KR20220137299A - Sidewall inserted insulation ventilator - Google Patents

Abstract

Disclosed is a side wall insert type insulated ventilator capable of having an insulation effect without a separate heat exchange unit, and reducing an indoor carbon dioxide concentration. In accordance with the present invention, the side wall insert type insulated ventilator includes: a first prismatic duct including a first duct inlet connected to an indoor area, a first duct outlet connected to an outdoor area, a first duct top surface, a first duct bottom surface, and a first duct side surface; a second prismatic duct including a second duct inlet connected to the outdoor area, a second duct outlet connected to the indoor area, a second duct top surface, a second duct bottom surface, and a second duct side surface; a first separator formed on an upper side or a lower side of the first duct inlet and the first duct outlet in a direction perpendicular to the first duct; a second separator formed on an upper side or a lower side of the second duct inlet and the second duct outlet in a direction perpendicular to the second duct; a heat exchange unit causing heat exchange to a part in which the first duct top surface and the second duct bottom surface or the first duct bottom surface and the second duct top surface are tightly fitted and coupled in contact with each other; a spacing unit spacing the first duct outlet and the second duct inlet apart from each other; and a fan formed in a space between the first duct outlet and/or the second duct inlet and the outdoor area.

Description

Sidewall inserted insulation ventilator

The present invention relates to a side wall insert-type adiabatic fan, and more particularly, to a side wall insert-type fan that has an insulating effect without a separate heat exchange unit and reduces indoor carbon dioxide concentration.

A fan is a machine manufactured for the purpose of controlling the flow of gas, and is usually used for the purpose of circulating air by discharging indoor air to the outside. The fan cannot change the temperature of the air by itself, so when it is operated, the cold or hot air from the outside is delivered to the room as it is.

On the other hand, in the conventional ventilation fan having a thermal insulation function, the duct in which the fan is installed is buried in the ceiling or exterior wall of the building, and a separate heat exchange unit is installed to ventilate the room and maintain the indoor temperature at an appropriate temperature. However, in this case, there is an inconvenience in that a separate heat exchange unit needs to be installed in the ventilation fan.

Accordingly, Korean Patent Laid-Open No. 10-2020-0089577 discloses a window and a disaster prevention system having a ventilation function, but there is a problem in that a separate heat exchange unit must be provided. In addition, Korean Patent Registration No. 10-1450606 discloses a side wall insertion type heat exchange type bidirectional fan, but since it has a structure in which external air and internal air meet in the same space, there is a problem in that the insulation effect and practicality of ventilation are reduced.

The present invention relates to a side wall insert-type adiabatic fan, and more particularly, to provide a side wall insert-type fan that has an insulating effect without a separate heat exchange unit and reduces the indoor carbon dioxide concentration.

In order to solve the above problems, the present invention provides a prismatic first duct including a first duct inlet connected to the indoor, a first duct outlet connected to the outdoors, a first duct upper surface, a first duct lower surface, and a first duct side surface ; a prismatic second duct including a second duct inlet connected to the outdoors, a second duct outlet connected to the interior, a second upper surface of the duct, a second lower surface of the duct, and a second side surface of the duct; a first separator formed on an upper side or a lower side of the first duct inlet and the first duct outlet in a direction perpendicular to the first duct; a second separator formed on an upper side or a lower side of the second duct inlet and the second duct outlet in a direction perpendicular to the second duct; a heat exchange unit in which heat exchange occurs at a portion in which the first duct upper surface and the second duct lower surface or the first duct lower surface and the second duct upper surface are press-fitted and abutted; a spacer separating the first duct outlet and the second duct inlet; and a fan formed in a space between the first duct outlet and/or the second duct inlet and the outdoors.

In addition, it is formed at the first duct outlet and the second duct inlet, it provides a heat insulation ventilator comprising a cover that is opened and closed by the wind.

In addition, two or more of the first ducts are spaced apart by the interval of the first separator and are vertically coupled to provide an adiabatic fan to form a first duct row.

In addition, two or more second ducts are spaced apart by the interval of the second separator and vertically coupled to provide an adiabatic ventilator to form a second duct row.

In addition, two or more of the first duct provides an adiabatic fan, characterized in that the coupling between the side of the first duct.

In addition, two or more of the second duct provides an adiabatic fan, characterized in that the coupling between the side surfaces of the second duct.

The present invention provides the first and second ducts and the ventilator that ventilate the indoor air and provide a thermal insulation effect, thereby having an insulating effect without a separate heat exchange unit, and providing a side wall insertion type ventilator that ventilates the indoor air and reduces the carbon dioxide concentration. can

1 and 2 are perspective views for explaining the shape of the first duct and the second duct in an embodiment of the present invention, respectively.
3 and 4 are perspective views for explaining the shape of the first duct column and the second duct column in an embodiment of the present invention.
5A and 5B are perspective and enlarged perspective views each showing that a heat exchange part and a spaced part formed by abutting a first duct row and a second duct row in an embodiment of the present invention are formed by force fitting;
6 is a perspective view for explaining the shape of a fan in an embodiment of the present invention.
7 and 8 are perspective views for explaining the shape of the cover mounted on the fan in one embodiment of the present invention.
9 is a perspective view exemplarily showing a form in which the first duct column, the fan and the cover are combined in one embodiment of the present invention.
10 is a perspective view exemplarily showing a form in which the second duct column and the cover are combined in one embodiment of the present invention.
11 to 13 are respectively a perspective view, a plan view and a front view of a sidewall insertion type adiabatic fan according to an embodiment of the present invention.
14 and 15 are perspective views exemplarily showing a form in which a fan is inserted into a side wall according to an embodiment of the present invention.
16 and 17 are diagrams showing the experimental results for the indoor heat insulation effect and the change in the concentration of carbon dioxide when the fan is operated according to the present invention, respectively.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted. In order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are given to similar parts throughout the specification, and the detailed configuration direction of the present invention will be described with reference to the drawings. In addition, throughout the specification, when a part "includes" a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated.

The inventors of the present invention face the fact that a conventional fan must have a separate heat exchange unit to bring about a thermal insulation effect, and as a result of repeated research to solve this problem, when using a fan having a specific type of duct, A ventilation fan having an insulating effect without a separate heat exchange mechanism was discovered and led to the present invention.

1 and 2 are perspective views for explaining the shape of the first duct 110 and the second duct 120 in an embodiment of the present invention, respectively.

Referring to Figure 1, the first duct 110 is a duct for discharging indoor air to the outdoors, a first duct inlet 111a where the indoor and the duct meet to connect to the indoor, and the outdoor and the duct meet to connect with the outdoors A first duct outlet 111b, a first duct upper surface 112, a first duct lower surface 113, and a first duct side surface 114 may be formed. The first duct upper surface 112 and the first duct lower surface 113 may have a parallelogram shape, and the first duct side surface 114 may have a rectangular shape, so that the first duct 110 may have a prismatic shape.

The indoor air passes through the first duct inlet 111a and moves to the first duct outlet 111b so that indoor air can be discharged from the indoor to the outdoor, so that indoor carbon dioxide can be discharged to the outdoors.

On the other hand, a first separation membrane 115 may be formed on an upper side or a lower side of the first duct inlet 111a and the first duct outlet 111b in a direction perpendicular to the first duct 110, which is an indoor Air movement can be controlled by blocking the air from being discharged to the outside without passing through the first duct inlet 111a.

Referring to FIG. 2 , the second duct 120 is a duct for sucking outdoor air into the room, and a second duct inlet 121a where the outdoor and the duct meet to connect to the outdoors, and the indoor and the duct meet to connect with the indoor The second duct outlet 121b may include a second duct upper surface 122 , a second duct lower surface 123 , and a second duct side surface 124 . The second duct upper surface 122 and the second duct lower surface 123 may have a parallelogram shape, and the second duct side surface 124 may have a rectangular shape, so that the second duct 120 may have a prismatic shape.

The outdoor air passes through the second duct inlet 121a and moves to the second duct outlet 121b, so that the outdoor air can be introduced into the room, thereby reducing the indoor carbon dioxide concentration.

On the other hand, a second separation membrane 125 may be formed on an upper side or a lower side of the second duct inlet 121a and the second duct outlet 121b in a direction perpendicular to the second duct 120, which Air movement can be controlled by blocking the air from moving into the room without passing through the first duct inlet 121a.

3 and 4 are perspective views for explaining the shape of the first duct column and the second duct column in an embodiment of the present invention.

Referring to FIG. 3 , two or more of the first ducts 110 are spaced apart by the interval of the first separator 115 and are vertically coupled to each other, and are formed on the upper side or the lower side of the first duct inlet 111a. The first separator 115 and the first separator 115 formed on the upper or lower side of the first duct outlet 111b and in contact with the lower or upper side of the first separation membrane 115 and the first duct inlet 111a The duct outlet (111b) may be in contact with the lower side or the upper side and may be press-fitted, so that two or more first ducts 110 may be coupled in parallel to form a first duct row 1100.

Referring to FIG. 4 , two or more of the second ducts 120 are spaced apart by the interval of the second separation membrane 125 and are vertically coupled to each other, and are formed on the upper side or the lower side of the second duct inlet 121a. The second separation membrane 125 and the second separation membrane 125 and the second separation membrane 125 formed on the upper side or the lower side of the second duct outlet 121b in contact with the lower side or the upper side of the second duct inlet 121a. The second ducts 120 formed in two or more may be coupled in parallel to form a second duct row 1200 by being in contact with the lower side or the upper side of the duct outlet (121b) and press-fitting.

When the first duct row 1100 and the second duct row 1200 come into contact with each other and are press-fitted, a plurality of heat exchange units 130 to be described below may be formed.

5A and 5B are perspective and enlarged perspective views each showing that a heat exchange part and a spaced part formed by abutting a first duct row and a second duct row in an embodiment of the present invention are formed by force fitting;

5A and 5B, in the process in which the first duct and the second duct are press-fitted, the first duct upper surface 112 and the second duct lower surface 123 or the first duct lower surface 113 ) and the second duct upper surface 122 may be in contact with each other to form a heat exchange unit 130 in which heat exchange occurs.

The heat exchange unit 130 heats or cools the first duct 110 to the room temperature while the indoor air passes through the first duct 110 and exits the second duct 120 in contact therewith. Since it can be heated or cooled, the air entering the room through the second duct 120 can be heated or cooled to the room temperature without a separate heat exchange device, thereby obtaining a thermal insulation effect.

In addition, when the first duct row 1100 and the second duct row 1200 are in contact by being press-fitted, the first duct 110 and the second duct 120 are in contact by being press-fitted. Since the contact area is wider and the heat exchange unit 130 is formed more, it is possible to obtain a more excellent thermal insulation effect.

On the other hand, a spacer 131 that is spaced apart between the first duct outlet 111b and the second duct inlet 121a may be formed, so that the air discharged from the first duct outlet 111b is immediately discharged into the second duct outlet 111b. By preventing the inflow into the second duct inlet 121a, the indoor carbon dioxide concentration can be easily controlled and the indoor insulation effect can be maximized.

In order to facilitate heat exchange in the heat exchange unit 130, a metal having a high heat transfer rate of the first duct 110 and the second duct 120 may be used, and if it is a material capable of maintaining its shape, it is particularly limited. However, it is preferable to use stainless steel in terms of durability according to long-term use of the duct.

6 is a perspective view for explaining the shape of the fan 140 in an embodiment of the present invention.

Referring to FIG. 6 , the fan 140 serves to facilitate smooth indoor air circulation by moving indoor air to the outdoors or indoors, and the form is not particularly limited.

7 and 8 are perspective views for explaining the shape of the cover 150 mounted on the fan in an embodiment of the present invention.

7 and 8 , in the cover 150 , when the fan 140 is operated to generate wind and the switch 151 is opened, air can be moved to the opening 152 and the fan 140 . When the opening/closing unit 151 is closed due to non-operation, the air cannot move to the opening/closing opening 152, and when the fan 100 is not in use, foreign substances such as outdoor dust may be prevented from entering the room.

In addition, a shielding film 153 may be formed on the cover 150 to prevent vertical and horizontal movement of the air discharged from the first duct outlet 111b and to discharge it forward, thereby facilitating the discharge of indoor air. By preventing the vertical and horizontal movement of the air flowing into the second duct inlet 121a and allowing it to flow forward, it is possible to facilitate the inflow of outdoor air and prevent foreign substances such as rain, snow, and dust from entering the room.

9 is a perspective view exemplarily showing a form in which the first duct column 1100, the fan 140, and the cover 150 are combined in an embodiment of the present invention, and FIG. It is a perspective view exemplarily showing the form in which the two duct columns 1200 and the cover 150 are combined.

9 and 10 , the fan 140 may be formed between the first duct outlet 111b and/or the second duct inlet 121a and the outside, and the fan 140 is When formed at the first duct outlet 111b, indoor air may pass through the first duct inlet 111a, the first duct outlet 111b, and the opening/closing port 152 in order to be discharged to the outside, and the When formed in the second duct inlet 121a, outdoor air may pass through the opening 152, the first duct inlet 121a, and the second duct outlet 121b in order to be introduced into the room.

11 to 13 are a perspective view, a top view, and a front view, respectively, of the sidewall insertion type adiabatic fan 100 according to an embodiment of the present invention.

11 to 13 , two or more first duct rows 1100 may be formed to be coupled between the first duct side surfaces 114 , and two or more second duct rows 1200 may be formed similarly. to be coupled between the second duct side surfaces 124 . In this case, since the contact area between the first duct 110 and the second duct 120 is further increased, a plurality of the heat exchange units 130 are formed so that heat exchange is more active to maximize the heat insulation effect, which makes it easier to The room temperature can be maintained.

14 and 15 are perspective views exemplarily showing a form in which the fan 100 is inserted into the side wall according to an embodiment of the present invention.

14 and 15 , since the fan 100 is inserted into the sidewall, the height of the first duct 110 and the second duct 120 may be equal to or wider than the width of the sidewall.

In addition, the ventilation fan 100 may be inserted at the top of the window W from the side wall where the window W is formed, and in this case, it is possible to more effectively reduce the carbon dioxide concentration during ventilation together with the window.

Hereinafter, specific examples and comparative examples according to the present invention will be described.

Example

By combining three stainless steel first ducts up and down, the first duct row is manufactured in which the total length of the first duct inlet and the first duct outlet is 90 × 110 mm and the height of the first duct is 230 mm. And, these first 7 duct rows are coupled between the sides of the first duct so that the total horizontal length of the first duct inlet and the first duct outlet is 630 mm. In the same way, by combining three stainless steel second ducts up and down, the second duct row was formed in which the width and length of the second duct inlet and the second duct outlet were 90 × 110 mm and the height of the second duct was 230 mm. manufactured, and the total width of the second duct inlet and the second duct outlet is 630 mm by coupling 7 of these second duct rows between the side surfaces of the second ducts. The manufactured 1st and 2nd ducts are brought into contact with each other and are press-fitted together, and a 150 mm wide screen is installed where the 1st duct outlet and the 2nd duct inlet meet. 7 1st duct rows and 7 2nd ducts It is manufactured so that the sum of the horizontal lengths of the column and the screen is 1410 mm. Then, seven fans were installed at the seven first duct outlets, and 14 covers were combined at the first duct outlet and the second duct inlet to manufacture an insulating ventilator, which was inserted into the side wall of the building to connect indoors and outdoors.

comparative example

In the above embodiment, except for the installation of the first duct and the second duct, a fan was installed to manufacture a ventilator, and it was inserted into the side wall of the building to connect the indoor and the outdoor.

test example

The ventilators of Examples and Comparative Examples were operated and tested according to the following method, and the results are shown in Table 1, FIGS. 16 and 17 below.

[How to measure]

(1) Insulation effect

The temperature of a building with an outdoor temperature of 0°C and an indoor temperature of 20°C was measured for a total of 5 times for 2 minutes each.

(2) Indoor carbon dioxide concentration

The carbon dioxide concentration of a building with an initial carbon dioxide concentration of 20000 ppm was measured for a total of 5 times for 2 minutes each.

division Example comparative example Insulation effect (℃) after 0 minutes 20 20 after 2 minutes 18 15 after 4 minutes 15 11 after 6 minutes 13.5 9 after 8 minutes 12 7 after 10 minutes 11.5 4 Indoor Carbon Dioxide Concentration (ppm) after 0 minutes 20000 20000 after 2 minutes 3225 3835 after 4 minutes 954 1001 after 6 minutes 647 702 after 8 minutes 606 632 after 10 minutes 598 611

Referring to Table 1, according to the present invention, the adiabatic ventilator (Example) including a first duct, a second duct, a first separator, a second separator, a heat exchange unit, a spacer, and a fan has excellent thermal insulation effect and It is confirmed that the carbon dioxide concentration is lowered.

In contrast, when there is no adiabatic fan in which the first duct and the second duct are press-fitted (Comparative Example), the indoor carbon dioxide concentration is lowered, but there is no heat insulation effect, so it can be confirmed that the indoor temperature is rapidly lowered. .

As above, preferred embodiments of the present invention have been described in detail with reference to the drawings. The description of the present invention is for illustrative purposes, and those of ordinary skill in the art to which the present invention pertains will understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention.

Accordingly, the scope of the present invention is indicated by the following claims rather than the description of the invention, and all changes or modifications derived from the meaning, scope, and equivalent concept of the claims are interpreted as being included in the scope of the present invention. should be

100: adiabatic fan 110: first duct
1100: first duct row 111a: first duct inlet
111b: first duct exit 112: first duct top surface
113: when the first duct 114: the side of the first duct
115: first separator 120: second duct
1200: second duct row 121a: second duct inlet
121b: second duct exit 122: second duct upper surface
123: when the second duct 124: the second side of the duct
115: second separator 130: heat exchange unit
131: spaced part 140: fan
150: cover 151: switch
152: opening 153: screen
B: Building W: Windows

Claims (6)

a prismatic first duct including a first duct inlet connected to the indoor, a first duct outlet connected to the outdoors, a first duct upper surface, a first duct lower surface, and a first duct side surface;
a prismatic second duct including a second duct inlet connected to the outdoors, a second duct outlet connected to the interior, a second upper surface of the duct, a second lower surface of the duct, and a second side surface of the duct;
a first separator formed on an upper side or a lower side of the first duct inlet and the first duct outlet in a direction perpendicular to the first duct;
a second separator formed on an upper side or a lower side of the second duct inlet and the second duct outlet in a direction perpendicular to the second duct;
a heat exchange unit in which heat exchange occurs at a portion in which the first duct upper surface and the second duct lower surface or the first duct lower surface and the second duct upper surface are press-fitted and abutted;
a spacer separating the first duct outlet and the second duct inlet; and
and a fan formed in a space between the first duct outlet and/or the second duct inlet and the outdoors. The method of claim 1,
The first duct outlet and the second duct inlet is formed, the heat insulation fan comprising a cover that is opened and closed by wind. The method of claim 1,
An adiabatic fan in which two or more of the first ducts are spaced apart by the interval of the first separator and vertically coupled to form a first duct row. The method of claim 1,
An adiabatic fan in which two or more second ducts are spaced apart by an interval of the second separator and vertically coupled to form a second duct row. The method of claim 1,
At least two of the first ducts are adiabatic fan, characterized in that the coupling between the side surfaces of the first duct. The method of claim 1,
Two or more second ducts are adiabatic fan, characterized in that the coupling between the side surfaces of the second duct.

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