KR102079211B1 - A Ventilator - Google Patents

Abstract

The present invention relates to a total heat exchanger for ventilating indoor air and, more specifically, to a total heat exchanger having a large-capacity filter for causing air to flow to a lower portion, comprising: a total heat exchange portion having a heat exchange element; a filter portion provided on a lower portion of the total heat exchange portion; and first and second air flow chamber portions respectively provided on a side surface portion and a lower surface portion of the filter portion. The filter portion is composed of a filter unit and a lower chamber and an upper chamber on upper and lower sides thereof. The total heat exchange portion and the filter portion are separately operated so that the capacity of the filter is enlarged and the indoor air is allowed to flow through the second air flow chamber portion. The filter is mounted and detached so that the ventilation performance of the total heat exchanger is improved as well as the replacement of the filter is easy, thereby significantly increasing ventilation efficiency and convenience.

Description

Heat exchanger with large-capacity filter that allows air to flow to the bottom {A Ventilator}

The present invention relates to a total heat exchanger for ventilating indoor air, and more particularly, a first heat exchanger provided with a heat exchange element, a filter unit provided below the total heat exchanger, a first side provided at the side surface and the bottom surface of the filter unit. It consists of two air flow chamber part, the filter part is composed of the filter unit and the lower chamber and the upper chamber on the upper and lower sides thereof, and the heat exchanger and the filter part are separately operated to increase the capacity of the filter and at the same time the indoor air It is equipped with a large-capacity filter that allows air to flow through the air flow chamber and the filter is mounted and detached to improve ventilation performance of the total heat exchanger as well as to easily replace the filter, thereby greatly improving air efficiency and convenience. It relates to a total heat exchanger.

In general, the air in the closed activity space provided inside the building increases or is contaminated with carbon dioxide content over time due to the breathing or activity of the occupant, which causes many harmful effects on the inner activity or health of the occupant.

Therefore, when a person stays in a narrow space such as an enclosed space such as an office, the polluted air in the internal space should be replaced with fresh air from time to time for ventilation. In this case, a commonly used ventilator.

Most conventional ventilation apparatuses employ a method of forcibly discharging only indoor air to the outside by using one blower fan. However, when forced to discharge only the indoor air by using one blower fan, the indoor air is discharged to the outside without filtration and the outdoor air is introduced without heat exchange through the door or window gap. The cost of cooling was unnecessarily high.

In addition, sudden cold air and heat flows from the outside to the inside of the air due to the rapid change in temperature of people inside the interior uncomfortable, especially when the indoor air is discharged only when the window or door frame is closed. Oxygen deficiency may occur due to blocking the inflow of fresh air from outside, and the humidity control of the indoor air is not made at all, and there is a problem in that a pleasant indoor environment is not maintained even though a ventilation device is provided. .

In order to solve the conventional problems, when the indoor air is discharged to the outside, the heat exchange method of the ventilator of the heat exchange method for the first heat exchange with the discharged indoor air and then supplying the outdoor air has been proposed.

The total heat exchange ventilation device as described above, in the process of discharging the indoor air to the outside and at the same time supplying the outdoor air to the indoor, by exchanging them with each other between the indoor air discharged to the outside and the outdoor air flowing into the indoor Increasing the temperature of outdoor air flowing into the room, supplying air close to the indoor air.

Thus, even if the indoor air to be ventilated by the outdoor air to reduce the change in the room temperature, it is possible to minimize the increase in the load required for cooling or heating.

Looking at the general configuration of the general heat exchange ventilation system, the air supply duct is provided inside the hollow body to the outdoor air, the exhaust duct is crossed with the air supply duct at a predetermined position and the indoor air is guided to the outdoor Is provided. And an electric heat exchanger for heat-exchanging the outdoor air that is supplied at the point where the air supply duct and the exhaust duct intersect and the indoor air that is exhausted. At this time, the air supply duct and the exhaust duct are not interfered with each other by the partition wall partitioning the inside of the body up and down.

As a related art, Patent Nos. 10-1272674 and 10-2008-0024379 disclose a uniform heat flow of indoor and outdoor air to improve heat exchange efficiency.

However, since the conventional heat exchanger is installed and operated on the ceiling, there is a problem that replacement and installation of a filter (pre-filter) provided in the heat exchange element is very difficult and difficult due to the narrow space.

In addition, since the filter provided in the conventional heat exchanger is installed in the outside air supply portion of the lead exchange element, there is a limit that the size (capacity) of the filter cannot be increased due to the limitation of the installation space.

KR 10-1272674 (registration number) 2013.07.03. KR 10-2008-0024379 (publication number) 2008.03.18. KR 10-0532188 (registration number) 2005.11.23.

Accordingly, the present invention has been made to solve the above conventional problems,

The heat exchange element is provided with a heat exchange element in the ceiling of the room, the filter unit for removing dust contained in the outside air, the first air flow chamber unit in which air flows to the side of the filter unit, and the indoor air flows to the lower surface of the filter unit Install a total heat exchanger consisting of a second air flow chamber portion, and separate the heat exchange portion for exchanging outside air and a filter portion for filtering dust, the outside air flows through the first air flow chamber portion, the indoor air is second It is an object of the present invention to provide a total heat exchanger having a large-capacity filter in which air flows to the lower part which greatly improves the ventilation performance by providing a separate large-capacity filter unit at the lower side of the total heat-exchanging unit while flowing to the air flow chamber part.

Another object of the present invention is to replace the filter by providing a lower chamber and an upper chamber on the upper side and the lower side of the filter unit, respectively, and by mounting and detaching the filter unit of the filter unit provided between the upper chamber and the lower chamber. It is to provide this easy total heat exchanger.

Still another object of the present invention is to divide the first air flow chamber part provided at the side of the filter unit into the front chamber and the rear chamber so that outside air is introduced through the front chamber and bet is discharged through the rear chamber to double the ventilation efficiency. have.

Still another object of the present invention is to reduce operating costs by operating an internal clean mode in which indoor air is simply circulated back through the filter unit without passing through a heat exchange element.

The present invention for achieving the above object is a heat exchange element 111, the heat exchange is performed while the outside and the bet intersects, the air supply fan 112 for supplying air into the room, and the exhaust fan 113 for discharging the air to the outside A total heat exchange part (110) formed; The filter unit is provided in the lower portion of the heat exchange unit 110 and the upper chamber 121, the lower chamber 122, and a filter unit 123 installed between them to remove dust while the air flows up and down ( 120); A first air flow chamber unit 130 provided at a side portion of the heat exchanger unit 110 and the filter unit 120 and installed with a second damper (D2) for controlling the inflow of outside air; And a second air flow chamber part 140 provided at a lower portion of the filter unit 120 and having a plurality of perforations 141 through which indoor air flows into the bottom surface, through which air flows. The first air passage 131 through which the lower chamber 122 and the air of the filter unit 120 flow with each other, and the second air flow chamber unit 140, are provided on the side surface of the first air flow chamber unit 130. Second air passages 132 through which air flows are formed, respectively; The first air passage 131 and the second air passage 132 have different installation heights.

In addition, the filter unit 123 and the heat exchange element 111 of the present invention is formed in a quadrangle, and when viewed from the top four vertices of the heat exchange element 111 abuts the edge of the filter unit 123.

In addition, the first air flow chamber 130 of the present invention is provided with the front chamber 133 and the rear of the front chamber 133 and the outdoor air flows through the second damper (D2) is introduced into the indoor air A rear chamber 134 which flows, wherein the front chamber 133 and the rear chamber 134 are separated by a chamber split plate 135 partitioning therebetween; The first air passage 131 is provided on the lower side surface of the front chamber 133 so that the front chamber 133 and the lower chamber 122 communicate with each other, and the second air passage 132 is the rear side. The chamber 134 and the second air flow chamber 140 are provided on the lower side portion of the rear chamber 134 so as to communicate with each other.

In addition, a blocking plate 142 is provided between the lower chamber 122 and the second air flow chamber unit 140 of the present invention, and the air and the second air passage (moved from the first air passage 131 ( The air moved in 132 is not mixed with each other.

In addition, the rear chamber 134 of the present invention is branched into a passage for supplying the air introduced through the second air passage 132 to the lower chamber 122 and a passage for supplying the heat exchange unit 110. A three-way valve is provided to control the air flowing through the second air passage 132 to either the lower chamber 122 or the total heat exchange part 110.

In addition, the air supply fan 112 and the exhaust fan 113 of the present invention is provided with first and third dampers (D1, D3) for controlling the flow of air, respectively, of the first air flow chamber 130 The rear chamber 134 is provided with a fourth damper (D4) for controlling the air flow to supply to the heat exchange element 111, the air to the heat exchange element 111 on one side of the upper surface of the upper chamber 121 The fifth damper (D5) for controlling the flow is provided, the other side of the upper surface of the upper chamber 121 is opposed to the fifth damper (D5) and communicates with the air supply fan 112 to control the flow of air A sixth damper (D6) is provided, the second air flow chamber 132 through the second air flow chamber 140 in the rear chamber 134 of the first air flow chamber 130 is introduced into the second air passage (132) The seventh damper (D7) for supplying the air to the lower chamber 122 is provided, and by ventilating the outdoor air by supplying the outdoor air to the indoor The key is the general ventilation mode, the indoor air clean mode which recirculates the indoor air through the filter unit without passing through the heat exchange element, and the indoor air clean mode to cleanly ventilate the room. It is operated in any one of the bypass ventilation mode for discharging to the outside through the filter exhaust mode to remove the dust collected in the filter unit provided in the filter unit to discharge to the outside.

In the general ventilation mode of the present invention, the air supply fan 112 and the exhaust fan 113 are turned on, the sixth and seventh dampers D6 and D7 are turned off, and the first to fifth dampers ( D1 to D5 are turned on, and the outside air OA flows into the front chamber 133 of the first air flow chamber 130 through the second damper D2, and the introduced outside air is After entering the lower chamber 122 through the first air passage 131 and passing through the filter unit 123, the dust or foreign matter contained in the outside air is removed and supplied to the upper chamber 121, and the upper chamber Outside air supplied to the 121 is entered into the heat exchange element 111 through the fifth damper (D5) provided on the upper surface of the upper chamber 121 is transferred to the room through the air supply fan 112 while being heated. The indoor air flows into the second air flow chamber 140 through the perforation 141 and then the first air through the second air passage 132. After entering the inside of the rear chamber 134 of the flow chamber 130, and enters the heat exchange element 111 through the fourth damper (D4) and is transferred to the outside through the exhaust fan 113.

In the indoor air cleaning mode of the present invention, the air supply fan 112 is turned on, the exhaust fan 113 is turned off, and the third, sixth, and seventh dampers D3, D6, and D7 are turned on. The first and second dampers D1 and D2 and the fourth and fifth dampers D4 and D5 are turned off, and the indoor air flows into the second air flow chamber 140 through the perforations 141. After entering the inside of the rear chamber 134 of the first air flow chamber 130 through the second air passage 132 and again into the lower chamber 122 through the seventh damper (D7) While passing through the filter unit 123 to remove the dirt contained in the bet is supplied to the upper chamber 121, the bet supplied to the upper chamber 121, the air supply fan (6) through the sixth damper (D6) 112) and is fed back into the room.

In the bypass ventilation mode of the present invention, the air supply fan 112 and the exhaust fan 113 are turned on, and the first to fourth dampers and the sixth dampers D1 to D4 and D6 are turned on, and the fifth , 7 damper (D5, D7) is OFF, the outside air is introduced into the front chamber 133 of the first air flow chamber 130 through the second damper (D2), the introduced outside air is After entering the lower chamber 122 through the first air passage 131 and passing through the filter unit 123, the foreign matter contained in the outside air is removed and supplied to the upper chamber 121, and the upper chamber ( The outside air supplied to 121 enters the air supply fan 112 through the sixth damper D6 and is supplied into the room, and the indoor air is supplied to the second air flow chamber 140 through the perforation 141. Flows into the rear chamber 134 of the first air flow chamber 130 through the second air passage 132 and then into the fourth damper D4. It enters the heat exchange device 111 is the heat transfer is discharged to the outside through the exhaust fan 113 through.

In the filter exhaust mode of the present invention, the air supply fan 112 is turned off, the exhaust fan 113 is turned on, and the second and fifth dampers D2 and D5 are turned off. , 6, 7 dampers (D1, D3, D4, D6, D7) is ON, the air is sucked by the exhaust fan 113, the third damper (D3) and the air supply fan 112 and the first After entering the upper chamber 121 of the filter unit 120 through the 6 damper (D6) and passes through the filter unit 123 to the lower chamber 122 to the filter unit 123 The dust or debris is collected, and the bet from which the dust or the debris is detached from the rear chamber 134 of the first air flow chamber 130 through the seventh damper D7 in the lower chamber 122. After passing through the heat exchange element 111 of the heat exchange unit 110 through the fourth damper (D4) and thus the bet passing through the heat exchange element 111 bet the exhaust fan 113 It is discharged to the outside dust and debris is removed.

Electrothermal heat exchanger having a large-capacity filter in which air flows to the bottom according to the present invention is installed separately from the heat exchanger for exchanging the outside and the filter for filtering dust to filter filter size (capacity) regardless of the size of the heat exchange element, etc. Since it can be freely changed and installed in a large capacity, it is possible to effectively cope with improving the performance of the total heat exchanger.

In addition, the present invention has a first air flow chamber portion divided into a front chamber and a rear chamber so as to distinguish the inlet and the discharge of the outside air on the side of the filter unit is made efficient ventilation operation.

In addition, the present invention can further double the ventilation performance by having a second air flow chamber portion for introducing indoor air to the lower side of the filter portion.

In addition, the present invention has an advantage that the filter replacement is convenient by having an upper chamber and a lower chamber on the upper side and the lower side of the filter part, respectively, and allowing the filter unit provided between the upper chamber and the lower chamber to be attached and detached. have.

In addition, the present invention also has the advantage of reducing the cost by allowing the indoor air to operate the internal clean mode to simply circulate back to the room through the filter unit without passing through the heat exchange element.

1 is a schematic perspective state diagram of a total heat exchanger having a large-capacity filter in which air flows to the bottom according to the present invention;
2 is a schematic separated perspective view of a total heat exchanger having a large-capacity filter in which air flows to the bottom according to the present invention;
Figure 3 is a schematic side cross-sectional view and front view of the heat exchanger having a large-capacity filter in which air flows to the bottom according to the present invention,
Figure 4 is a flow diagram of the air flow in the room (general mode) through the total heat exchanger having a large-capacity filter in which air flows to the bottom according to the present invention,
5 is a flow diagram of air flowing back into the room after removing dust while passing through the filter without passing through the heat exchange element through the heat exchanger having a large-capacity filter in which air flows to the bottom according to the present invention (cleaning Mode),
Figure 6 is a state diagram of the flow of air discharged through the heat exchange element when the outside air enters the room without passing through the heat exchange element through a heat exchanger having a large-capacity filter in which air flows to the bottom according to the present invention (BiPad mode) ego,
7 is a flow diagram of air for removing dust accumulated in the filter while the indoor air is discharged through the second air flow chamber in the heat exchanger having a large-capacity filter in which air flows to the bottom according to the present invention (filter exhaust mode) )to be.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described to be easily carried out by those of ordinary skill in the art.

As shown in FIGS. 1 to 7, the total heat exchanger 100 having a large-capacity filter through which air flows to the bottom according to the present invention,

A heat exchange element (110) consisting of a heat exchange element (111) for exchanging air with an outside air, an air supply fan (112) for supplying air to the room, and an exhaust fan (113) for discharging air to the outside;

The filter unit is provided in the lower portion of the heat exchange unit 110 and the upper chamber 121, the lower chamber 122, and a filter unit 123 installed between them to remove dust while the air flows up and down ( 120);

A first air flow chamber unit 130 provided at a side portion of the heat exchanger unit 110 and the filter unit 120 and installed with a second damper (D2) for controlling the inflow of outside air; And

And a second air flow chamber unit 140 provided at a lower portion of the filter unit 120 and having a plurality of perforations 141 through which indoor air flows into the bottom surface, through which air flows.

The first air passage 131 and the second air flow chamber 140 in which air flows between the lower chamber 122 and the air of the filter unit 120 are formed on side surfaces of the first air flow chamber 130. And a second air passage 132 through which air flows with each other is formed.

In addition, the filter unit 123 and the heat exchange element 111 is formed in a rectangular shape, the filter unit 123 is installed on the lower side in the heat exchange element 111 when viewed from the top of the heat exchange element 111 The four vertices are in contact with the edge of the filter unit 123 to provide the filter unit 123 very large. The filter unit 123 has a sufficient space even when fabricated as a collective filter in which various filters such as a hepa filter, a medium filter, and a photocatalyst filter having various functions are collected. In addition, the first air passage 131 flows air only between the first air flow chamber 130 and the lower chamber 122 to move air to the filter unit 123 and to heat exchange in spring and autumn. A bypass mode can be provided without going through the device. The second air passage 132 is configured to allow air to flow with the second air flow chamber 140.

Here, the first air flow chamber unit 130 is provided with a front chamber 133 through which outside air flows through the second damper D2 and a rear chamber of the front chamber 133 while the indoor air is introduced and flows into the rear chamber. It consists of 134. The front chamber 133 and the rear chamber 134 are separated by a chamber separation plate 135 partitioning therebetween, so that the air introduced into the front chamber 133 does not go to the rear chamber 134, and the rear chamber ( The air introduced into 134 does not go to the front chamber 133.

In addition, the lower side surface portion of the front chamber 133 is provided with the first air passage 131 through which air flows to the lower chamber 122, and the lower side surface portion of the rear chamber 134 has the second air flow chamber. The second air passage 132 through which air flows with the part 140 is provided. The installation height of the first air passage 131 and the second air passage 132 is different, and mutual air movement is prohibited by the blocking plate 142 described later.

Therefore, the air of the front chamber 133 flows with the lower chamber 122 through the first air passage 131, and the air of the rear chamber 134 passes through the second air passage 132. Flow with the second air flow chamber 140, and vice versa.

On the other hand, the upper chamber 121 and the lower chamber 122, the air introduced into the empty space can be easily moved to move in the upper and lower portions of the filter unit 123, any particular filter unit 123 Do not force air movement on the part.

The present invention is configured as described above is the first air passage 131 and the lower chamber 122, the filter unit (1) the outside air flowing into the front chamber 133 of the first air flow chamber 130 123), the heat is introduced into the heat exchange element 111 through the upper chamber 121, and is heat-exchanged to supply indoors through the air supply fan 112 to ventilate the inside.

The heat exchange element 110 is a heat exchange element 111 is installed in a lozenge (or square) in the interior of the body frame (110a) that is typically inserted into the ventilation duct (not shown) provided in the ceiling of the room. . Therefore, each of the corners of the body frame (110a) is formed with a flow space of air and the fifth, six dampers (D5, D6), the air supply fan 112 and the exhaust fan to control the flow of air in the flow space ( 113 is installed to connect.

The air supply fan 112 is installed to supply the air introduced through the heat exchange element 111 to the room, and a third damper D3 for controlling the access of the indoor air is connected to the air supply fan 112. In addition, the air supply fan 112 may be configured to introduce the air in the room to the reverse, wherein the third damper (D3) is also operated to enable the flow of air to the reverse.

Therefore, air may be supplied to the room through the air supply fan 112 and the third damper D3 or vice versa by the operation of the air supply fan 112 and the third damper D3. .

In addition, the exhaust fan 113 is installed to discharge the air introduced into the heat exchange unit 110 to the outside, the exhaust fan 113 is provided with a first damper (D1) for opening and closing the flow of air. .

Therefore, by opening the first damper (D1) and operating the exhaust fan 113, the bet can be discharged to the outside.

On the other hand, the filter unit 120 is provided on the lower side of the total heat exchange unit 110 as described above. That is, the heat exchanger 110 is installed adjacent to the lower portion of the body frame (110a), in which case the filter unit 120 and the heat exchanger 110 may be integrally or separately manufactured and combined.

The filter unit 120 is provided on the upper chamber 121 is formed on the upper side and the air flows inward, the lower chamber 122 is formed on the lower side and the air flows inward, and the boundary between them It is composed of a filter unit 123 for removing the dust contained in the air supplied to the room.

As described above, the present invention is divided into a total heat exchange part 110 provided with the heat exchange element 111 and a filter part 120 provided with the filter unit 123, whereby the heat exchange element 111 is connected to the total heat exchange part. The inside of the 110 can be raised and installed to the maximum, and the filter unit 123 can also be installed with a large capacity to the maximum on the lower side of the heat exchange unit 110 separately from the heat exchange element 111. do. As a result, the ventilation performance may be further improved, and the maintainability of the filter unit 123 may be improved.

And a fifth damper (D5) for controlling the air supply of the upper chamber 121 to the heat exchange element 111 is provided on one side of the upper surface of the upper chamber 121.

Accordingly, the fifth damper D5 may be opened to supply air from the upper chamber 121 to the heat exchange element 111.

In addition, the other side of the upper surface of the upper chamber 121 is further provided with a sixth damper (D6) which is opposed to the fifth damper (D5) to communicate with the air supply fan 112 to control the flow of air.

Here, the sixth damper (D6) is to exhaust the dust collected in the filter unit 123 to discharge to the outside or to supply the outside air in the bypass mode, the air supply fan through the control unit When the operation of the 112 is stopped and the third damper D3 is opened, indoor air flows into the air supply fan 112 and then enters the upper chamber 121 through the sixth damper D6. The filter unit 123 passes through in the reverse direction (the air flows in the direction opposite to the direction of ventilation) to detach the dust. The third damper (D3) is installed so that air can flow in both directions.

On the other hand, the front chamber 133 of the first air flow chamber 130 is provided with the second damper (D2) for introducing the outside air. In addition, a fourth damper (D4) is installed in the rear chamber 134 of the first air flow chamber 130 to allow indoor air to flow therein and to control the air flow to the upper side of the side to supply the heat exchange element 111. ) Is installed.

In addition, the lower chamber 122 receives air introduced into the second air passage 132 through the second air flow chamber 140 into the rear chamber 134 of the first air flow chamber 130. The seventh damper (D7) for controlling so that the supply can be supplied to the

Air introduced into the front chamber 133 of the first air flow chamber 130 is supplied to the lower chamber 122 through the first air passage 131.

On the other hand, the present invention is the air introduced through the second air passage 132 instead of the fourth damper (D4) and the seventh damper (D7) of the lower chamber 122 or the total heat exchange unit 110 It can be installed as a three-way valve (not shown) that operates to selectively feed to either side. The rear chamber 134 may be selectively configured when the space for installing the fourth damper D4 and the seventh damper D7 is insufficient and narrow.

The three-way valve is provided in the rear chamber 134 so that a passage through which air flows through the second air passage 132 is supplied to the lower chamber 122 and the heat exchange unit 110. Branched to the passage for supplying to the air to be introduced through the second air passage 132 is controlled to supply to either the lower chamber 122 or the heat exchanger (110).

The bottom surface of the lower chamber 122, which is the lower part of the filter unit 120, is installed as a blocking plate 142 that blocks up and down flow of air.

Here, the blocking plate 142 forms an upper surface of the second air flow chamber part 140.

In addition, a plurality of perforations 141 through which indoor air flows are formed on the bottom surface of the second air flow chamber 140. Here, the perforation 141 includes a circular, oval or long groove.

Therefore, indoor air RA is introduced into the second air flow chamber 140 through the perforation 141. Air introduced into the second air flow chamber part 140 flows to the rear chamber 134 of the first air flow chamber part 130 through the second air passage 132.

Thus, the second air flow chamber 140 of the present invention is provided on the lower side of the filter unit 120 and its bottom surface is installed horizontally with the ceiling of the room (Room) so that the air in the room It is introduced into the second air flow chamber 140 through the perforation 141.

Here, the second air flow chamber part 140 may be installed to protrude slightly toward the lower side of the ceiling, and in this case, the perforation 141 may be provided to form a protruding side part thereof.

Electrothermal heat exchanger of the present invention configured as described above is a general ventilation mode for supplying and ventilating the outdoor air (outer air, OA) to the room while ventilating the indoor air (outer, RA) to the outside, and the indoor air without passing through the heat exchange element The indoor air clean mode which recirculates only through the filter unit to cleanly ventilate the room, and when the temperature difference between the indoor and outdoor areas is not large, the outside air is supplied to the room through the filter unit without passing through the heat exchange element and the bet is discharged to the outside through the heat exchange element. The bypass ventilation mode for preventing the filter, and the filter dusting mode for removing dust collected in the filter unit provided in the filter unit and discharging them to the outside may be operated.

Hereinafter, a flow chart of indoor and outdoor air for each mode will be described.

In the general ventilation mode, as shown in FIG. 4, the indoor air is discharged to the outside and the outside air is supplied to the room and ventilated.

The air supply fan 112 and the exhaust fan 113 are turned on by the controller (not shown), the sixth and seventh dampers D6 and D7 are turned off, and the first to fifth dampers D1 to D5. ) Is ON,

The outside air OA flows into the front chamber 133 of the first air flow chamber 130 through the second damper D2, and the introduced outside air opens the first air passage 131. After entering the lower chamber 122 through the filter unit 123 to remove the dust and the like contained in the outside air is supplied to the upper chamber 121. Subsequently, the outside air supplied to the upper chamber 121 enters the heat exchange element 111 through the fifth damper D5 provided on the upper surface of the upper chamber 121, and heats the air supply fan 112. It is supplied to the room (SA) through.

At the same time, the indoor air RA is introduced into the second air flow chamber 140 through the perforation 141 and then the first air flow chamber 130 through the second air passage 132. After entering the rear chamber 134 of the heat transfer element 111 through the fourth damper (D4) of the heat transfer to the outside through the exhaust fan 113 while being discharged (EA) cycle of the general ventilation mode This is done.

In the indoor air cleaning mode, as shown in FIG. 5, the indoor air is passed through the filter unit without passing through the heat exchange element, and the dust contained in the bet is removed and then supplied again to the room to cleanly ventilate the room. Mode,

The air supply fan 112 is turned on by the controller (not shown), the exhaust fan 113 is turned off, and the third, sixth and seventh dampers D3, D6, and D7 are turned on, and the first and second The dampers D1 and D2 and the fourth and fifth dampers D4 and D5 are turned off,

Room air (RA) is introduced into the second air flow chamber portion 140 through the perforation 141 and then the rear of the first air flow chamber portion 130 through the second air passage 132. After entering the chamber 134 and then again into the lower chamber 122 through the seventh damper (D7) and passes through the filter unit 123 to remove the dust contained in the bet and the upper chamber 121 Is supplied. Subsequently, the bet supplied to the upper chamber 121 enters the air supply fan 112 through the sixth damper D6 and is resupplied to the room, thereby performing a cycle of the indoor air clean mode.

In the bypass ventilation mode, as shown in FIG. 6, the outside air is supplied to the room only through the filter unit without passing through the heat exchange element and the bet is discharged to the outside through the heat exchange element, and the room is ventilated cleanly.

Such bypass ventilation mode has an advantage of preventing condensation because the outdoor air is supplied to the room through the filter unit without passing through the heat exchange element.

The air supply fan 112 and the exhaust fan 113 are turned on by the controller (not shown), and the first to fourth dampers and the sixth to sixth dampers D1 to D4 and D6 are turned on, and the fifth and seventh dampers ( D5, D7) is turned off,

Outside air (OA) is introduced into the front chamber 133 of the first air flow chamber 130 through the second damper (D2), the introduced outside air through the first air passage (131) After entering the lower chamber 122 and passing through the filter unit 123, dust and the like contained in the outside air are removed and supplied to the upper chamber 121. Subsequently, the outside air supplied to the upper chamber 121 enters the air supply fan 112 through the sixth damper D6 and is supplied to the room SA.

At the same time, the indoor air RA is introduced into the second air flow chamber 140 through the perforation 141 and then the first air flow chamber 130 through the second air passage 132. After entering into the rear chamber 134 of the heat exchange element 111 through the fourth damper (D4) is heated and discharged to the outside through the exhaust fan 113 (EA) of the bypass ventilation mode The cycle is done.

As shown in FIG. 7, the filter dedusting mode is a mode in which dust collected on the filter unit provided in the filter unit is detached and discharged to the outside to restore the dust removal performance of the filter unit to improve durability.

The air supply fan 112 is turned off by the controller (not shown), the exhaust fan 113 is turned on, the second and fifth dampers D2 and D5 are turned off, and the first, third, fourth, 6, 7 damper (D1, D3, D4, D6, D7) is ON,

The upper chamber 121 of the filter unit 120 is provided with indoor air through the third damper D3, the air supply fan 112, and the sixth damper D6 by the suction force of the exhaust fan 113. After being introduced into the filter unit 123 through the filter unit 123 is introduced into the lower chamber 122 to desorb dust or foreign matter collected in the filter unit 123.

Subsequently, the bet from which the dust or the foreign substance is detached enters the rear chamber 134 of the first air flow chamber 130 through the seventh damper D7 in the lower chamber 122, and then the fourth damper ( D4) is passed through the heat exchange element 111 of the heat exchange unit 110 and the bet passed through the heat exchange element 111 is discharged to the outside through the exhaust fan 113 is dust or foreign matter, etc. As it is removed, a cycle of filter exhaustion mode is performed.

As described above, the present invention operates one of the general ventilation mode, the indoor air clean mode, the bypass ventilation mode, and the filter exhaustion mode. In this case, the filter unit 123 is separately installed to increase its size to the maximum. It can greatly improve ventilation performance.

In addition, the present invention allows the filter unit 123 to be mounted or detached by sliding along the lateral space of the duct so that the filter unit can be replaced very quickly and conveniently.

As described above, the electrothermal heat exchanger having a large-capacity filter through which air flows to the lower portion according to the present invention is provided with an electrothermal heat exchanger provided with a heat exchange element, a filter unit provided under the electrothermal heat exchanger, and a side portion and a lower surface of the filter portion It consists of the first and second air flow chamber portion, wherein the filter unit is composed of the filter unit and the lower chamber and the upper chamber on the upper and lower sides thereof, by separately operating the heat exchanger and the filter unit to increase the capacity of the filter and at the same time the indoor air The flow through the second air flow chamber and the filter is mounted and detached to improve the ventilation performance of the total heat exchanger as well as to facilitate the replacement of the filter significantly improves the ventilation efficiency and convenience.

100: Electrothermal exchanger with a large-capacity filter in which air flows to the bottom
110: heat exchanger 110a: body frame
111: heat exchange element 112: air supply fan 113: exhaust fan
120: filter unit
121: upper chamber 122: lower chamber 123: filter unit
130: first air flow chamber
131: first air passage 132: second air passage 133: front chamber 134: rear chamber
135: Chamber separator
140: second air flow chamber 141: punching 142: blocking plate
D1: First damper D2: Second damper D3: Third damper D4: Fourth damper
D5: fifth damper D6: sixth damper D7: seventh damper

Claims (10)

A heat exchange element (110) consisting of a heat exchange element (111) for exchanging air with an outside air, an air supply fan (112) for supplying air to the room, and an exhaust fan (113) for discharging air to the outside;
The filter unit is provided in the lower portion of the heat exchange unit 110 and the upper chamber 121, the lower chamber 122, and a filter unit 123 installed between them to remove dust while the air flows up and down ( 120);
A first air flow chamber unit 130 provided at a side portion of the heat exchanger unit 110 and the filter unit 120 and installed with a second damper (D2) for controlling the inflow of outside air; And
And a second air flow chamber part 140 provided at a lower portion of the filter unit 120 and having a plurality of perforations 141 through which indoor air flows into the bottom surface to allow air to flow.
The first air passage 131 through which the lower chamber 122 and the air of the filter unit 120 flow with each other, and the second air flow chamber unit 140, are formed on the side surface of the first air flow chamber unit 130. And second air passages 132 through which air flows to each other are formed;
The first air passage (131) and the second air passage (132) is a total heat exchanger having a large-capacity filter in which air flows to the lower the installation height is different.
The method of claim 1,
The filter unit 123 and the heat exchange element 111 is made of a square,
4. A total heat exchanger having a large-capacity filter in which air flows to a lower portion where four vertices of the heat exchange element 111 are in contact with an edge of the filter unit 123 when viewed from the top.
The method of claim 1,
The first air flow chamber unit 130 is provided with a front chamber 133 through which the outside air flows through the second damper D2 and a rear chamber of the front chamber 133, and a rear chamber through which indoor air flows. (134), wherein the front chamber (133) and the rear chamber (134) are separated by a chamber separation plate (135) partitioning therebetween;
The first air passage 131 is provided on the lower side surface of the front chamber 133 so that the front chamber 133 and the lower chamber 122 communicate with each other, and the second air passage 132 is the rear side. And a large-capacity filter through which air flows to a lower portion of the lower side portion of the rear chamber 134 so that the chamber 134 and the second air flow chamber portion 140 communicate with each other.
The method of claim 1,
A blocking plate 142 is provided between the lower chamber 122 and the second air flow chamber 140 to move in the air and the second air passage 132 that are moved in the first air passage 131. Electrothermal exchanger having a large-capacity filter in which the air flows to the lower portion is not mixed with the air.
The method of claim 3,
In the rear chamber 134, the air introduced through the second air passage 132 is branched into a passage that is supplied to the lower chamber 122 and a passage that supplies the heat exchange unit 110 to the second air passage. Heat transfer having a large-capacity filter in which air flows to the bottom provided with a three-way valve for supplying air introduced through the furnace 132 to either the lower chamber 122 or the heat exchanger 110. Exchanger.
The method of claim 3,
The air supply fan 112 and the exhaust fan 113 are provided with first and third dampers (D1, D3) for controlling the flow of air, respectively, and the rear chamber (1) of the first air flow chamber (130) 134 is provided with a fourth damper (D4) for controlling the air flow to supply to the heat exchange element 111,
One side of the upper surface of the upper chamber 121 is provided with a fifth damper (D5) for controlling the air flow to the heat exchange element 111,
The other side of the upper surface of the upper chamber 121 is provided with a sixth damper (D6) which is opposed to the fifth damper (D5) and communicates with the air supply fan 112 to control the flow of air,
The air introduced into the second air passage 132 through the second air flow chamber 140 to the rear chamber 134 of the first air flow chamber 130 is transferred to the lower chamber 122. A seventh damper (D7) for supplying is provided,
General ventilation mode for supplying outdoor air to the outside while ventilating the indoor air to the outside, and indoor air clean mode for freshly ventilating the room by recirculating the indoor air through the filter unit without passing through the heat exchange element, and the outside air exchange element The filter is supplied to the room through the filter unit without passing through and the bet is exhausted to the outside through the heat exchange element, the filter exhaust mode to remove the dust collected in the filter unit provided in the filter unit to discharge to the outside Electrothermal exchanger equipped with a large-capacity filter in which air flows to the bottom operated in the mode.
The method of claim 6,
In the general ventilation mode, the air supply fan 112 and the exhaust fan 113 are turned on, the sixth and seventh dampers D6 and D7 are turned off, and the first to fifth dampers D1 to D5. Is ON,
The outside air OA flows into the front chamber 133 of the first air flow chamber 130 through the second damper D2, and the introduced outside air opens the first air passage 131. After entering the lower chamber 122 through the filter unit 123 to remove the dust or foreign matter contained in the outside air is supplied to the upper chamber 121, the outside air supplied to the upper chamber 121 It is supplied to the room through the air supply fan 112 while being heated to enter the heat exchange element 111 through the fifth damper (D5) provided on the upper surface of the upper chamber 121,
The indoor air flows into the second air flow chamber 140 through the perforation 141 and then the rear chamber 134 of the first air flow chamber 130 through the second air passage 132. The heat exchanger is provided with a large-capacity filter in which air flows into the lower portion discharged to the outside through the exhaust fan 113 while being transferred to the heat exchange element 111 through the fourth damper (D4).
The method of claim 6,
In the indoor air cleaning mode, the air supply fan 112 is turned on, the exhaust fan 113 is turned off, and the third, sixth and seventh dampers D3, D6, and D7 are turned on, and the first and second The dampers D1 and D2 and the fourth and fifth dampers D4 and D5 are turned off,
The indoor air flows into the second air flow chamber 140 through the perforation 141 and then the rear chamber 134 of the first air flow chamber 130 through the second air passage 132. ) After entering into the lower chamber 122 through the seventh damper (D7) and then passes through the filter unit 123 to remove the dust contained in the bet and to supply to the upper chamber 121 And a bet supplied to the upper chamber 121 is provided with a large-capacity filter in which air flows to the lower part which enters the air supply fan 112 through the sixth damper (D6) and is resupplied to the room.
The method of claim 6,
In the bypass ventilation mode, the air supply fan 112 and the exhaust fan 113 are turned on, and the first to fourth and sixth dampers D1 to D4 and D6 are turned on, and the fifth and seventh dampers ( D5, D7) is turned off,
Outside air flows into the front chamber 133 of the first air flow chamber 130 through the second damper D2, and the introduced outside air flows into the lower chamber through the first air passage 131. After entering the 122 and passing through the filter unit 123, the foreign matter contained in the outside air is removed and supplied to the upper chamber 121, the outside air supplied to the upper chamber 121, the sixth damper ( D6) enters the air supply fan 112 and is supplied into the room,
The indoor air flows into the second air flow chamber 140 through the perforation 141 and then the rear chamber 134 of the first air flow chamber 130 through the second air passage 132. The heat exchanger having a large-capacity filter that enters the inside and then heats up the heat exchange element through the fourth damper (D4) and flows air to the lower portion discharged to the outside through the exhaust fan (113).
The method of claim 6,
In the filter exhaust mode, the air supply fan 112 is turned off, the exhaust fan 113 is turned on, the second and fifth dampers D2 and D5 are turned off, and the first, third, fourth, sixth, seventh and seventh. Damper (D1, D3, D4, D6, D7) is ON,
The upper chamber 121 of the filter unit 120 is provided with indoor air through the third damper D3, the air supply fan 112, and the sixth damper D6 by the suction force of the exhaust fan 113. After the inflow to the filter unit 123 through the filter unit 123 is introduced into the lower chamber 122 to desorb dust or foreign matter collected in the filter unit 123,
Subsequently, the bet from which the dust or foreign matter is detached enters the rear chamber 134 of the first air flow chamber 130 through the seventh damper D7 in the lower chamber 122, and then the fourth damper D4. Pass through the heat exchange element 111 of the heat exchange unit 110 and the bet passing through the heat exchange element 111 is discharged to the outside through the exhaust fan 113 to remove dust or foreign matter Electrothermal exchanger equipped with a large-capacity filter in which air flows to the bottom.

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