KR101193222B1 - Ventilation system - Google Patents

Abstract

PURPOSE: A ventilation system is provided to prevent dew condensation by reducing temperature difference between indoor space and outdoor space. CONSTITUTION: A ventilation system comprises a supply duct(110), a discharge duct(120), a total-heat exchanger(130), a first damper(210), and a second damper(220). An elastic member is attached to the supply duct or the discharge duct for air tightness. The total-heat exchanger is installed in the cross portion of the supply duct and the discharge duct. The first damper is installed for controlling air inflow. The second damper is installed for controlling air outflow.

Description

Ventilation system

The present invention relates to a ventilation system, and more particularly, when the heat exchanger does not operate, by installing a damper to block outside air from entering the interior of the duct connecting the outdoor and the heat exchanger to prevent condensation from occurring inside the duct. To a ventilation system to avoid.

In general, indoors such as homes and offices are kept in a closed state to improve cooling and heating efficiency, and the sealed indoor spaces cause air pollution to increase after a certain period of time. Foreign matter becomes rich.

Therefore, in order to remove such odors and dust in the room to ventilate the room air every predetermined time, the ventilation device is used for more rapid ventilation.

Such a ventilator is usually installed on the ceiling surface of the room, and the ventilator is formed with an outdoor air inlet and an indoor air outlet on the outdoor side of the body, and an indoor air inlet and an outdoor air outlet are formed on the indoor side of the body.

The inside of the ventilator is provided with an air supply blower for forcibly blowing the outdoor air to be supplied to the indoor side, and an exhaust air blower for forcibly blowing the exhausted indoor air to the outdoor side. It is provided with a total heat exchanger for recovering the heat of the exhaust heat of the indoor air and heat transfer to the outdoor air to be supplied.

According to Korean Utility Model Publication No. 20-2010-0010459 (published on Oct. 25, 2010), the conventional ventilation system uses outdoor air intake and indoor air outlet formed on the outdoor side of the ventilation body when the ventilation device is inactive. A damper is separately installed outside the ventilator to prevent water from entering the room. By installing such a damper, it is possible to prevent a poor ventilation caused when the outdoor air flows back to the ventilation device.

However, when the ventilation device does not operate in the conventional ventilation device as described above, outdoor air flows into the duct connecting the ventilation device to the outside, and in the summer or winter season, the indoor air flows in accordance with the difference between the indoor temperature and the outdoor temperature. Due to condensation, water is generated, and there is a problem such that the generated water is introduced into the room.

The present invention for solving the conventional problems as described above, when the heat exchanger does not operate, by sealing the air tightly so that the outside air does not flow into the interior of the duct connecting the outdoor heat exchanger to reduce the temperature difference between the room temperature and the inside of the duct The aim is to provide a ventilation system that prevents condensation from occurring inside the duct.

The present invention for achieving the above object is an air supply duct for guiding the outdoor air indoors, the air supply duct intersects at a predetermined position, and the exhaust duct for guiding the indoor air to the outside and the air supply duct and the exhaust duct is crossed And an electric heat exchanger in which the temperature of the indoor air exhausted and the outdoor air supplied to the branch is exchanged, and the air supply duct is provided with a first damper to control the inflow of outdoor air at a point adjacent to the air supply inlet communicating with the outdoor. In addition, the exhaust duct provides a ventilation system for installing a second damper to control the discharge of the indoor air at a point adjacent to the exhaust outlet in communication with the outdoors.

In addition, the first damper or the second damper is a butterfly valve, the rotation axis of the drive motor is connected to the central axis of the disc of the butterfly valve, the disc is rotated in conjunction with the drive motor supply duct or exhaust duct Provide a ventilation system with controlled opening and closing rates.

In addition, the inner circumferential surface of the air supply duct or the exhaust duct provides a ventilation system having a sealing member of a flexible material including window paper for securing airtightness with the disc.

In addition, the one or both surfaces of the disc provides a ventilation system is attached to the windproof member including a window paper to ensure the insulation.

The ventilation system may further include a controller connected to a controller for controlling the operation of the heat exchanger and outputting an open / close signal to the first damper or the second damper according to an on / off operation signal of the heat exchanger. To provide.

The present invention also provides a ventilation system including a sensor for detecting whether the first damper or the second damper is opened or closed, and a notification unit which displays an open / closed state of the first damper or the second damper according to a detection signal of the sensor. .

According to the present invention as described above, when the heat exchanger does not operate, by blocking the air tightly to prevent the outside air flow into the interior of the duct connecting the outdoor and the heat exchanger by reducing the temperature difference between the indoor temperature and the inside of the duct condensation inside the duct There is an effect that the phenomenon does not occur.

In addition, the sealing member is attached so that the damper is more airtight between the duct and the damper when the damper is closed, thereby completely preventing the outdoor air from flowing into the duct. There is an effect that can be kept higher than the temperature.

In addition, since the damper is automatically opened and closed depending on whether the heat exchanger is operated in conjunction with the heat exchanger, it is efficient in terms of energy use because it is operated only during ventilation and hassle-free operation of the damper separately. As soon as it is confirmed, it is possible to respond quickly to malfunctions.

1 is a block diagram showing an embodiment of a ventilation system according to the present invention,
Figure 2 is a perspective view showing a shielded state of the damper and the duct according to the present invention,
3 is a perspective view showing an open state of a damper and a duct according to the present invention;
4 to 5 is a longitudinal sectional view showing a shielded state of the damper and the duct according to the present invention,
Figure 6 is a block diagram showing another embodiment of the ventilation system according to the present invention.

Hereinafter, the configuration and operation of the ventilation system of the present invention according to the accompanying drawings in more detail.

1 is a block diagram showing an embodiment of a ventilation system according to the present invention. As shown in FIG. 1, the ventilation system according to the present invention has an air supply duct 110 for guiding outdoor air to an interior, and an air exhaust duct crossing the air supply duct 110 at a predetermined position and guiding the indoor air to an outdoor location. And a heat exchanger (130) installed at a point where the duct 120 and the air supply duct 110 and the exhaust duct 120 intersect to exchange the temperature of the outdoor air that is supplied with the air and the indoor air that is exhausted. 110 installs a first damper 210 to control the inflow of outdoor air at a point adjacent to the air supply inlet 111 in communication with the outdoor, the exhaust duct 120 is an exhaust outlet 121 in communication with the outdoor It is configured to install a second damper 220 to control the discharge of indoor air at a point adjacent to the.

First, the heat exchanger 130 is installed at the point where the air supply duct 110 and the exhaust duct 120 intersect, and the heat exchange between the outdoor air that is supplied and the indoor air that is exhausted proceeds to generate heat energy of the indoor air that is exhausted. It acts to allow the air to be supplied to be absorbed into the room by absorbing outdoor air. The heat exchanger (130) is usually formed with a first inlet through which indoor air is introduced and a first outlet through which the heat exchange is completed is exhausted into the exhaust duct (120), where the outdoor air of the air supply duct (110) is introduced. The second inlet is formed with a second outlet for supplying the indoor air with heat exchange complete with heat exchange. Each of the first and second inlets and the first and second outlets is provided with an opening / closing damper which regulates the entry and exit of air. In addition, an exhaust fan that sucks indoor air and discharges it to the outside and an air supply fan that sucks outdoor air and supplies it to the room are mounted. Ventilation proceeds through the fan, and when the ventilation is in progress, the indoor air and the outdoor air cross each other in the heat exchanger 130, and the temperatures are exchanged with each other.

The air supply duct 110 connects the air supply inlet 111 and the second inlet of the heat exchanger 130 communicated with the outdoors, and the exhaust duct 120 connects the first outlet and the exhaust outlet of the heat exchanger 130. Connect (121).

The first damper 210 is installed inside the air supply duct 110 and installed at a point adjacent to the air supply inlet 111, that is, at a point adjacent to the outdoor side, so that outdoor air flows into the air supply duct 110. Enforce. The second damper 220 is installed inside the exhaust duct 120, and is installed at a point adjacent to the exhaust outlet 121, that is, at a point adjacent to the outdoor side, so that outdoor air flows into the exhaust duct 120. Enforce.

The first damper 210 and the second damper 220 are opened only when the dampers that are shielding each entrance and exit of the heat exchanger 130 while the heat exchanger 130 is operated and are ventilated to open inflow of outdoor air. And the discharge of indoor air, and on the contrary, as the heat exchanger 130 is stopped, the dampers used to open the entrances and exits of the heat exchanger 130 are shielded, and when the ventilation is not in progress, the outdoor air is ducted. It blocks the flow into the 110 and the exhaust duct 120. For reference, the first damper 210 and the second damper 220 may be installed not only in the air supply duct 110 and the exhaust duct 120, but also in the air supply inlet 111 and the exhaust outlet 121. Various opening and closing means known in the art, including a method, a rotation method can be applied.

In addition, in the present invention, the air supply duct 110 and the exhaust duct 120 has been described in the communication structure with the outside separately through the air supply inlet 111 and the exhaust outlet 121, respectively, the air supply duct ( When the 110 and the exhaust duct 120 communicate with the outside through a single entrance, and the entrance, the air supply duct 110 and the exhaust duct 120 is separated from one duct, the duct connected to the entrance It is preferable that one damper is installed in the integrated management of the air supply and the exhaust.

According to the present invention as described above, when the heat exchanger 130 does not operate, it can be airtightly blocked so that outside air does not flow into the duct (110, 120) connecting the outdoor and the heat exchanger 130, In the summer or winter, the temperature difference between the indoor temperature and the ducts 110 and 120 can be reduced, and thus, condensation does not occur in the ducts 110 and 120.

On the other hand, Figure 2 is a perspective view showing a shielded state of the damper and the duct according to the present invention, Figure 3 is a perspective view showing an open state of the damper and the duct according to the present invention. According to another aspect of the present invention as shown in Figures 2 to 3, the first damper 210 or the second damper 220 is a butterfly valve, the rotating shaft 204 of the drive motor 203 is The opening and closing degree of the air supply duct 110 or the exhaust duct 120 is connected to the central axis 202 of the disc 201 of the butterfly valve, and the disc 201 rotates in association with the drive motor 203. Is adjusted.

Since the air supply duct 110 or the exhaust duct 120 usually takes the form of a circular pipe, the air supply duct 110 or the exhaust duct 120 may be used to shield the inside of the air supply duct 110 or the exhaust duct 120. A butterfly valve in the form of a disc 201 corresponding to the inner cross-section of the shell should be installed. The disc 201 rotates in an electric manner, and the central axis 202 of the disc 201 is connected to the rotation shaft 204 of the drive motor 203. The drive motor 203 can be rotated in both directions. When the first damper 210 or the second damper 220 is to be opened, the driving motor 203 rotates the original plate 201 by 90 ° in the forward direction, and the first damper 210 or the second damper ( When shielding 220, the original plate 201 is rotated 90 degrees in the reverse direction to return to the original position. In addition, according to the degree of rotation of the drive motor 203, the rotation angle of the first damper 210 or the second damper 220 is adjusted, and eventually the opening and closing of the air supply duct 110 or the exhaust duct 120 The degree is adjusted. In the present invention, the air supply duct 110 or the exhaust duct 120 has been described by way of example in the form of a circular pipe, the air supply duct 110 or the exhaust duct 120 may be made of a pipe having a variety of shapes, including a square. The air supply duct 110 or the exhaust duct 120 and the first damper 210 or the second damper 220 may be connected by separate connectors.

4 to 5 are longitudinal cross-sectional views showing the shielding state of the damper and the duct according to the present invention. Referring to the drawings, the inner circumferential surface of the air supply duct 110 or the exhaust duct 120 sealing the elastic material to ensure the airtightness with the disc 201 of the first damper 210 or the second damper 220 The member 300 is attached. The sealing member 300 is a state in which the first damper 210 or the second damper 220 shields the air supply duct 110 or the exhaust duct 120, the air supply duct 110 and the first damper 210. By blocking the gap between the original plate 201, the exhaust duct 120 and the original plate 201 of the second damper 220 is attached to prevent any outdoor air from flowing through the minute gap. The sealing member 300 may be formed of various materials such as paper and tape-type wind paper, including various elastic materials such as rubber, silicon, sponge, etc., and the first damper 210 or the second damper 220 is installed. It is attached to the point along the inner circumferential surface of the air supply duct 110 or the exhaust duct 120. Meanwhile, the first damper 210 or the second damper 220 opens and closes the air supply duct 110 or the exhaust duct 120 while rotating the original plate 201 by 90 ° in the forward and reverse directions. When the sealing member 300 is attached in the opposite direction in which the 201 is rotated, the sealing member 300 is intimately connected between the disc 201 and the inner surface of the air supply duct 110 or the exhaust duct 120 without interfering with the rotation of the disc 201. Can be shielded.

According to another aspect of the present invention, the windproof member 400 is attached to one or both surfaces of the disc 201 of the first damper 210 or the second damper 220 to ensure insulation. The windproof member 400 is attached to one side or both sides of the disc 201, and when attached to one side, attaching the windproof member 400 to a surface facing the outdoor. The windproof member 400 may be made of a variety of materials excellent in windproof and warmth, including vinyl, foamable resin. Therefore, in summer, the internal temperature of the air supply duct 110 or the exhaust duct 120 is kept lower than the outdoor temperature, and the temperature difference between the indoor temperature and the ducts 110 and 120 can be reduced to prevent condensation. In winter, the internal temperature of the air supply duct 110 or the exhaust duct 120 is maintained higher than the outdoor temperature, and the temperature difference between the indoor temperature and the ducts 110 and 120 can be reduced to prevent condensation. Can be.

According to another aspect of the present invention, the sealing member 300 or the windproof member 400 is provided with various branches including window paper. The window paper has a thin thickness, excellent windproof ability, and has a tough property not to be torn even with frequent friction, so when the window paper is provided with the sealing member 300 and the windproof member 400, the disc 201 and the air supply duct 110 are provided. Alternatively, the inner surface of the exhaust duct 120 may be more closely shielded, and the outdoor air introduced through the air supply inlet 111 and the air exhaust port 121 may be connected to the first damper 210 or the second damper 220. Strong windproof is achieved to prevent passage, and the thermal insulation inside the ducts 110 and 120 is strengthened, so that the internal temperature of the ducts 110 and 120 can be kept lower than the outdoor temperature in the summer, and high in the winter. There is this.

6 is a configuration diagram showing another embodiment of the ventilation system according to the present invention. According to another aspect of the present invention, the first damper 210 is connected in circuit with the controller 140 for controlling the operation of the heat exchanger 130 in accordance with the on-off operation signal of the heat exchanger (130). Or a control unit 230 for outputting an open / close signal to the second damper 220.

The controller 140 that controls the operation of the heat exchanger 130 is usually operated in connection with the wired remote controller 150 disposed indoors. In this case, the signal input from the remote controller 150 is input not only to the controller 140 but also to the controller 230 so that the first damper 210 or the second damper 220 is automatically opened and closed according to the signal. Can be. For example, the residents who feel the need for ventilation operate the ventilation system through the remote controller 150 arranged indoors. In this case, the input signal is input to the controller 140 of the total heat exchanger 130, and the controller 140 opens the dampers that shield each entrance and exit of the total heat exchanger 130, and drives a fan to perform ventilation. To help. At this time, the control unit 230 is connected to the controller 140 circuitry is the first damper 210 and the second damper that is shielding the air supply duct 110 and the exhaust duct 120 at the same time the heat exchanger 130 is driven. The driving motor 203 of the 220 is operated for a predetermined time to open the air supply duct 110 or the exhaust duct 120. On the contrary, if the controller 140 shields the dampers that open the respective entrances and exits of the heat exchanger 130, and the ventilation is not performed by stopping the driving of the fan, the controller 230 is connected to the controller 140. While the driving of the total heat exchanger 130 is stopped and at the same time, the driving motor 203 of the first damper 210 and the second damper 220 which open the air supply duct 110 and the exhaust duct 120 are fixed in the opposite direction. The air supply duct 110 or the exhaust duct 120 is shielded by driving for a time.

According to another aspect of the present invention, the first damper 210 according to the sensor 500 and the detection signal of the sensor 500 to detect whether the first damper 210 or the second damper 220 is opened or closed. Or a notification unit 600 which displays the open / closed state of the second damper 220 to the outside.

The sensor 500 is installed inside the air supply duct 110 or the exhaust duct 120, and includes a wind speed sensor for detecting the inflow of outdoor air, as well as the first damper 210 or the second damper 220 and the air supply duct. The pressure sensor and the proximity sensor mounted on the 110 or the exhaust duct 120 to detect whether the first damper 210 and the air supply duct 110 or the second damper 220 and the exhaust duct 120 are firmly in contact with each other. It is provided to detect whether the first damper 210 or the second damper 220 is opened or closed. The notification unit 600 displays an open / closed state of the first damper 210 or the second damper 220 to the outside according to the detection signal of the sensor 500, and the remote controller 150 disposed at the indoor side. Open / close state can be displayed on the screen, and it can be displayed as a separate warning light to the outside by the color or blinking of the warning light.

As described above, since the dampers 210 and 220 are interlocked with the total heat exchanger 130 and operate the total heat exchanger 130, the dampers 210 and 220 need to be operated separately, and there is no need to operate the dampers 210 and 220 separately. Since it is only operated in terms of energy use, it is efficient in terms of operation, and each damper (210, 220) can be immediately confirmed when the operation error has the advantage that can respond quickly to malfunctions.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art to which the present invention pertains without departing from the spirit and scope of the present invention as set forth in the claims below It will be readily understood that modifications and variations are possible.

110: air supply duct 111: air supply intake
120: exhaust duct 121: exhaust outlet
130: heat exchanger 140: controller
150: remote control 201: negative
202: central axis 203: drive motor
204: axis of rotation 210: first damper
220: second damper 230: control unit
300: sealing member 400: windproof member
500: sensor 600: notification unit

Claims (7)

An air supply duct for guiding outdoor air to the interior, an exhaust duct intersecting the air supply duct at a predetermined position to guide the indoor air to the outside, and an outdoor air and exhaust air installed at an intersection point of the air supply duct and the exhaust duct An electric heat exchanger in which the temperature of indoor air is exchanged, the air supply duct is provided with a first damper installed to control the inflow of outdoor air at a point adjacent to the air supply inlet communicated with the outside, and the exhaust duct is provided with an exhaust outlet communicating with the outside. A ventilation system comprising a second damper installed to control the discharge of indoor air at an adjacent point,
The first damper or the second damper is a butterfly valve, the rotation axis of the drive motor is connected to the central axis of the disc of the butterfly valve, the disc is rotated in conjunction with the drive motor to open and close the air supply duct or exhaust duct The degree is adjusted, the inner circumferential surface of the air supply duct or the exhaust duct is attached to the sealing member of the elastic material for ensuring the airtightness with the disc, and the windproof member is attached to one side or both sides of the disc to secure the heat insulation Ventilation system. delete delete delete The method of claim 1,
Ventilation system, characterized in that the sealing member or the windproof member is provided with a window paper. The method of claim 1,
And a controller connected to a controller for controlling the operation of the heat exchanger and outputting an open / close signal to the first damper or the second damper according to an on-off operation signal of the heat exchanger. Ventilation system. The method of claim 1,
A sensor for detecting whether the first damper or the second damper is opened or closed;
And a notification unit for displaying the open / closed state of the first damper or the second damper to the outside according to the detection signal of the sensor.

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