KR20190133516A - Ventilating apparatus for building - Google Patents

Abstract

The present invention relates to an indoor ventilation apparatus comprising: a housing; a main partition installed in the housing to divide an indoor air discharge line with which an indoor inlet and an outdoor outlet communicate and an outdoor air inlet line with which an outdoor inlet and an indoor outlet communicate; a first blowing fan installed on the indoor air discharge line to forcibly move air in one direction; a second blowing fan installed on the outdoor air inlet line to forcibly move air in one direction; a total heat exchanger installed across both sides of the indoor air discharge line and the outdoor air inlet line; and a filter unit installed on the outdoor air inlet line to purify air. The total heat exchanger is rotated by a motor to change a surface onto which air flows into the total heat exchanger and a position where air passes in the total heat exchanger in the indoor air discharge line and the outdoor air inlet line. The present invention applies a total heat exchanger rotating to change an air entering position and a passing position to eliminate a problem where air passes only a fixed position of a total heat exchanger to degrade heat exchange efficiency and prevent a problem caused by creation of condensation in the total heat exchanger.

Description

Indoor Ventilation Unit {VENTILATING APPARATUS FOR BUILDING}

The present invention relates to a ventilation device, and more particularly to an indoor ventilation device that can reduce the energy loss.

Generally, a window is formed in a building, and a conventional ventilation method is to open a window to exhaust indoor air to the outside and to perform outdoor air inflow.

However, there is a case where there is no window or a small building or the arrangement of the windows, and there is a case that the ventilation of the indoor air cannot be performed through the window. For this purpose, a ventilation device for circulating the indoor and outdoor air has been developed.

Recently, even if sufficient ventilation is possible through the windows, heat exchange facilities for preventing heat loss have been installed in the ventilation system in order to reduce energy loss in the process of ventilating through the windows in the summer or winter when the indoors are cooled and heated. It is used in addition. Furthermore, when ventilation is performed through a window, a problem occurs that contaminants such as fine dust contained in outdoor air flow into the room as it is, and interest in a ventilation device to which a filter is added is also increasing.

However, there is a disadvantage in that the efficiency of the heat exchanger is reduced due to a large temperature difference between indoor air and outdoor air passing through, and in particular, there is a problem in that the efficiency decreases due to condensation caused by humidity. Republic of Korea Patent No. 1105995 has applied a method of reducing the temperature difference by using a bypass flow passage that partially mixes indoor air and outdoor air using a bypass flow passage.

However, the conventional technology of passing through the heat exchanger unconditionally in the process of discharging indoor air and inflow of outdoor air inevitably reduces the efficiency of ventilation and has a disadvantage in that it is not possible to solve the performance degradation due to the dew condensation generated in the heat exchanger.

Republic of Korea Patent No. 1105995

The present invention has been made to solve the above-mentioned problems of the prior art, and an object of the present invention is to provide an indoor ventilation device with less performance degradation of a heat exchanger.

Indoor ventilation device according to the present invention for achieving the above object, the housing; A main partition wall disposed inside the housing and separating an indoor air discharge line in which an indoor inlet and an outdoor discharge port communicate with each other and an outdoor air inlet line in which the outdoor inlet port and the indoor discharge port communicate with each other; A first blowing fan installed in the indoor air discharge line for forcibly moving air in one direction; A second blower fan installed in the outdoor air inlet line and forcibly moving air in one direction; An electrothermal heat exchanger installed on both the indoor air discharge line and the outdoor air inlet line; And a filter unit installed at the outdoor air inlet line to purify the air. The heat exchanger is rotated by a motor, so that the air flows into the heat exchanger from the indoor air discharge line and the outdoor air inlet line. In the air passing position is characterized in that it can be changed.

At this time, it is preferable that the heat exchanger is formed in a cylindrical shape and rotates with respect to the center of the cylinder so that the curved position of the cylinder into which the air flows into the heat exchanger in the indoor air discharge line and the outdoor air inlet line is changed.

In addition, the center of the cylinder is formed in an empty shape, there is an advantage that can reduce the raw material costs by leaving the middle portion of the air does not pass.

The total heat exchanger occupies only a part of the cross section of the indoor air discharge line, and the remaining part of the cross section of the indoor air discharge line is blocked by a first auxiliary bulkhead that prevents the flow of air, and the first auxiliary bulkhead selectively opens and closes. The auxiliary opening and closing is formed, it is preferable to be able to control whether the air passing through the indoor air discharge line passes through the heat exchanger by opening and closing the first auxiliary opening and closing.

The total heat exchanger occupies only a portion of the cross section of the outdoor air inflow line, and the remaining portion of the cross section of the outdoor air inflow line is blocked by a second auxiliary bulkhead that blocks the flow of air, and the second auxiliary bulkhead is selectively opened and closed. The auxiliary opening and closing is formed, it is preferable to be able to control whether the air passing through the outdoor air inlet line passes through the heat exchanger by opening and closing the second auxiliary opening and closing.

All the air passing through the indoor air discharge line and the outdoor air inlet line does not pass through the heat exchanger, but controls the passage of the heat exchanger by adjusting the first auxiliary opening and the second auxiliary opening and closing opening.

The internal circulation switchgear is formed in the main bulkhead so that the air flowing into the indoor air discharge line through the indoor inlet port moves to the outdoor air inlet line and is discharged to the indoor exhaust port, but the internal circulation switch is moved to the outdoor air inlet line. It is possible to purify the indoor air by the filter unit by placing the filter unit in a place where it passes through the filter unit to be discharged to the indoor outlet.

In the housing, it is preferable that a toilet inlet for introducing air in the toilet to the indoor air discharge line is formed separately.

At this time, a third auxiliary bulkhead is installed in the indoor air discharge line and further includes a third auxiliary bulkhead for preventing the air inside the bathroom flowing into the bathroom inlet from reaching the heat exchanger, and the third auxiliary bulkhead can be selectively opened and closed. Is formed, it is preferable to open the third auxiliary opening and closing only when passing the indoor air other than the air inside the toilet through the heat exchanger.

According to the present invention configured as described above, by applying a pre-heat exchanger that rotates the position where the air is introduced and the air passing through, the air passes only to a predetermined position of the pre-heat exchanger does not cause a problem that the heat exchange efficiency of the portion is lowered In addition, there is an effect that can prevent problems caused by condensation generated in the total heat exchanger.

1 is a view showing the structure of an indoor ventilation device according to a first embodiment of the present invention.
2 and 3 are views showing a state in which the indoor ventilation device according to the first embodiment of the present invention to vent the indoor and outdoor air.
4 is a view showing the indoor ventilation device purifies the indoor air according to the first embodiment of the present invention.
5 is a view showing the structure of an indoor ventilation device according to a second embodiment of the present invention.

With reference to the accompanying drawings will be described embodiments of the present invention;

1 is a view showing the structure of an indoor ventilation device according to a first embodiment of the present invention.

The indoor ventilation device of the present embodiment has a main bulkhead 110 in the interior of the housing 100, and the indoor air discharge line and the outdoor inlet 140, which communicate with the indoor inlet 120 and the outdoor outlet 130, communicate with the indoor. The outdoor air inflow line through which the outlet 150 is communicated is located separately.

The first blower fan 210 and the second blower fan 220 are installed in front of the outdoor outlet 130 of the indoor air discharge line and the indoor outlet 150 of the outdoor air inlet line, respectively. In this embodiment, a blower fan is installed in front of the outlet for efficiency of the blower fan, but is not limited thereto.

In the present embodiment, the heat exchanger 300 is positioned to span both the indoor air discharge line and the outdoor air inflow line separated by the main partition wall 110. Although not shown, the heat exchanger 300 is configured to be rotatable by a motor, and by rotating the heat exchanger 300, air is introduced into the heat exchanger 300 from the indoor air discharge line and the outdoor air inflow line. It is possible to continuously change the position where the air passes inside the heat exchanger (300).

As such, by applying the pre-heat exchanger 300 is rotated by changing the position where the air is introduced and the passing position, the air passes only to a predetermined position of the pre-heat exchanger does not cause a problem that the heat exchange efficiency of the portion is lowered.

In addition, even if condensation occurs in the total heat exchanger due to the temperature difference and humidity, the heat exchanger 300 rotates, thereby performing heat exchange to a portion where condensation does not occur, instead of condensation. You can solve the problem.

In addition, the condensation occurs in the portion can be quickly eliminated by the rotation of the condensation effect.

In order to increase the efficiency of the rotary heat exchanger 300, in this embodiment, a cylindrical heat exchanger 300 is applied. More specifically, by applying a donut-shaped cross-section heat exchanger 300, the indoor air discharge line and the outdoor air inlet line is separated from the main partition wall 110 by emptying the intermediate portion that is not used for heat exchange to reduce the raw material ratio There is a saving effect. At this time, the total heat exchanger 300 may be configured by a total heat exchange method of asbestos, aluminum, nylon, etc. laminated in a honeycomb shape, but is not limited thereto.

Indoor ventilation device of the present embodiment, the filter unit 400 for removing the contaminants contained in the air introduced from the outside is provided in the outdoor air inlet line. The filter unit 400 uses a triple filter that overlaps a plurality of filters to include one or more HEPA filters and one or more prefilters. In this embodiment, in order to prevent contamination of the heat exchanger 300, the filter unit 400 is located between the heat exchanger 300 and the outdoor inlet 140, the outdoor air introduced into the outdoor inlet 140 The filter unit 400 was configured to reach the total heat exchanger 300.

The indoor ventilation device of the present embodiment is configured such that the total heat exchanger 300 does not block the entire air passage of the indoor air discharge line and the outdoor air inflow line, but blocks only a part of the cross section of the air passage, while the first auxiliary bulkheads are respectively disposed on the remaining passage cross sections. The first auxiliary opening and closing 162 and the second auxiliary opening and closing opening 162 and the second auxiliary opening and closing opening 172 which can selectively open and close the air by forming the second auxiliary partition wall 170 and the second auxiliary partition wall 170 are formed. It was formed in each of the second auxiliary partition wall (170). By this structure, not all the air passing through the indoor air discharge line and the outdoor air inlet line passes through the heat exchanger 300, and the first heat exchanger 300, when the first auxiliary switch 162 is opened, has a slow air flow. When the indoor air moves through the indoor air discharge line through the first auxiliary opening and closing 162, and the first auxiliary opening and closing 162 is closed, the indoor air blocked by the first auxiliary partition wall 160 is a heat exchanger. The indoor air discharge line moves through 300. Similarly, when the second auxiliary switchgear 172 is opened, outdoor air moves to the outdoor air inflow line through the second auxiliary switchgear 172 rather than the heat exchanger 300 in which air flows slowly, and the second auxiliary switchgear is opened. When 172 is closed, outdoor air blocked by the second auxiliary partition wall 170 moves through the heat exchanger 300 to the outdoor air inflow line.

On the other hand, the indoor ventilation device of the present embodiment, the inner circulation opening and closing 112 that can be selectively opened and closed on the main partition wall 110, and when the internal circulation opening and closing 112 is opened, the indoor inlet 120 is opened. After the indoor air introduced into the indoor air discharge line is introduced into the outdoor air inflow line through the internal circulation opening and closing 112, the indoor air is circulated back through the indoor exhaust port 150. At this time, by installing the position of the internal circulation opening and closing 112 to the rear of the filter unit 400, the air circulated internally is configured to pass through the filter unit 400, to clean the inside without discharging the indoor air to the outside It is possible to perform the air clean mode operation.

In addition, the housing 100 has a toilet inlet 122 is connected to the indoor air discharge line, so that the internal air of the toilet requiring a separate ventilation due to the smell and moisture, etc. can be separately introduced and discharged. At this time, the toilet inlet 122 is positioned between the first auxiliary partition wall 160 and the outdoor discharge port 130, so that the air inflowing from the toilet can be discharged directly along the outdoor discharge port 130.

Hereinafter, the function of each component of the indoor ventilation device will be further described through a specific driving method of the indoor ventilation device according to the above embodiment.

2 and 3 are views illustrating a state in which the indoor ventilation device according to the first embodiment of the present invention vents indoor and outdoor air.

FIG. 2 shows the ventilation performed using the total heat exchanger for energy saving, and FIG. 3 shows the ventilation performed without the total heat exchanger for quick ventilation.

Ventilation, which is a main function of the indoor ventilation device of the present embodiment, discharges indoor air to the outside and introduces outdoor air into the room. Such ventilation is performed by operating the first blowing fan 210 and the second blowing fan 220. Is performed.

The indoor air flows into the indoor inlet 120 by the first blowing fan 210 and moves to the indoor air discharge line discharged from the outdoor outlet 130 to the outside, and the outdoor air is blown out by the second blowing fan 220. Air flows into the outdoor inlet 140 and moves from the indoor outlet 150 to the outdoor air inlet line.

In this case, when the first auxiliary opening and closing 162 and the second auxiliary opening and closing 172 are closed, as shown in FIG. 2, air moves through the heat exchanger 300 in both the indoor air discharge line and the outdoor air inlet line. do. This driving method can be called an ECO ventilation mode that can save heating and cooling energy. At this time, as described above, by rotating the heat exchanger 300, the air flows in the indoor air discharge line and the outdoor air inlet line and the position where the air passes in the heat exchanger 300 inside the surface and the heat exchanger (300). Continuously changing, the problem caused by condensation and efficiency degradation of the total heat exchanger (300) does not occur.

On the other hand, in the case of opening the first auxiliary opening and closing 162 and the second auxiliary opening and closing 172, as shown in FIG. 3, the first auxiliary opening and closing 162 and the first auxiliary opening and closing of the air flow is slowed. 2 The air moves through the auxiliary opening and closing 172. This driving method can be called a fast ventilation mode that can quickly ventilate the air. In the case where the heat exchange is not necessary because the temperature difference between the indoor and outdoor is not large, it is common to perform the ventilation as shown in FIG. 3, but even if the ventilation is required faster than the problem of loss of thermal energy, the fast heat exchanger as shown in FIG. Ventilation can be performed.

In all cases, the outdoor air introduced into the outdoor inlet 140 is introduced into the room in a purified state through the filter unit 400.

Meanwhile, FIG. 2 illustrates a case in which the air moves through the heat exchanger 300 in both the indoor air discharge line and the outdoor air inflow line, but is not limited thereto. For example, it is also possible to configure or operate only the outdoor air inflow line that causes a large amount of energy loss to pass through the heat exchanger (300).

4 is a view showing the indoor ventilation device purifies the indoor air according to the first embodiment of the present invention.

As described above, the indoor ventilation device of the present embodiment may perform an air cleaning mode for purifying indoor air. By opening and closing the internal circulation opening 112, the indoor air is discharged back into the room after passing through the filter unit 400 by turning the interior of the indoor ventilation device. At this time, the outdoor outlet 130 and the outdoor inlet 140 should be closed for efficiency, and in order to prevent backflow of efficiency and odor in the construction of an indoor ventilation device, the indoor inlet 120 and the outdoor outlet 130, the outdoor inlet 140 and the indoor outlet 150 may be configured to selectively open and close, so that these can be used.

At this time, since the air cleaning mode is to circulate the air in the room, it corresponds to a case where there is no problem of energy loss, and it will be common to operate by opening both the first auxiliary opening and closing 162 and the second auxiliary opening and closing 172.

5 is a view showing the structure of an indoor ventilation device according to a second embodiment of the present invention.

The indoor ventilation device of the second embodiment is the same in most configurations as the first embodiment described above. However, in addition to the first auxiliary bulkhead 160 in the indoor air discharge line, the third auxiliary bulkhead 180 and the third auxiliary installed therein prevent the toilet air introduced from the bathroom inlet 122 from being closed in the heat exchanger 300. There is a difference in that the opening and closing port 182 is added. Since the rest of the configuration is the same as the indoor ventilation device of the first embodiment, a detailed description thereof will be omitted.

In the indoor ventilation device according to the second embodiment, in the process of directly discharging the toilet air through the toilet inlet 122, by closing the third auxiliary opening and closing 182, a lot of moisture by the third auxiliary bulkhead 180. The toilet air may be prevented from contacting the total heat exchanger 300, and thus, the life of the total heat exchanger 300 may be further increased.

However, when the ventilation is performed in the form shown in FIG. 2, the air introduced from the room is discharged to the outside through the heat exchanger 300 only when the third auxiliary opening 182 is opened.

While the present invention has been described through the preferred embodiments, the above-described embodiments are merely illustrative of the technical idea of the present invention, and various changes may be made without departing from the technical idea of the present invention. Those of ordinary skill will understand. Therefore, the protection scope of the present invention should be interpreted not by the specific embodiments, but by the matters described in the claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

100: housing 110: main bulkhead
112: internal circulation opening and closing 120: indoor inlet
122: toilet inlet 130: outdoor outlet
140: outdoor inlet 150: indoor outlet
160: first auxiliary bulkhead 162: first auxiliary opening and closing
170: second secondary bulkhead 172: second secondary opening and closing
180: third secondary bulkhead 182: third secondary opening and closing
210: first blowing fan 220: second blowing fan
300: total heat exchanger 400: filter portion

Claims (8)

housing;
A main partition wall disposed inside the housing and separating an indoor air discharge line in which an indoor inlet and an outdoor discharge port communicate with each other and an outdoor air inlet line in which the outdoor inlet port and the indoor discharge port communicate with each other;
A first blowing fan installed in the indoor air discharge line for forcibly moving air in one direction;
A second blower fan installed in the outdoor air inlet line and forcibly moving air in one direction;
An electrothermal heat exchanger installed on both the indoor air discharge line and the outdoor air inlet line; And
Installed in the outdoor air inlet line includes a filter for purifying the air,
The electrothermal heat exchanger is rotated by a motor, the indoor air discharge line and the indoor air inlet line, characterized in that the air flows in the heat exchanger and the surface where the air flows into the heat exchanger can be changed.
The method according to claim 1,
The total heat exchanger is formed in a cylindrical shape, rotated about the center of the cylinder,
An indoor ventilation device, characterized in that the curved position of the cylinder into which the air enters the heat exchanger in the indoor air discharge line and the outdoor air inlet line is changed.
The method according to claim 2,
The heat exchanger is an indoor ventilation device, characterized in that the center of the cylinder is hollow shape.
The method according to claim 1,
The heat exchanger occupies only a part of the cross section of the indoor air discharge line, and the remaining part of the cross section of the indoor air discharge line is blocked by a first auxiliary partition wall that blocks the flow of air.
A first auxiliary opening and closing which can be selectively opened and closed is formed in the first auxiliary bulkhead, and by opening and closing the first auxiliary opening and closing, the air passing through the indoor air discharge line passes through the heat exchanger. Indoor ventilation system.
The method according to claim 1,
The total heat exchanger occupies only a part of the cross section of the outdoor air inlet line, and the remaining part of the cross section of the outdoor air inlet line is blocked by a second auxiliary partition wall that blocks the flow of air.
A second auxiliary opening and closing which can be selectively opened and closed is formed in the second auxiliary bulkhead, and by opening and closing the second auxiliary opening and closing, the air passing through the outdoor air inflow line passes through the heat exchanger. Indoor ventilation system.
The method according to claim 1,
An air circulation opening and closing port is formed in the main bulkhead to allow the air introduced into the indoor air discharge line through the indoor inlet to be discharged to the indoor air outlet by moving to the outdoor air inlet line.
The position of the internal circulation opening and closing, the indoor ventilation device, characterized in that the air moved to the outdoor air inlet line passes through the filter unit to be discharged to the indoor outlet.
The method according to claim 1,
The housing ventilator characterized in that the toilet inlet for introducing the air in the toilet to the indoor air discharge line formed.
The method according to claim 7,
A third auxiliary partition wall installed at an indoor air discharge line to prevent the air inside the bathroom introduced into the bathroom inlet from reaching the heat exchanger;
A third auxiliary opening and closing is formed on the third auxiliary bulkhead to be opened and closed selectively, and the third auxiliary opening and closing is opened only when the indoor air other than the air inside the toilet is passed through the heat exchanger. .

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