KR102563224B1 - Ventilation cap used in heat recovery ventilator - Google Patents

Abstract

a ventilation cap body coupled to one surface of the heat recovery ventilator and including a bottom surface in contact with one surface of the heat recovery ventilator and both side surfaces formed on both sides of the bottom surface; an indoor air cap discharge port formed on at least one of the both side surfaces; an outdoor air cap inlet formed on the other side of the both side surfaces; an indoor air cap inlet formed through the bottom surface to communicate with the indoor air outlet of the heat recovery ventilator; an outdoor air cap discharge port formed through the bottom surface to communicate with the outdoor air intake port of the heat recovery ventilator; an indoor air communication passage formed in the ventilation cap main body to communicate the indoor air cap inlet and the indoor air cap outlet; and an outdoor air communication passage formed in the ventilation cap main body to communicate the outdoor air cap outlet and the outdoor air cap inlet. Therefore, a heat recovery ventilator ventilation cap optimized for a heat recovery ventilator that does not require a separate pipe installation is provided.

Description

Ventilation cap used in heat recovery ventilator}

The present invention relates to a heat recovery ventilator, and more particularly, to a heat recovery ventilator ventilation cap attached to the heat recovery ventilator and exposed to the outside.

In general, a heat recovery ventilator using a total heat exchanger is used to discharge polluted indoor air of buildings such as apartment houses, offices, department stores, and large marts to the outside and supply new outside air to the indoor space.

That is, a conventional total heat exchanger is a device that first exchanges heat with indoor air discharged to the outside to prevent sudden cool air and heat from entering the inside from the outside when ventilating indoor air. Therefore, the total heat exchanger discharges volatile organic compounds generated in the room through the exhaust and inhales the filtered external fresh air into the room to keep the indoor air comfortable.

Therefore, when explaining the operation of a general total heat exchanger, when the air in the conditioned room is discharged to the outside, the exhaust fan installed in the total heat exchanger operates, and the polluted air passes through the total heat exchanger element at a constant pressure at this time. discharged to the outside

In such a heat recovery ventilator, a total heat exchanger must be installed inside, and a blowing fan must be provided so that indoor air and outdoor air can flow through the total heat exchanger. As a result, a size larger than a certain level is unavoidable. Therefore, conventional heat recovery ventilators are limited in that they are installed on the ceiling or installed in a tower type due to size problems.

However, in recent years, with the increase in single-person households, dwelling types with small acreage have become common, and the conventional heat recovery ventilator has a problem in that it takes up too much space to install in a small acreage of a small area.

In addition, the outlet for discharging indoor air and the inlet for sucking in outdoor air should be installed at a certain distance from each other to prevent the indoor air discharged through the outlet from being recirculated to the inlet. However, in order to prevent the air flowing through the inlet and the outlet from being mixed, separate piping must be installed, which not only occupies a lot of space, but also causes an increase in construction cost.

1. Korean Patent Publication No. 10-2019-0030418

Embodiments of the present invention have been made to solve the above problems, and provide a heat recovery ventilator that occupies less space.

In addition, it is intended to provide a heat recovery ventilator ventilation cap optimized for a heat recovery ventilator that does not require a separate pipe installation.

An embodiment of the present invention is coupled to one side of the heat recovery ventilator to solve the above problems, and includes a bottom surface in contact with one side of the heat recovery ventilator and both sides formed on both sides of the bottom surface. A ventilation cap body; an indoor air cap discharge port formed on at least one of the both side surfaces; an outdoor air cap inlet formed on the other side of the both side surfaces; an indoor air cap inlet formed through the bottom surface to communicate with the indoor air outlet of the heat recovery ventilator; an outdoor air cap discharge port formed through the bottom surface to communicate with the outdoor air intake port of the heat recovery ventilator; an indoor air communication passage formed in the ventilation cap main body to communicate the indoor air cap inlet and the indoor air cap outlet; and an outdoor air communication passage formed in the ventilation cap body to communicate the outdoor air cap discharge port and the outdoor air cap inlet.

In addition, it is preferable that the outdoor air cap discharge port and the indoor air cap inlet are vertically spaced from each other based on the heat recovery ventilator.

The indoor air cap discharge port includes an upper indoor air cap discharge port and a lower indoor air cap discharge port which are separated from each other in upper and lower directions, and the indoor air communication passage includes an upper indoor air communication passage communicating with the upper indoor air cap discharge port, and the upper indoor air cap discharge port. and a lower indoor air communication passage formed separately from the indoor air communication passage and communicating with the lower indoor air cap discharge port, wherein the indoor air cap inlet is selectively connected to the upper indoor air communication passage and the lower indoor air communication passage. It is effective to further include a cap indoor air branch damper to communicate.

The outdoor air cap inlet includes an upper outdoor air cap inlet and a lower outdoor air cap inlet that are separated from each other in upper and lower directions, and the outdoor air communication passage includes an upper outdoor air communication passage communicating with the upper outdoor air cap inlet; and a lower outdoor air communication passage formed separately from the upper outdoor air communication passage and communicating with the lower outdoor air cap inlet, wherein the outdoor air cap discharge port is selectively connected to the upper outdoor air communication passage and the lower outdoor air communication passage. A cap outdoor air branch damper to communicate with; may be further included.

a first barrier rib formed to face surfaces of the lower indoor air communication passage and the upper outdoor air communication passage simultaneously facing each other; and a second barrier rib formed to face surfaces of the upper indoor air communication passage and the lower outdoor air communication passage simultaneously facing each other.

According to the problem solving means of the present invention as described above, various effects including the following can be expected. However, the present invention is not established when all of the following effects are exhibited.

The heat recovery ventilator of the present invention has an advantage in that it can be mounted and operated on a window frame without a separate pipe and can be operated in various modes.

In addition, a heat recovery ventilator ventilation cap optimized for a heat recovery ventilator that does not require a separate pipe installation is provided.

1 is a partially broken perspective view of a heat recovery ventilator according to an embodiment of the present invention
Figure 2 is a front view of Figure 1
Figure 3 is a partial perspective view of a portion where the ventilation cap of Figure 1 is installed
4 is a rear perspective view of a state in which the ventilation cap of FIG. 1 is separated from the heat recovery ventilator;
Figure 5 is an exploded perspective view of the ventilation cap of Figure 3
Figure 6 is a rear perspective view of the upper case of Figure 4
Figure 7 is a perspective view of the intermediate separator of Figure 4
Figure 8 is a front exploded perspective view of the lower plate case and the middle separator of Figure 1
9 is a cross-sectional view along the line IX-IX of FIG. 8
Figure 10 is a perspective view of a state in which the damper is removed from the lower case of Figure 8
11 is a perspective view showing an operation example of the ventilation cap of FIG. 1 in summer
12 is a perspective view showing an operation example of the ventilation cap of FIG. 1 in winter
13 to 15 show the operating state for each operation mode of the heat recovery ventilator of the present invention,
13 is an operation diagram of a ventilation mode
14 is an air cleaning mode operation diagram
15 is a bypass mode operation diagram

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

1 is a partially broken perspective view of a heat recovery ventilator according to an embodiment of the present invention, FIG. 2 is a front view of FIG. 1 , and FIG. 3 is a partial perspective view of a portion where a ventilation cap of FIG. 1 is installed.

As shown in these drawings, the heat recovery ventilator 10 according to one embodiment of the present invention is fitted and fixed to the window frame 1 in the form of a cartridge. That is, the heat recovery ventilator 10 according to an embodiment of the present invention includes a ventilator case 9 having a high height relative to FIG. 2 and having a left and right width greater than a thickness.

The left side of the ventilator case 9 is exposed to the indoor area 2 and the right side is exposed to the outdoors 3 based on FIG. 2 .

The ventilator case (9) is formed so that the indoor air discharge passage (4) and the outdoor air supply passage (5) cross each other, and is located at the point where the indoor air discharge passage (4) and the outdoor air supply passage (5) intersect. A heating element 13 is installed. An indoor air inlet 11a communicating with the indoor air discharge passage 4 is formed at the lower left corner, and an outdoor air outlet 12a communicating with the outdoor air supply passage 5 is formed at the upper left corner. An outdoor air inlet 12 communicating with the outdoor air supply passage 5 is formed at the lower right corner, and an indoor air outlet 11 communicating with the indoor air discharge passage 4 is formed at the upper right corner. Here, the distance between the outdoor air outlet 12a and the indoor air intake 11a is greater than the distance between the outdoor air intake 12 and the indoor air outlet 11 . That is, the interval between the discharge port and the suction port formed on the left and right is formed asymmetrically. This is a structure for implementing a ventilation device including a heating element in a narrow space.

2, the heating element 13 is arranged in a diamond shape at the center, the indoor air outlet 11 is formed on the upper side of the right vertex of the heating element 13, and the outdoor air intake 12 is formed on the lower side. do. The ventilation cap 100 is coupled to one surface (side) on which the indoor air outlet 11 and the outdoor air intake 12 are formed. The ventilation cap 100 is exposed to the outside.

An indoor air discharge fan 19 is installed on the indoor air discharge passage 4 connecting the indoor air outlet 11 and the heating element 13 . An outdoor air supply fan 14 is installed on the outdoor air supply passage 5 through which the outdoor air of the heating element 13 is heat-exchanged and then supplied to the room. In addition, a sterilization device 17 may be installed between the heating element 13 and the outdoor air supply fan 14 to sterilize harmful bacteria contained in the air supplied indoors. The sterilizer 17 may be implemented with a UV lamp or the like.

In addition, the indoor air discharge passage opening and closing damper 15 installed adjacent to the indoor air intake port 11a and opening and closing the indoor air discharge passage 4, and between the heating element 13 and the outdoor air supply fan 14 An outdoor air supply passage (5) between an air damper (16) capable of opening and closing the direct communication between the outdoor air supply passage (5) and the indoor (2), and the heating element (13) and the outdoor air supply fan (14) and a bypass damper 18 capable of opening and closing communication between the indoor air discharge passage 4 between the heating element 13 and the indoor air discharge fan 19.

4 is a rear perspective view of a state in which the ventilation cap of FIG. 1 is separated from the heat recovery ventilator. 5 is an exploded perspective view of the ventilation cap of FIG. 3, FIG. 6 is a rear perspective view of the upper case of FIG. 4, FIG. 7 is a perspective view of the middle separator 130 of FIG. 4, and FIG. FIG. 9 is a front exploded perspective view of the separating plate, FIG. 9 is a cross-sectional view along the line IX-IX in FIG. 8 , and FIG. 10 is a perspective view of a state in which the damper is removed from the lower case of FIG. 8 .

As shown in these drawings, the ventilation cap 100 is coupled to one surface of the heat recovery ventilator 10, and the bottom surface 111 in contact with one surface of the heat recovery ventilator 10 and the bottom surface 111 A ventilation cap body (110, 120, 130) including both side surfaces formed on both sides, an indoor air cap discharge port (123, 124) formed on at least one of the both side surfaces, and an outdoor air cap intake port (121) formed on the other side of the both side surfaces , 122), the indoor air cap inlet 113 formed through the bottom surface 111 to communicate with the indoor air outlet 11 of the heat recovery ventilator, and the outdoor air inlet 12 of the heat recovery ventilator. The ventilation cap main body (110, 120) communicates with the outdoor air cap outlet (112), the indoor air cap inlet (113), and the indoor air cap outlet (123, 124) formed by penetrating the bottom surface (111) as much as possible. , 130) and an outdoor air communication passage 150 formed in the ventilation cap body to communicate between the outdoor air cap outlet and the outdoor air cap inlet.

The ventilation cap bodies 110 , 120 , and 130 include a lower case 110 , a middle separator plate 130 , and an upper case 120 .

The upper case 120 has indoor air cap outlets 123 and 124 formed on one side and outdoor air cap intake ports 121 and 122 formed on the other side. The indoor air cap discharge ports 123 and 124 include an upper indoor air cap discharge port 123 and a lower indoor air cap discharge port 124 separated from each other in the upper and lower directions. That is, the upper and lower indoor air cap outlets 123 and 124 are separated from each other by the upper and lower separation membranes 125 formed across the inside of the upper case 120 . The outdoor air cap intake ports 121 and 122 include an upper outdoor air cap intake port 121 and a lower outdoor air cap intake port 122 separated from each other in the upper and lower directions. That is, the upper and lower outdoor air cap inlets 121 and 122 are separated from each other by the upper and lower separation membranes 125 . In addition, the upper indoor/outdoor separation membrane 126 separating the space between the upper indoor air cap outlet 123 and the upper outdoor air cap inlet 121, and the lower indoor air cap discharge port 124 and the lower outdoor air cap inlet 122 It includes a lower indoor/outdoor separator 127 separating spaces.

Due to the upper and lower separation membranes 125, the upper indoor/outdoor separation membrane 126, and the lower indoor separation membrane 127, the upper indoor air room 128a, the lower indoor air room 128c, the upper outdoor air room 128b, and the lower outdoor air room 128b The air chambers 128c are separated independently from each other and communicate with the upper indoor air cap outlet 123, the lower indoor air cap outlet 124, the upper outdoor air cap inlet 121, and the lower outdoor air cap inlet 122, respectively. do.

In the intermediate separator 123, communication holes 131, 132, 133, and 134 communicating with the space partitioned by the upper and lower separators 125, the upper indoor and outdoor separators 126, and the lower indoor and outdoor separators 127, respectively, are formed in the intermediate separator 123. ) is formed.

The lower case 110 has a bottom surface 111 and an upper surface 114, and an intermediate separator 130 is coupled to the upper surface 114. The above-described indoor air cap inlet 113 and the outdoor air cap outlet 112 are formed through the bottom surface 111. The outdoor air cap outlet 112 and the indoor air cap inlet 113 are vertically spaced from each other based on the heat recovery ventilator.

As shown in FIG. 8, the upper surface 114 has an upper indoor communication hole 116a communicating with the upper indoor air room 128a, the lower indoor air room 128c, the upper outdoor air room 128b, and the lower outdoor air room 128d, respectively. ), a lower indoor communication hole 116c, an upper outdoor communication hole 116b, and a lower outdoor communication hole 116d are formed.

In addition, as can be seen from FIGS. 10 and 9 , a separate indoor conversion hole 117a communicating with the indoor air cap intake 113 and an outdoor air cap discharge port 112 are provided at the middle portion of the lower case 110 in the thickness direction. An outdoor conversion hole 117b communicating with is formed.

Due to this structure, the aforementioned indoor air communication passage 140 and the outdoor air communication passage 150 are respectively formed. That is, as shown in FIG. 10 , the indoor air communication passage 140 includes the upper indoor air communication passage 141 communicating with the upper indoor air cap discharge port 123 and the upper indoor air communication passage 141. It is formed separately and includes a lower indoor air communication passage 142 communicating with the lower indoor air cap discharge port 124 . The outdoor air communication passage 150 is formed separately from the upper outdoor air communication passage 151 communicating with the upper outdoor air cap inlet 121 and the upper outdoor air communication passage, and is formed separately from the lower outdoor air cap inlet 121. A lower outdoor air communication passage 152 is provided.

That is, the upper indoor air communication passage 141 is a passage connecting the indoor air cap inlet 113 and the upper indoor air cap discharge port 123 through the upper indoor communication hole 116a, and the lower indoor air communication passage 142 ) is a flow path connecting the lower indoor air cap discharge port 124 through the indoor air cap inlet 113, the indoor air conversion hole 117a, and the lower indoor air communication hole 116c.

In addition, the upper outdoor air communication passage 151 is a passage connecting the upper outdoor air cap inlet 121 through the outdoor air cap discharge port 112, the outdoor conversion hole 117b, and the upper outdoor air communication hole 116b. The lower outdoor air communication passage 152 is a passage connecting the outdoor air cap discharge port 112 and the lower outdoor air cap intake port 122 through the lower outdoor air communication hole 116d.

Meanwhile, a cap indoor air branch damper 160 is further included to selectively communicate the indoor air cap inlet 113 to the upper indoor air communication passage 141 and the lower indoor air communication passage 142. That is, the cab indoor air branch damper 160 selectively allows the indoor air cab inlet 113 to communicate with one of the upper indoor communication hole 116a and the indoor conversion hole 117a. Additionally, the cab indoor air branch damper 160 may be formed in a 3-way structure including a position where the indoor air cap inlet 113 is closed.

In addition, a cap outdoor air branch damper 170 for selectively communicating the outdoor air cap discharge port 112 to the upper outdoor air communication passage 151 and the lower outdoor air communication passage 152 may be further included. . That is, the cap outdoor air branch damper 170 allows the outdoor air cap discharge port 112 to selectively communicate with either the lower outdoor communication hole 116d or the outdoor conversion hole 117b. Additionally, the cap outdoor air branch damper 170 may be formed in a 3-way structure including a position where the outdoor air cap outlet 112 is closed.

A first partition wall 115 is formed so that the lower indoor air communication passage 142 and the upper outdoor air communication passage 151 face each other simultaneously. By being formed in this way, when indoor air and outdoor air flow through the two passages, an additional heat exchange effect can be obtained.

As described above, in the ventilation cap of the embodiment of the present invention, the cap inlets 121 and 122 for sucking outdoor air are operated by the cap outdoor air branch damper 170 to open the upper and lower outdoor air cap inlets 121 and 122. Any of the upper and lower cap outlets 123 and 124 for discharging indoor air may be selected.

Therefore, as shown in FIGS. 11 and 12 , by allowing the sucked outdoor air and the discharged indoor air to flow in opposite directions, it is possible to sufficiently prevent the discharged indoor air from being re-inhaled into the sucked outdoor air.

In addition, in summer, as shown in FIG. 11, cool indoor air is discharged through the lower actual air cap outlet 124, and hot outdoor air is sucked in through the upper outdoor air cap inlet 121, so that cold indoor air It is more difficult to move upward and re-inhale through the upper outdoor air cap inlet 121.

And, in winter, as shown in FIG. 12, warm indoor air is discharged upward and cold outdoor air is sucked in from the lower side, further reducing the possibility that warm indoor air is sucked through the lower outdoor air cap inlet 122. there is.

13 to 15 show the operation state of the heat recovery ventilator according to the operation mode of the present invention. FIG. 13 is a ventilation mode operation diagram, FIG. 14 is an air cleaning mode, and FIG. 15 is a bypass mode.

When operating in the ventilation mode, as shown in FIG. 13, both the outdoor air supply fan 14 and the indoor air discharge fan 19 operate, the air damper 16 and the bypass damper 18 are closed, , the rest of the dampers are all open and working. In this way, after the outdoor air and indoor air exchange heat through the heating element 13, the outdoor air is supplied to the room and the indoor air is discharged to the outside.

When operating in the air cleaning mode, as shown in FIG. 14, the outdoor air supply fan 14 is operated in a state in which the air cleaning damper 16 is opened and all other dampers are closed. As a result, indoor air is recirculated as it is, and the sterilizer 17 can sterilize harmful bacteria contained in the room.

When operated in the bypass mode, as shown in FIG. 15, after opening the air damper 16 and the bypass damper 18, all other dampers are closed. When the actual air discharge fan 19 is operated in this state, indoor air is discharged to the outdoors as it is.

As described above, the heat recovery ventilator of the present invention has an advantage in that it can be mounted and operated on a window frame without a separate pipe and can be operated in various modes.

In the above, preferred embodiments of the present invention have been described by way of example, but the scope of the present invention is not limited only to these specific embodiments, and can be appropriately changed within the scope described in the claims.

4: indoor air discharge passage 5: outdoor air supply passage
10: heat recovery ventilator 11a: indoor air intake
11: indoor air outlet 12a: outdoor air outlet
12: outdoor air inlet 100: ventilation cap
111: bottom surface 112: outdoor air cap discharge port
113: indoor air cap inlet 121: upper outdoor air cap inlet
122: lower outdoor air cap inlet 123: upper indoor air cap discharge port
124: lower indoor air cap discharge port 140: indoor air communication passage
141: upper indoor air communication passage 142: lower indoor air communication passage
150: outdoor air communication passage 151: upper outdoor air communication passage
152: lower outdoor air communication passage 160: cab indoor air branch damper
170: Cab outdoor air branch damper

Claims (5)

a ventilation cap body coupled to one surface of the heat recovery ventilator and including a bottom surface in contact with one surface of the heat recovery ventilator and both side surfaces formed on both sides of the bottom surface;
an indoor air cap discharge port formed on at least one of the both side surfaces;
an outdoor air cap inlet formed on the other side of the both side surfaces;
an indoor air cap inlet formed through the bottom surface to communicate with the indoor air outlet of the heat recovery ventilator;
an outdoor air cap discharge port formed through the bottom surface to communicate with the outdoor air intake port of the heat recovery ventilator;
an indoor air communication passage formed in the ventilation cap main body to communicate the indoor air cap inlet and the indoor air cap outlet; and
an outdoor air communication passage formed in the ventilation cap body to communicate the outdoor air cap discharge port with the outdoor air cap inlet port;
Including,
The indoor air cap discharge port includes an upper indoor air cap discharge port and a lower indoor air cap discharge port separated from each other in upper and lower directions;
The indoor air communication passage includes an upper indoor air communication passage communicated with the upper indoor air cap discharge port and a lower indoor air communication passage formed separately from the upper indoor air communication passage and communicating with the lower indoor air cap discharge port; ,
a cap indoor air branch damper to selectively communicate the indoor air cap inlet with the upper indoor air communication passage and the lower indoor air communication passage;
Heat recovery ventilator ventilation cap further comprising a.
According to claim 1,
The outdoor air cap discharge port and the indoor air cap inlet,
A heat recovery ventilator ventilation cap, characterized in that formed spaced apart from the top and bottom based on the heat recovery ventilator mounted on the heat recovery ventilator.
delete According to claim 1,
The outdoor air cap inlet includes an upper outdoor air cap inlet and a lower outdoor air cap inlet that are separated from each other in upper and lower directions;
The outdoor air communication passage includes an upper outdoor air communication passage communicating with the upper outdoor air cap intake and a lower outdoor air communication passage formed separately from the upper outdoor air communication passage and communicating with the lower outdoor air cap intake. and
a cap outdoor air branch damper for selectively communicating the outdoor air cap discharge port with the upper outdoor air communication passage and the lower outdoor air communication passage;
Heat recovery ventilator ventilation cap further comprising a.
According to claim 4,
a first barrier rib formed to face surfaces of the lower indoor air communication passage and the upper outdoor air communication passage simultaneously facing each other; and
a second barrier rib formed to face surfaces of the upper indoor air communication passage and the lower outdoor air communication passage simultaneously facing each other;
Heat recovery ventilator ventilation cap further comprising a.

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