet (OA), the exhaust port (EA), the air supply port (SA), and the ventilation port (RA) are all disposed on one side of the outside of the housing, and the bypass flow path is inside the housing. Since it is formed along one side of the furnace housing, there is an advantage in that it is easy to manufacture.

In addition, the residential ventilation system according to the present invention can increase ventilation efficiency by rapidly discharging air sucked from the ventilation port to the exhaust port through the exhaust fan disposed on the second flow path communicating the second side of the heat exchange unit and the exhaust port. .

In addition, the residential ventilation system according to the present invention includes an air guide having first to fourth flow paths that communicate with the external air outlet (OA), the exhaust port (EA), the air supply port (SA), and the ventilation port (RA), respectively, inside the housing. By disposing in the , the flow of air according to the ventilation operation through the first to fourth flow paths can be made smoothly.

In addition, in the residential ventilation system according to the present invention, first to fourth flow passages are formed by the combination of the upper cover and the lower cover of the air guide, and the first to fourth flow passages communicate with the heat exchange unit, respectively, to exchange heat during total heat ventilation. Electrothermal ventilation may be provided via the unit.

In addition, in the residential ventilation system according to the present invention, the bypass flow path is formed by the combination of the upper cover and the bypass cover of the air guide, so that air during normal ventilation can be moved only through the bypass flow path without passing through the heat exchange unit. .

In addition, in the residential ventilation system according to the present invention, the first flow path communicating the first side of the heat exchange unit and the ventilation hole is made of a straight flow path and a curved flow path, or is made to include at least two or more curved flow paths, so the bypass The flow resistance becomes larger than the flow path, so that air flows through the bypass flow path rather than the first flow path during normal ventilation.

In addition, in the residential ventilation system according to the present invention, the first flow path and the bypass flow path are connected, the width of the first flow path is smaller than the width of the bypass flow path, and the length of the first flow path is longer than the length of the bypass flow path By being formed, the flow resistance of the first flow path becomes greater than the flow resistance of the bypass flow path, so that air flows into the bypass flow path rather than the first flow path during normal ventilation. In this case, the cross-sectional area of the first flow path may be smaller than the cross-sectional area of the bypass flow path, and the volume of the first flow path may be smaller than or equal to the volume of the bypass flow path.

In addition, in the residential ventilation system according to the present invention, the heat exchange unit may be disposed inside the housing in a state where each side surface of the heat exchange unit is parallel to each side surface of the housing.

In addition, the residential ventilation system according to the present invention can protect the total heat exchange element by filtering the air sucked from the ventilation hole through the first filter disposed on the first flow passage communicating the first side of the heat exchange unit and the ventilation hole, and , it is possible to prevent the total heat exchange element from being contaminated.

And, in the residential ventilation system according to the present invention, the air sucked from the ventilation port through the bypass flow path in which the ventilation port and the exhaust port are directly communicated is directly discharged to the exhaust port without passing through the heat exchange unit through the open operation of the damper in the normal ventilation mode. Usually, the efficiency of ventilation can be increased.

On the other hand, in the residential ventilation method according to the present invention, the external air outlet (OA), the exhaust port (EA), the air supply port (SA) and the ventilation port (RA) are all formed on one side, and the bypass damper is opened or When closing, the air sucked through the ventilation hole RA formed on one side of the housing is discharged to the exhaust port EA formed on one side of the housing, so that the short By using the bypass flow path, the flow of the flow is concentrated and the efficiency of normal ventilation can be increased.

In addition, the residential ventilation method according to the present invention implements an operation in which the bypass damper is closed in the electrothermal ventilation mode and opened in the normal ventilation mode, so that two dampers are not required and the ventilation mode can be implemented with only one damper.

Also, in the residential ventilation method according to the present invention, when the bypass damper is opened, indoor air is sucked into the ventilation hole formed on one side of the housing, and the heat exchange unit is bypassed through the bypass flow path to the exhaust port formed on one side of the housing. can be discharged with

Also, in the residential ventilation method according to the present invention, during the closing operation of the bypass damper, indoor air is sucked into a ventilation hole formed on one side of the housing and discharged through an exhaust port formed on one side of the housing through a heat exchange unit.

Through this structure, it is easy to manufacture compared to a structure in which the existing ventilation is formed from a ventilation port on one side to an exhaust port on the other side, and thus the manufacturing time can be reduced.

In addition, in the residential ventilation method according to the present invention, when the bypass damper is opened, indoor air is sucked into the ventilation hole formed on one side of the housing, and through the bypass damper and the bypass flow path, the exhaust port is formed on one side of the housing. By being discharged, the indoor air is discharged out through the bypass flow path with a short moving distance in the normal ventilation mode, so that the normal ventilation is performed within a short period of time, thereby increasing the ventilation efficiency.

Also, in the residential ventilation method according to the present invention, when the bypass damper is closed, indoor air is sucked into the ventilation hole formed on one side of the housing, and the first flow path communicating the first side of the heat exchange unit and the ventilation hole and the heat exchange unit By discharging to the exhaust port formed on one side of the housing through the second flow path that communicates with the second side and the exhaust port, the ventilation operation is performed because one damper is used compared to the conventional ventilation using two dampers in the electrothermal ventilation mode. You can save the electricity cost for

In the residential ventilation system according to the present invention, ventilation control for realizing ventilation is not usually complicated, and the manufacturing cost can be reduced by reducing the small amount of parts.

In addition, in the residential ventilation method according to the present invention, the flow of flow is concentrated due to an increase in flow path resistance in the normal ventilation mode, thereby increasing the efficiency of normal ventilation.

In addition, the residential ventilation system according to the present invention can increase ventilation efficiency by rapidly discharging indoor air sucked from the ventilation hole to the exhaust hole through the exhaust fan.

In addition, the residential ventilation system according to the present invention can protect the total heat exchange element by filtering the air sucked from the ventilation hole through the filter, and can prevent the total heat exchange element from being contaminated.

In addition, in the residential ventilation system according to the present invention, air sucked from the ventilation port in the normal ventilation mode is directly discharged to the exhaust port without passing through the heat exchange unit, thereby increasing the efficiency of normal ventilation.

In addition, in the residential ventilation method according to the present invention, the air sucked from the ventilation port is discharged directly to the exhaust port through the bypass flow path, so that a short bypass flow path is used instead of a long flow path passing through the heat exchange unit in normal ventilation mode. Due to the increase in flow resistance according to

In addition, in the residential ventilation method according to the present invention, it is possible to implement a ventilation mode with only one damper without requiring two dampers during normal ventilation.

In addition, the residential ventilation method according to the present invention can be ventilated through the ventilation hole and the exhaust hole formed on the same side in both the normal ventilation mode and the electrothermal ventilation mode. Compared with the structure consisting of the exhaust port of the manufacturing, it is easy to manufacture, thereby reducing the manufacturing time.

In addition, in the residential ventilation method according to the present invention, since indoor air is discharged out through a bypass flow passage having a short moving distance in a normal ventilation mode, ventilation is performed within a short time to increase ventilation efficiency.

In addition, the residential ventilation method according to the present invention uses one damper compared to the conventional ventilation using two dampers in the electrothermal ventilation mode, so that it is possible to save electricity cost for the ventilation operation.

In addition to the above-described effects, the specific effects of the present invention will be described together while describing specific details for carrying out the invention below.

1 is a view showing the conceptual structure and operation process of a general heat recovery ventilation system.
2a and 2b is a block diagram showing the internal configuration of a residential ventilation system according to an embodiment of the present invention.
3 is a perspective view showing an air guide of a residential ventilation system according to an embodiment of the present invention.
4 is an exploded perspective view of an air guide according to an embodiment of the present invention.
5 is a view showing the total heat ventilation mode operation and air flow of the residential ventilation system according to an embodiment of the present invention.
6 is a view showing the normal ventilation mode operation and air flow of the residential ventilation system according to an embodiment of the present invention.
7 is a diagram schematically illustrating an internal configuration of a bypass damper according to an embodiment of the present invention.
8 is an operation flowchart for explaining a ventilation method of a residential ventilation system according to an embodiment of the present invention.

The above-described objects, features and advantages will be described below in detail with reference to the accompanying drawings, and accordingly, those of ordinary skill in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

Although the first, second, etc. are used to describe various elements, these elements are not limited by these terms, of course. These terms are only used to distinguish one component from other components, and unless otherwise stated, the first component may be the second component, of course.

Throughout the specification, unless otherwise stated, each element may be singular or plural.

In the following, that an arbitrary component is disposed on the "upper (or lower)" of a component or "upper (or below)" of a component means that any component is disposed in contact with the upper surface (or lower surface) of the component. Furthermore, it may mean that other components may be interposed between the component and any component disposed on (or under) the component.

Also, when it is described that a component is "connected", "coupled" or "connected" to another component, the components may be directly connected or connected to each other, but other components are "interposed" between each component. It is to be understood that “or, each component may be “connected,” “coupled,” or “connected” through another component.

As used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as "consisting of" or "comprising" should not be construed as necessarily including all of the various components or various steps described in the specification, some of which components or some steps are It should be construed that it may not include, or may further include additional components or steps.

Also, as used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as "consisting of" or "comprising" should not be construed as necessarily including all of the various components or various steps described in the specification, some of which components or some steps are It should be construed that it may not include, or may further include additional components or steps.

Throughout the specification, when “A and/or B” is used, it means A, B or A and B, unless specifically stated to the contrary, and when “C to D” is used, it means that there is no specific contrary description. Unless otherwise specified, it means that it is greater than or equal to C and less than or equal to D.

Hereinafter, a residential ventilation system and method according to an embodiment of the present invention will be described.

2a and 2b is a block diagram showing the internal configuration of a residential ventilation system according to an embodiment of the present invention.

2A and 2B , the residential ventilation system 200 according to an embodiment of the present invention includes a housing 201 that forms an external shape, and an external vent (OA), an exhaust vent on the outside of the housing 201 (EA), the air inlet (SA) and the ventilation (RA) may have a structure formed on one side.

That is, as shown in Fig. 2a, the outer port OA, the exhaust port EA, the air supply port SA, and the ventilation port RA are arranged at regular intervals on the upper surface to the outside of the housing 201, and the outdoor port ( OA) and the exhaust port EA are disposed on the outdoor side, and the air supply port SA and the ventilation hole RA may have a structure disposed on the indoor side.

The housing 201 may be in the form of a box, and an accommodating space in which an internal component such as the heat exchange unit 202 may be installed may be formed therein.

The housing 201 may be formed of a metal material to ensure rigidity, but is not limited thereto. In addition, a bracket or the like may be attached to the outside of the housing 201 for convenience of installation. Accordingly, the ventilation system 100 or the total heat exchange element (HE) may be fixed to the installation area through the bracket.

Also, the residential ventilation system 200 according to an embodiment of the present invention may include an air guide 300 disposed inside the housing 201 .

The air guide 300 may form at least one air flow path in the inner space. That is, the air guide 300 may have a plurality of flow paths communicating with the external vent, the exhaust vent, the supply vent, and the vent, respectively.

The air guide 300 may also be referred to as an upper air guide in that it protects the top and side surfaces of components disposed inside the housing 201 .

Some parts of the residential ventilation system 200 may be accommodated inside the air guide 300 .

The heat exchange unit 202 is accommodated in the air guide 300 . That is, the heat exchange unit 202 is spaced apart from the inner wall surface (upper, lower, and four surfaces) of the housing 201 by a predetermined interval, and may be accommodated in an appropriate position except for a space forming each flow path.

The heat exchange unit 202 includes a total heat exchange element (HE) for exchanging heat between the air sucked through the outdoor port and the air sucked through the ventilation port. In addition, the heat exchange unit 202 may include a total heat exchange element (HE) having a low channel height in order to increase heat exchange efficiency.

Although not shown, the heat exchange unit 202 may include an upper plate, a lower plate, a total heat exchange element (HE), and a supporter. The total heat exchange element (HE) may be provided between the upper plate and the lower plate.

The heat exchange unit 202 may have a first side, a second side, a third side, and a fourth side extending between the upper plate and the lower plate, or may be connected to each other. The four sides may be perpendicular to the upper plate and perpendicular to the lower plate.

A first flow path 210 communicating with the first side surface of the heat exchange unit 202 and the ventilation hole RA may be formed in the air guide 300 . The first flow path 210 may be formed by connecting a straight flow path and a curved flow path from the ventilation hole RA to the first side surface. The first flow path 210 may be formed to include two or more curved flow paths (curved pipe portions). The first flow path 210 may be a main flow path in the total heat ventilation mode.

In addition, a second flow path 220 communicating with the second side surface of the heat exchange unit 202 and the exhaust port EA may be formed inside the air guide 300 . The second side surface of the heat exchange unit 202 may be disposed at a position facing and opposite to the first side surface.

In addition, a third flow path 230 communicating with the third side surface of the heat exchange unit 202 and the external air outlet OA may be formed inside the air guide 300 . The third side surface of the heat exchange unit 202 may extend in a plane perpendicular to the first side surface and extend in a plane perpendicular to the second side surface.

In addition, a fourth flow path 240 communicating with the fourth side surface of the heat exchange unit 202 and the air supply port SA may be formed inside the air guide 300 . The fourth side surface of the heat exchange unit 202 may be disposed at a position facing and opposite to the third side surface. The fourth side surface may also extend in a plane perpendicular to the first side surface and extend in a plane perpendicular to the second side surface.

In the total heat exchange element (HE), indoor air and outdoor air may be exchanged heat. That is, the total heat exchange element (HE) may be stacked so that a plurality of outside air guide layer and inner guide layer cross each other.

The outside air guide layer may communicate with the third flow path 230 in contact with the outdoor port OA and the fourth flow path 240 in contact with the air supply port SA, and the bet guide layer has a first flow path in contact with the ventilation port RA. (210 and the second flow path 220 in contact with the exhaust port EA may communicate.

Accordingly, the outdoor air sucked through the outdoor air hole OA may flow to the outdoor air guide layer, and the indoor air sucked through the ventilation hole RA may flow into the indoor air guide layer to exchange heat with each other. In general, since indoor air is heated by the body temperature of people and has a higher temperature than outdoor air, the temperature of outdoor air may be increased by such heat exchange.

Thereafter, the heat-exchanged indoor air may be discharged through the exhaust port EA, and the heat-exchanged outdoor air may be discharged through the air supply port SA. That is, it is possible to supply warm outdoor air into the room through the air supply port SA.

At least one filter 251 and 252 for purifying the air flowing into the total heat exchange element HE may be provided on a side surface of the heat exchange unit 202 .

The first filter 251 is disposed adjacent to the first side surface of the heat exchange unit 202 in the first flow path 210 and filters the air sucked into the ventilation hole RA.

The second filter 252 is disposed in the third flow path 230 close to the third side surface of the heat exchange unit 202 and filters the air sucked in through the external port OA.

Each filter 251, 252 may be installed in contact with the heat exchange unit 202, it is also possible to be installed spaced apart. Each of the filters 251 and 252 may serve to filter out foreign substances contained in the air and purify the air. Each of the filters 251 and 252 may be various well-known filters, such as a non-woven fabric filter and a HEPA filter. In addition, the plurality of filters 251 and 252 installed on each side of the heat exchange unit 202 may be different types of filters. For example, the first filter 251 may be a non-woven fabric filter, and the second filter 252 may be a high-cleaning HEPA filter. In addition, each of the filters 251 and 252 may apply a medium-performance filter to sufficiently filter fine dust. Here, the medium-performance filter increases the flow resistance, so that the flow of the flow is concentrated from the ventilation port RA to the exhaust port EA.

In the inner space of the air guide 300, the air supply fan 204 is disposed in contact with the air supply port SA in the fourth flow path 240, and the air supply fan 204 blows the air in the fourth flow path 240 through the air supply port ( SA) to discharge.

In the inner space of the air guide 300 , the exhaust fan 206 is disposed in contact with the exhaust port EA in the second flow path 220 , and the exhaust fan 206 exhausts the air in the second flow path 220 through the exhaust port EA. discharged with

A bypass flow path 260 communicating with the ventilation port RA and the exhaust port EA may be formed in the air guide 300 . The bypass flow path 260 may be formed in the air guide 300 along one side of the housing 201 and parallel to one side of the housing 201 .

A bypass damper 270 may be disposed on the bypass flow path 260 . The bypass damper 270 is closed in the electrothermal ventilation mode, and is normally opened in the ventilation mode.

Referring to FIG. 2B , the bypass flow path 260 may be connected to the first flow path 210 to communicate the ventilation port RA and the exhaust port EA. That is, the bypass flow path 260 has one side extending from the exhaust port EA, and the other side is connected to the first flow path 210 extending from the ventilation port RA to communicate the ventilation port RA and the exhaust port EA. have.

Also, the width d1 of the bypass flow path 260 may be greater than the width d2 of the first flow path 210 . Accordingly, the cross-sectional area of the bypass flow path 260 may be larger than that of the first flow path 210 .

In addition, the bypass flow path 260 connecting the ventilation port RA and the exhaust port EA may be formed to have a shorter length than the length of the first flow path 210 . Accordingly, the volume of the bypass flow path 260 may be smaller than or equal to the volume of the first flow path 210 . In this case, the bypass flow path 260 may be the main flow path in the normal ventilation mode.

Meanwhile, the first flow path 210 may extend from the ventilation hole RA and be connected to the first side surface of the heat exchange unit 202 to communicate the ventilation hole RA and the heat exchange unit 202 .

In this case, the first flow path 210 may be formed by connecting at least one straight flow path and a curved flow path from the ventilation hole RA to the first side surface of the heat exchange unit 202 .

In addition, the first flow path 210 may be formed to include two or more curved flow paths (bent pipe portions) on the flow path formed from the ventilation hole RA to the heat exchange unit 202 .

Accordingly, the first flow path 210 formed from the ventilation hole RA to the heat exchange unit 202 may be the main flow path in the total heat ventilation mode.

3 is a perspective view illustrating an air guide of a residential ventilation system according to an embodiment of the present invention, and FIG. 4 is an exploded perspective view of the air guide according to an embodiment of the present invention.

2 to 4 , the air guide 300 according to an embodiment of the present invention may include an upper cover 310 , a lower cover 320 , and a bypass cover 330 .

In the internal space of the air guide 300 , some parts including the total heat exchange unit 202 , the air supply fan 204 , the exhaust fan 206 , and the like may be accommodated.

In the air guide 300 , a plurality of flow paths may be formed in the inner space by coupling the upper cover 310 and the lower cover 320 .

That is, in the inner space of the air guide 300 , a first flow path 210 communicating the first side surface of the heat exchange unit 202 and the ventilation port RA is formed, and the second side surface of the heat exchange unit 202 and the exhaust port ( A second flow path 220 that communicates with the EA) may be formed.

In addition, in the inner space of the air guide 300 , a third flow path 230 communicating the third side surface of the heat exchange unit 202 and the external air outlet OA is formed, and the fourth side surface of the heat exchange unit 202 and the water supply A fourth flow path 240 communicating with the instrument SA may be formed.

Here, each side surface (first to fourth) of the heat exchange unit 202 may be parallel to each side surface of the housing 201 , respectively.

In addition, the first flow path 210 , the second flow path 220 , the third flow path 230 , and the fourth flow path 240 are for coupling the upper cover 310 and the lower cover 320 of the air guide 30 . can be formed by

As described above, as four flow paths are formed in the inner space of the air guide 300 , the indoor air sucked from the ventilation port RA is discharged through the first flow path 210 and the second flow path 220 through the exhaust port EA. The air is discharged to and sucked from the external port OA may be discharged to the air supply port SA through the third flow path 230 and the fourth flow path 240 .

In addition, as shown in FIG. 5 , a bypass flow path 260 may be formed in the inner space of the air guide 300 to communicate with the ventilation port RA and the exhaust port EA.

The bypass flow path 260 may be formed by coupling the upper cover 310 and the bypass cover 330 of the air guide 300 . That is, the air guide 300 bypasses the bypass cover 330 by being coupled to the upper cover 310 in a state in which a groove is formed in a flow path shape so as not to overlap the other first to fourth flow paths 210 to 240 . The flow path 260 is completed and formed.

The bypass flow path 260 may serve to bypass the heat exchange unit 202 so that the indoor air sucked into the ventilation port RA is discharged to the exhaust port EA.

The air guide 300 may be made of various materials, but is preferably made of Expandable Polystyrene (EPS). Foamed polystyrene (EPS) is lightweight and has excellent thermal insulation, soundproofing, and buffering properties to maintain heat insulation inside the ventilation system 100, and reduce noise generated by the supply fan 204 and the exhaust fan 206, etc. There is an advantage that can protect the internal components of the ventilation system 100 from external impact. The air guide 300 may be manufactured as a single injection-molded product, and thus may be manufactured in various shapes.

5 is a view showing the total ventilation mode operation and air flow of the residential ventilation system according to an embodiment of the present invention, Figure 6 is a view showing the normal ventilation mode operation and air flow of the residential ventilation system according to an embodiment of the present invention am.

Referring to FIGS. 2 to 6 , the residential ventilation system 100 according to an embodiment of the present invention is a bypass flow path 260 that communicates the ventilation port RA and the exhaust port EA in the internal space of the air guide 300 . ) is formed, and a bypass damper 270 may be disposed on the bypass flow path 260 .

The bypass damper 270 may be closed in the electrothermal ventilation mode, and may be opened in the normal ventilation mode.

When the bypass damper 270 is opened, the air sucked into the ventilation port RA may move to the bypass flow path 260 and be discharged to the exhaust port EA.

5 , the width of the first flow path 210 may be smaller than the width of the bypass flow path 260 , and the length of the first flow path 210 may be formed to be longer than the length of the bypass flow path 260 . have. That is, since the width of the bypass flow path 260 is greater than the width of the first flow path 210 and the length of the bypass flow path 260 is shorter than the length of the first flow path 210 , the bypass flow path 260 is The flow path resistance may be smaller than that of the first flow path 210 .

Accordingly, when the bypass damper 270 is opened, the air sucked into the ventilation port RA moves to the bypass flow path 260 having a low flow resistance rather than the first flow path 210 having a high flow resistance, and thus to the exhaust port EA. it will be ejected

In this case, the bypass damper 270 may be an electric damper having the same configuration as in FIG. 7 . 7 is a diagram schematically illustrating an internal configuration of a bypass damper according to an embodiment of the present invention. 7, the bypass damper 270 includes a vane 710 that adjusts the opening degree of the flow path so that air flows according to the rotation angle, and a damper actuator 720 that operates the vane. can

Here, the residential ventilation system 100 according to an embodiment of the present invention may further include a control unit 730 . The controller 730 controls the operation of the damper actuator 720 .

The controller 730 may control the opening degree of the bypass damper 270 by operating the damper actuator 720 . An increase in the damper opening may mean that the damper is opened. A decrease in the damper opening may mean that the damper is closed.

By operating the damper actuator 720 under the control of the controller 730 , the rotation angle of the vane 710 may be controlled. Accordingly, the intake of air through the ventilation hole RA may be controlled. The control unit 730 may control overall operation of the ventilation system 100 .

Although not shown in the embodiment, the present invention may include a communication unit, an interface unit, an inverter unit, a display unit, an input unit, etc. in addition to the control unit 730 .

The bypass damper 270 may be closed in the electrothermal ventilation mode, and may be opened in the normal ventilation mode.

In the bypass damper 270 , as shown in FIG. 5 , in the electrothermal ventilation mode, indoor air sucked through the ventilation port RA does not flow into the bypass flow path 260 , but passes through the first flow path 210 . It moves and is closed so as to be discharged to the exhaust port EA via the heat exchange unit 202 and the second flow path 220 .

On the other hand, in the bypass damper 270 , as shown in FIG. 6 in the normal ventilation mode, the indoor air sucked into the ventilation port RA passes through the bypass flow path 260 without passing through the heat exchange unit 202 . It is opened to be discharged to the exhaust port (EA) by bypassing it.

Therefore, when the bypass damper 270 is opened, the bypass flow path 260 has a larger width and a shorter length than the first flow path 210 , so that the flow resistance is smaller than that of the first flow path 210 . Although the air sucked in (RA) flows to the first flow path 210 , a large amount moves to the bypass flow path 260 having a low flow resistance.

In this case, since the first flow path 210 has a small width and a long length, an actual bypass effect can be obtained by increasing the flow path resistance and lowering the total flow flow to less than 20%.

8 is an operation flowchart for explaining a ventilation method of a residential ventilation system according to an embodiment of the present invention.

Referring to FIG. 8 , first, the normal ventilation mode or the electrothermal ventilation mode is selectively inputted from the input unit (S810).

Here, the residential ventilation system 100 according to an embodiment of the present invention may include an input unit provided with a plurality of buttons on the outer surface of the housing 201 so that the user can operate it, and display the operating state including the input state. It may include a display unit for displaying.

Accordingly, the user may select and input the electrothermal ventilation mode or the normal ventilation mode for the ventilation mode through the input unit.

Next, the controller 730 controls the damper actuator 720 according to the selected normal ventilation mode or electrothermal ventilation mode (S820).

That is, when the normal ventilation mode is selected through the input unit, the control unit 730 transmits a command to execute normal ventilation to the damper actuator 720, and when the electrothermal ventilation mode is selected, the control unit 730 sends a command to execute electrothermal ventilation to the damper transmitted to the actuator 720 .

Then, the damper actuator 720 operates the bypass damper 270 in the normal ventilation mode or in the electrothermal ventilation mode (S830).

That is, the damper actuator 720 increases or decreases the opening degree of the vane 710 by, for example, transmitting the rotational operation of the motor to the vane 710 .

Then, the bypass damper 270 is opened or closed (S840).

That is, the bypass damper 270 is opened when the opening degree of the vane 710 is increased, and is closed when the opening degree of the vane 710 is decreased.

Here, the bypass damper 270 is closed in the electrothermal ventilation mode, and is opened in the normal ventilation mode.

When the bypass damper 270 is opened or closed, air sucked into the ventilation hole RA formed on one side of the housing 201 may be discharged through the exhaust port EA formed on one side of the housing 201 .

When the bypass damper 270 is opened as shown in FIG. 6 in the normal ventilation mode, indoor air is sucked into the ventilation hole RA formed on one side of the housing 201 and heat exchanges through the bypass flow passage 260 . By bypassing the unit 202 , it is discharged to the exhaust port EA formed on one side of the housing 201 . In this case, since the width of the bypass flow path 260 is greater than the width of the first flow path 210 and the length of the bypass flow path 260 is formed shorter than the length of the first flow path 210 , the bypass flow path 260 . has a flow resistance smaller than that of the first flow path 210 .

Accordingly, when the bypass damper 207 is opened, indoor air is sucked into the ventilation hole formed on one side of the housing and flows into the bypass flow path 260 having a flow resistance smaller than that of the first flow path 210 , so that the bypass damper It is discharged to an exhaust port formed on one side of the housing via the 270 and the bypass flow path 260 .

On the other hand, when the bypass damper 270 is closed in the electrothermal ventilation mode, indoor air is sucked into the ventilation hole RA formed on one side of the housing 201 and one side of the housing 201 via the heat exchange unit 202 . It is discharged through the exhaust port EA formed on the surface.

That is, when the bypass damper is closed, the indoor air is sucked into the ventilation hole formed on one side of the housing, and the first flow path 210 communicating the first side of the heat exchange unit 202 with the ventilation hole RA and the heat exchange unit It is discharged to the exhaust port formed on one side of the housing via the second flow path 220 that communicates with the second side of the 202 and the exhaust port (EA).

On the other hand, the residential ventilation system 100 according to an embodiment of the present invention that operates as described above has the same configuration as in FIGS. 2A, 2B, 3 to 4 and the wall-mounted type shown in FIG. 9 or FIG. It can be implemented in the ceiling type shown in 10. 9 is a perspective view illustrating a wall-mounted ventilation system according to an embodiment of the present invention, and FIG. 10 is a perspective view illustrating a ceiling-type ventilation system according to an embodiment of the present invention.

As shown in FIG. 9 , the wall-mounted ventilation system according to an embodiment of the present invention may include a fixing bracket 910 to be installed on an internal wall, such as a house or a building.

That is, the wall-mounted ventilation system according to an embodiment of the present invention is provided with fixing brackets 910 at the upper and lower ends of the rear surface of the housing 201, respectively, and can be fixed to the wall using screws or the like.

In addition, in the wall-mounted ventilation system, an opening 920 is formed in a rectangular shape of a predetermined size on the front surface of the housing 201, and an open door that can cover or open the opening 920 on the same surface. ) (930) may be provided. That is, in the wall-mounted ventilation system, when the open door 930 is opened, the air guide 300 provided inside through the opening 920, the supply air fan 204, the exhaust fan 206, and a plurality of filters ( 251 , 252 , and internal devices such as a heat exchange unit 202 are exposed. Accordingly, a user or an administrator may check the state of the internal devices through the opening 920 , and in some cases, may perform a task of replacing a specific device.

The ceiling type ventilation system shown in FIG. 10 may include a bracket stopper 1010 on the left and right sides of the housing 201 , respectively. That is, the ceiling type ventilation system may be fixed to the ceiling by using a screw or the like by matching the bracket stopper 1010 to the bracket fixed to the ceiling surface or the like.

In addition, the ceiling type ventilation system has an opening 1020 formed on the bottom surface of the housing 201, and may include an open door 1030 that covers or opens the opening 1020 on the same surface. That is, in the ceiling ventilation system, when the open door 1030 is opened, the heat exchange unit 202 provided therein through the opening 1020 , the supply air fan 204 , the exhaust fan 206 , and a plurality of filters 251 . , 252), etc., are revealed. Accordingly, a user or an administrator may check the status of internal devices through the opening 1020 , and may perform a task of replacing a specific device in some cases.

As described above, according to the present invention, it is possible to provide a ventilation system for residential use in which ventilation control for implementing normal ventilation is not complicated, and the manufacturing cost can be reduced by reducing the small amount of parts.

In addition, according to the present invention, it is possible to provide a ventilation method for residential use in which the flow of flow is concentrated due to an increase in flow resistance in the normal ventilation mode to increase the efficiency of normal ventilation.

As described above, the present invention has been described with reference to the illustrated drawings, but the present invention is not limited by the embodiments and drawings disclosed in the present specification. It is obvious that variations can be made. In addition, although the effects according to the configuration of the present invention are not explicitly described and described while describing the embodiments of the present invention, it is natural that the effects predictable by the configuration should also be recognized.

200: ventilation device 201: housing
202: heat exchange unit 204: air supply fan
206: exhaust fan 210: first flow path
220: second euro 230: third euro
240: fourth flow path 251: first filter
252: second filter 260: bypass flow path
270: bypass damper 300: air guide
310: upper cover 320: lower cover
330: bypass cover 710: vane
720: damper actuator 730: control unit
910: fixing bracket 920: opening
930: open door 1010: bracket catch
1020: opening 1030: open door
OA: Exhaust vent EA: Exhaust vent
SA : Air inlet RA : Ventilation
HE: Total heat exchange element

Claims (13)

a housing having an external port (OA), an exhaust port (EA), an air supply port (SA), and a ventilation port (RA);
an air guide disposed inside the housing and having a plurality of flow paths communicating with the external port, the exhaust port, the air supply port, and the ventilation port, respectively;
a heat exchange unit accommodated in the air guide and including a total heat exchange element for exchanging heat between the air sucked through the outdoor port and the air sucked through the ventilation port;
a bypass passage communicating the ventilation port and the exhaust port into the air guide; and
and a bypass damper disposed on the bypass flow path, closed in electrothermal ventilation mode, and opened in normal ventilation mode,
The outdoor port, the exhaust port, the air supply port, and the ventilation port are disposed on one external side of the housing, and the bypass flow path is formed inside along the one side of the housing, the ventilation system.
The method of claim 1,
The air guide is
a first flow path communicating the first side surface of the heat exchange unit and the ventilation port;
a second flow passage communicating the second side surface of the heat exchange unit and the exhaust port;
a third flow path communicating the third side surface of the heat exchange unit with the external air outlet; and
a fourth flow passage communicating a fourth side surface of the heat exchange unit and the air supply port;
A ventilation system comprising a.
3. The method of claim 2,
The air guide includes an upper cover, a lower cover and a bypass cover,
The first flow path, the second flow path, the third flow path and the fourth flow path are formed by coupling the upper cover and the lower cover, the ventilation system.
4. The method of claim 3,
The bypass flow path is formed by the coupling of the upper cover and the bypass cover, ventilation system.
3. The method of claim 2,
The first flow path includes a straight flow path and a curved flow path, or a ventilation system comprising at least two or more curved flow paths.
3. The method of claim 2,
The first flow path and the bypass flow path are connected,
The width of the first flow path is smaller than the width of the bypass flow path,
The length of the first flow path is formed longer than the length of the bypass flow ventilation system.
3. The method of claim 2,
A cross-sectional area of the first flow path is smaller than a cross-sectional area of the bypass flow path,
A volume of the first flow path is less than or equal to a volume of the bypass flow path.
The method of claim 1,
each side of the heat exchange unit is parallel to each side of the housing.
3. The method of claim 2,
an exhaust fan disposed in the second flow path in contact with the exhaust port and configured to discharge air in the second flow path to the exhaust port; and
an air supply fan disposed in contact with the air supply port in the fourth flow path and discharging air in the fourth flow path to the air supply port;
A ventilation system further comprising a.
3. The method of claim 2,
a first filter disposed in the first flow path adjacent to a first side surface of the heat exchange unit and configured to filter the air sucked into the ventilation hole; and
a second filter disposed in the third flow path adjacent to a third side surface of the heat exchange unit and configured to filter the air sucked into the outdoor port;
A ventilation system further comprising a.
An external air port (OA), an exhaust port (EA), an air supply port (SA), and a ventilation port (RA) are all formed on one side on the outside, and a bypass flow path through which the ventilation port and the exhaust port communicate with each other, the ventilation port and the heat exchange unit A ventilation method of a ventilation system in which a first flow path and a second flow path through which the exhaust port communicates with the heat exchange unit are formed, and a bypass damper is disposed on the bypass flow path,
(a) a step of selectively inputting a normal ventilation mode or an electrothermal ventilation mode from the input unit;
(b) the control unit controlling the damper actuator according to the selected normal ventilation mode or electrothermal ventilation mode;
(c) the damper actuator operating the bypass damper in a normal ventilation mode or in an electrothermal ventilation mode; and
(d) the bypass damper comprising the step of being opened (Open) or closed (Close),
When the bypass damper is opened or closed, the air sucked into the ventilation hole RA formed on one side of the housing is discharged to the exhaust port EA formed on one side of the housing.
12. The method of claim 11,
A width of the bypass flow path is greater than a width of the first flow path, and a length of the bypass flow path is formed to be shorter than a length of the first flow path,
When the bypass damper is opened in step (d), indoor air is sucked into the ventilation hole formed on the one side surface, flows into the bypass flow path having a flow resistance lower than that of the first flow path, and is formed on the one side surface A method of ventilation of a ventilation system, which is discharged through an exhaust port.
12. The method of claim 11,
When the bypass damper is closed in step (d), indoor air is sucked into the ventilation hole formed on the one side and formed on the one side through the first flow path, the heat exchange unit, and the second flow path A method of ventilation of a ventilation system, which is discharged through an exhaust port.

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