KR101959875B1 - Heat exchanger - Google Patents

Abstract

The present invention relates to an indoor air return means communicating with the indoor air outlet and the indoor air inlet on the upper surface of a main body having an indoor air inlet, an indoor air outlet, an outdoor air inlet, an outdoor air outlet, an air heat exchanger, a support partition, In order to prevent contamination of the filter, the filter of the total heat exchanger is installed in a very large number of days when the dust is very fine. In order to prevent contamination of the filter, the outdoor air inlet and the outdoor air outlet are shut off on a lot of fine dust and the fine dust is prevented from flowing into the room It is possible to improve the efficiency of the filter by extending the filter pollution time of the total enthalpy heat exchanger by supplying the clean air from the indoor air through the clean filter and removing the dust etc. from the room without discharging the indoor air to the outside, I do not let the warm air of the cold winter get outdoors, filter the polluted air, Turn to relate to combined heat exchanger cleaning function room air returned to a cold reuse of clean air improves the heating efficiency reduce energy costs and reduce energy consumption in summer and winter.

Description

{HEAT EXCHANGER} that has indoor air return and clean function.

More particularly, the present invention relates to a total heat exchanger having an indoor air inlet, an indoor air outlet, an outdoor air inlet, an outdoor air outlet, an air heat exchanger, a support partition, an intake fan, an exhaust fan, The indoor air return means communicated with the indoor air outlet and the indoor air inlet port is provided on the upper surface of the indoor air outlet and the filter of the total enthalpy heat exchanger is contaminated in a short period of time when a lot of fine dust is present. The outdoor air inlet and the outdoor air outlet are blocked, the fine dust is prevented from flowing into the room, the indoor air is not discharged to the outdoor, the indoor air is returned through the clean filter, the clean air from which dust is removed, The efficiency of the filter is increased, and the cold air in summer or the very cold The indoor air return to reduce the energy cost by reducing the energy cost by improving the efficiency of heating and cooling by reusing the clean air by filtering the polluted air without returning the warm air of the paddle to the outside, And a clean function.

Generally, the total heat exchanger is used as a component of the building air conditioning system. In order to ventilate the building, indoor air is discharged outdoors, indoor air discharged from the room is sucked into the room, So that the heat loss generated during the ventilation process can be reduced.

1, the total enthalpy heat exchanger includes a main body 1 having suction and discharge flow paths 1a and 1b, an indoor and an outer suction ports 1c and 1d, and indoor and outdoor discharge ports 1e and 1f, And a total heat-exchanging element 2 arranged in a rhombic shape in the main body 1 for exchanging heat between the outdoor air and the room air.

And a filter (3) installed on both suction surfaces of the total heat-exchanging element (2) to filter out foreign matter.

A support partition 4 disposed at the center of the inner slope of the main body 1 for supporting the total heat-exchanging element 2 and the filter 3 and partitioning the suction passage 1a and the discharge passage 1b ).

And an intake fan 5 and an exhaust fan 6 installed at the outlets of the intake passage 1a and the exhaust passage 1b, respectively.

In the total enthalpy heat exchanger, the outdoor air sucked into the room and the indoor air discharged to the outdoor are laminated so that the flow path through which the outdoor air sucked into the room is passed and the flow path through which the room air discharged out of the room passes are perpendicular to each other. And the total enthalpy heat exchanging element 2 for heat exchange with each other.

However, the total heat exchanger equipped with a filter that sucks air outdoors due to fine dust rising seriously and sends clean air, which has removed fine dust and the like, to the room through the filter is used. In the case where fine dust is present, The filter 3 of the filter 3 is contaminated within a short time and the filter 3 can not be used for a long time.

In addition, the total enthalpy heat exchanger may be configured such that the indoor air used for indoor use in the summer season (pole stop) or the indoor air in which the indoor temperature is not lowered during the winter season (extreme event) 6b to the outside through the indoor suction port 1c, the discharge flow passage 1b and the outdoor discharge port 1f through the outdoor air inlet port 1d and the suction fan 5, 1 a), the room air is supplied to the room through the room outlet 1 e to discharge the indoor air used for the indoor air conditioning to the outside in the state of no loss of heat and heat, There were many problems that the cooling cost and the heating cost in winter increased.

In order to overcome the above-described problems, the present invention provides an indoor unit having an indoor heat exchanger main body having an indoor heat exchanger main body having an indoor air inlet, an indoor air outlet, an outdoor air inlet, an outdoor air outlet, an air heat exchanger, a support partition, And indoor air return means communicated with the indoor air intake port are provided. The filter of the total enthalpy heat exchanger is contaminated in a short time when a lot of fine dust is present. Therefore, in order to prevent contamination of the filter, the outdoor air inlet and the outdoor air outlet are blocked It prevents the inflow of fine dust into the room, discharges indoor air to the outside, supplies indoor air through the clean filter, and returns clean air with the dust removed to the room, thereby extending the filter pollution time of the total heat exchanger. And an indoor air return function for increasing the efficiency of the indoor heat exchanger.

The other purpose is to reduce the energy cost by improving the efficiency of heating and cooling by reusing the clean air by returning to the indoor after filtering the polluted air without causing the cold air of the very hot summer or the cold air of the cold winter to be discharged outdoors, And an indoor heat exchanger which has a function of returning indoor air to reduce energy consumption in winter and a clean function.

In order to attain the above object, the present invention provides a refrigerator comprising: a main body having a suction passage, an exhaust passage, an indoor suction port, an outdoor suction port, an indoor discharge port, and an outdoor discharge port; A total heat-exchanging element disposed inside the main body for exchanging heat between outdoor air and indoor air; A support partition disposed at the center of the inner slope of the main body and partitioning the suction passage and the discharge passage for supporting the total heat-exchanging element; An intake fan and an exhaust fan installed at the outlet of the discharge passage; An indoor air return provided on both sides of the total heat-exchanging element and a filter member provided on both sides of the suction surface to remove foreign matter, dust and fine dust, the total heat-
A first air inlet / outlet opening / closing part installed at a right angle to the indoor air inlet port and formed on an upper surface of the main body, and a first air inlet / outlet opening / closing part coupled to the first air hole; And a second air inlet / outlet opening / closing portion connected to the second air hole, and a connecting pipe connecting the first air inlet / outlet opening / closing portion and the second air inlet / outlet opening / closing portion to each other And,

The first and second air inlet and outlet opening and closing portions include a main body portion having a lower inlet portion and an upper outlet portion bent at a right angle in the lower inlet portion and communicating with each other, a rotating bar horizontally penetrating the inner periphery of the upper outlet portion, An opening and closing member provided on the turning bar, and a driving motor provided around the outer periphery of the upper discharging unit in association with the turning bar for driving the turning bar.

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In addition, the upper and lower portions of the first rotating bar are inserted into pivot holes formed in one side of the upper and lower horizontal bars fixed to the upper and lower surfaces of the suction surface, respectively, and the upper portion of the second rotating bar And a lower portion of the second pivot bar is inserted into a pivot hole formed in an upper horizontal bar provided on a front upper surface of the suction surface and passing through a pivot hole formed in the lower horizontal bar on a lower front surface of the suction surface, And is rotated in connection with the motor.

In addition, the first rotating bar may be provided on one side between the upper horizontal bar and the lower horizontal bar, and a screw thread formed on the outer circumference of the upper exposed portion of the first rotating bar exposed through the rotating hole formed in the upper horizontal bar A screw thread formed on an outer periphery of a lower exposed portion of the first pivot bar exposed through the pivot hole formed in the lower horizontal bar, and a nut screwed to the screw thread;

Wherein the second rotating bar is provided on an opposite side of the upper horizontal bar and the lower horizontal bar and is formed around the upper exposed portion of the second rotating bar exposed through the rotating hole formed in the upper horizontal bar, And a lower exposed portion of the second rotating bar exposed through the rotating hole formed in the lower horizontal bar is connected to the motor.

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The new moving filter member which is not contaminated with foreign matter and dust newly covers the upper surface of the suction surface of the total heat-exchanging element and is moved by an area capable of filtering foreign matter and dust, and the foreign matter and dust are contaminated, Is depressurized around the outer periphery of the second rotating bar.

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The present invention relates to an indoor air return means communicating with the indoor air outlet and the indoor air inlet on the upper surface of a main body having an indoor air inlet, an indoor air outlet, an outdoor air inlet, an outdoor air outlet, an air heat exchanger, a support partition, In order to prevent contamination of the filter, the filter of the total heat exchanger is installed in a very large number of days when the dust is very fine. In order to prevent contamination of the filter, the outdoor air inlet and the outdoor air outlet are shut off on a lot of fine dust and the fine dust is prevented from flowing into the room It is effective to increase the efficiency of the filter by extending the filter pollution time of the total enthalpy heat exchanger by supplying the indoor air through the clean filter and the clean air from which dust and the like have been removed to the indoor without discharging the indoor air to the outside.

In addition, it does not let the cold air of the very hot summer season or the cold air of the cold winter be discharged to the outside, but it returns to the indoor after filtering polluted air to reduce the energy cost by improving the cooling and heating efficiency by reusing clean air. Thereby reducing energy consumption.

1 is a schematic view showing a conventional total enthalpy heat exchanger;
FIG. 2 is a schematic view showing an indoor air returning means provided in a main body according to the present invention; FIG.
FIG. 3 is a schematic view showing that a main body according to the present invention is provided with first and second air inlet / outlet switching units, which are indoor air return means.
4 is a schematic view showing the indoor air return means separated from the main body according to the present invention.
5 is a schematic cross-sectional view of a main body and indoor air return means according to the present invention.
6 is a schematic sectional view showing an opening / closing part according to the present invention.
7 is a plan view of the main body according to the present invention in which a moving filter member is installed.
8 is an exploded perspective view of the moving filter member according to the present invention.
9 is an exploded perspective view of the moving filter member according to the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to explain the present invention more safely to those having ordinary skill in the art.

Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals.

FIG. 2 is a schematic view showing that the indoor air returning means is installed in the main body according to the present invention, FIG. 3 is a schematic view showing that the first and second air inlet / 5 is a schematic sectional view showing a main body and indoor air returning means according to the present invention, and FIG. 6 is a schematic view showing an opening / closing part according to the present invention FIG. 9 is a perspective view showing the moving filter member according to the present invention, FIG. 9 is a perspective view showing the moving filter member according to the present invention, FIG. to be.

The total enthalpy heat exchanger having the function of cleaning indoor air according to the present invention will now be described in detail with reference to FIGS. 2 to 9.

The total enthalpy heat exchanger having the function of cleaning by the indoor air returning according to the present invention has the main body 10, the total heat-exchanging element 20, the supporting partition 30, the intake fan 40a and the exhaust fan 40b, 50, an indoor air return susan 60, a contamination detection sensor 70, and a control unit 80.

The total enthalpy heat exchanger constructed as described above is installed so as to be embedded in the ceiling of the building, and when the room is ventilated, the outdoor air sucked into the room and the room air discharged to the outside are exchanged with each other, And the heat loss can be reduced by reducing the difference.

The main body 10 includes a suction passage 11a for guiding the room to the inside and a discharge passage 11b for guiding the room air to the outside.

One side of the main body 10 is provided with an indoor suction port 12a through which room air is sucked and an indoor discharge port 13a through which outdoor air is discharged to the room.

The other side of the main body 10 is provided with an outdoor air inlet 12b through which outdoor air is sucked and an outdoor air outlet 13b through which room air is discharged outdoors.

The outdoor air intake port 12b and the outdoor air outlet port 13b are connected to each other by the suction flow path 11a so that the outdoor air can be sucked into the room. And is connected by the discharge passage 11b to discharge indoor air to the outside.

In the total enthalpy heat exchanging element 20, the suction passage 11a and the discharge passage 11b intersect each other at an intermediate portion thereof so that the outdoor air sucked into the room and the room air discharged to the outside can heat-exchange with each other The air passing through the suction passage 11a and the air passing through the discharge passage 11b can be exchanged with each other at a crossing point where the suction passage 11a and the discharge passage 11b intersect with each other, .

The total enthalpy heat exchanging element 20 is stacked alternately so that the flow path through which the air sucked in is passed and the flow path through which the exhausted air passes are perpendicular to each other so that the air passing through the suction path 11 and the exhaust path 11b can be exchanged without mixing with each other.

The supporting partition 30 is disposed at the center of the inner slope of the main body 10 and the supporting partition 40 supports the total enthalpy heat exchanging element 20 and the moving filter member 50 And at the same time separates the suction passage 11a and the discharge passage 11b

The suction fan 40a and the exhaust fan 40b generate a blowing force to smoothly flow along the suction passage 11a and the discharge passage 11b. The outdoor air and the indoor air flow along the suction passage 11a and the discharge passage 11b, respectively, in accordance with the operation of the exhaust fan 50b.

The intake fan 40a and the exhaust fan 40b may be driven by the power source, but may be controlled by a control unit 80 described later.

The filter member 50 is provided on both sides of the suction surface 21 provided on both sides of the total heat-exchanging element 20 and is configured to remove foreign matter, dust and fine dust.

The filter member 50 is composed of a moving filter member 50a.

The moving filter member 50a includes suction surfaces 21 provided on both sides of the total heat-exchanging element 20, first and second rotating bars 51 and 52 provided on both sides of the suction surfaces 21, And is disposed so as to be depressurized around the outer periphery of the first rotating bar 51 and move to the outer periphery of the second rotating bar 52.

The moving filter member 50a is composed of a filter a.

That is, the filter a is depressurized by the first rotating bar 51 and is moved to the second rotating bar 52 driven by the motor 60a.

The moving filter member 50 prevents foreign matter such as dust contained in the air from accumulating foreign matter on the internal flow path of the total enthalpy heat exchanging element 20.

The moving filter member 50 is composed of a first rotating bar 51 and a second rotating bar 52 provided on both sides of the suction surface 21 of the total enthalpy heat exchanging element 20 at a distance from each other .

The moving filter member 50 is decompressed around the outer periphery of the first rotating bar 51 and supplied to the outer periphery of the second rotating bar 52 driven by the motor 60a, And the member 50 is configured to be moved from the first rotation bar 51 to the second rotation bar 52 so as to be depressurized around the outer periphery of the second rotation bar 52.

Upper and lower portions of the first rotating bar 51 are formed with pivot holes 55 formed on one side of the upper and lower horizontal bars 53a and 54a fixed to the upper and lower surfaces of the suction surface 21, And is vertically installed and rotated.

The upper portion of the second rotating bar 52 is inserted into a pivot hole 55 formed in the upper horizontal bar 53a provided on the front upper surface of the suction surface 21 and the lower portion of the second rotating bar 52 Is connected to the motor (60a) provided on the main body (10) through a pivot hole (55) formed in the lower horizontal bar (54a) on the front lower surface of the suction surface (21)

In addition, the first rotating bar 51 is installed on one side between the upper horizontal bar 53a and the lower horizontal bar 54a.

And a thread n formed on the outer periphery of the upper exposed portion 51a of the first pivot bar 51 exposed through the pivot hole 55 formed in the upper horizontal bar 53a.

A nut m is screwed to the thread n and a lower exposed portion 51b of the first turning bar 51 exposed through the pivot hole 55 formed in the lower horizontal bar 54a, And a nut m is screwed to the thread n.

In addition, the second rotating bar 52 is installed on the other side between the upper horizontal bar 53a and the lower horizontal bar 54a.

And a thread n formed on the outer periphery of the upper exposed portion 52a of the second turning bar 52 exposed through the pivot hole 55 formed in the upper horizontal bar 53a.

A nut m is screwed to the thread n and a lower exposed portion 52b of the second turning bar 52 exposed through the pivot hole 55 formed in the lower horizontal bar 54a, Is connected to the motor 60a.

A plurality of vertically arranged vertically adjacent upper horizontal bars 53a and lower horizontal bars 53b are provided adjacent to the first rotary bar 51 and the second rotary bar 52, And a pressurizing guide rod 56 is provided.

The plurality of pressure guide rods 56 are vertically disposed between the upper and lower horizontal bars 53a and 54a adjacent to the first and second rotary bars 51 and 52, 51 is moved to the second rotating bar 52, the outer circumferential surface of the pressure guide rod 56 moves the moving filter member 50 to the total enthalpy heat exchanging element 20 so as to increase the filtering effect of the moving filter member 50 on the suction surface 21.

As described above, installing the moving filter member 50 on both the suction surfaces 21 of the total enthalpy heat exchanging element 20 can be achieved by installing the moving filter member 50 on both the suction surfaces 21 of the conventional total heat- In order to install a new filter on the suction surface, the filter is disassembled at a place where the total enthalpy heat exchanger is installed, and the main body 10 constituting the total enthalpy heat exchanger is disassembled in a stable place so that the total enthalpy heat exchanger 20 ) Is externally exposed to replace the detachable filter on both the suction surfaces 21 of the total enthalpy heat exchanging element 20 and to reassemble the main body 10 again after the disassembled main body 10 has been assembled When the moving filter member 50 is contaminated on both the suction surfaces 21 of the total enthalpy heat exchanging element 20 by removing the contaminated moving filter member 50, Every time The moving filter member 50 is moved to both the suction surfaces 21 of the total enthalpy heat exchanging element 20 so that the new uncontaminated moving filter member 50 can be easily and freely supplied.

The motor 60a is installed below the second rotary bar 52 and is rotated between the upper and lower horizontal bars 53a and 54a to be depressurized by the first rotary bar 51, (50).

The indoor air returning means 60 includes a first coupling hole 61a formed at a right angle to the indoor air outlet 12a and formed on the upper surface of the main body 10. [

And a first air inlet / outlet opening / closing portion 62a coupled to the first coupling hole 61a.

And a second coupling hole 61b formed on the upper surface of the main body 10 at a right angle to the indoor discharge port 13a.

And a second air inlet / outlet opening / closing portion 62b coupled to the second coupling hole 61b.

And a connection pipe 63 connecting the first air inlet / outlet switching unit 62a and the second air inlet / outlet switching unit 62b to each other.

That is, the first coupling hole 61a is formed on the upper portion of the opening / closing cover 10a which is opened / closed at the upper portion of the main body 10, and the second coupling hole 61b is formed.

As described above, the main body 10 includes the first air inlet / outlet opening / closing portion 62a communicating with the suction passage 11a, and the second air outlet / And the connection portion 63 connecting the first and second air inlet / outlet switching portions 62a and 62b to each other,

The indoor air returning means 60 may be provided with the indoor air returning means 60 for reusing the indoor air which has been introduced into the indoor inlet 12a of the main body 10, The indoor air is returned to the room by the indoor air outlet 13a to return to the room without returning the cold air of the summer to the outside so that the cooling efficiency is increased and the hot air of winter is returned to the room without being discharged outdoors To increase heating efficiency, it is necessary to reduce the cost of producing heating and cooling in summer and winter, and to reduce energy consumption in summer and winter.

The first and second air inlet and outlet opening and closing portions 62a and 62b include a lower inlet portion 64 and an upper outlet portion 65 bent at a right angle in the lower inlet portion 64 and communicated with each other. (66).

And a pivotal bar 65a horizontally penetrating the inner periphery of the upper discharge portion 65.

And a gap member 65b provided on the rotation bar 65a.

The opening and closing member 65b is installed on the inner periphery of the upper discharge portion 65 so as to prevent the indoor air flowing into the lower inflow portion 64 from flowing into or out of the indoor air flowing into the upper discharge portion 65, As shown in Fig.

And a driving motor 65c provided on the outer periphery of the upper discharge portion 65 in cooperation with the pivoting bar 65a to drive the pivoting bar 65a.

The drive motor 65c is driven by a constant power source and is controlled by the control unit 80 described later.

Further, a flange portion 64a is integrally formed around the outer periphery of the lower inflow portion 64.

The flange 64a has a plurality of first screw holes nh1 and a second screw hole nh2 formed around the outer circumferences of the first and second coupling holes 61a and 61b. As shown in FIG.

The screw n1 is screwed to the first and second screw holes nh1 and nh2.

Further, an elastic rubber material portion 65b-1 covered with an elastic rubber material is provided on the outer peripheral surface of the opening / closing member 65b.

And an extraneous extension portion 65b-2 extending outwardly from the elastic rubber portion 65b-1 with an elastic rubber material.

As described above, the opening / closing member 65b is composed of the elastic rubber material portion 65b-1 and the extraneous extension portion 65b-2,

The elastic rubber portion 65b-1 can be flexibly driven around the inner periphery of the upper discharge portion 65 and the extra-extension portion 65b-1 having an excellent elastic force on the outer periphery of the elastic rubber portion 65a- 2 is further formed so that air tightness is emphasized together with the elastic rubber part 65a-1 on the inner circumference of the upper discharge part 65 so that the air in the cold room is discharged to the lower inflow part 64 and the upper discharge part (65) to completely block the inflow and outflow by the open / close member (65b).

The contamination detection sensor 70 is configured to measure the foreign matter and the pollution degree of the moving filter member 50a.

The contamination detection sensor 70 comprises a differential pressure sensor or an operation time recorder.

In addition, the contamination detecting sensor 70 is configured to be connected to a MISSAN dust application installed in a home automobile which can be connected to the Internet.

The micro dusts installed in the grooved auto are connected to the contamination detection sensor 70 through the control unit 80.

The contamination detection sensor 70 measures the foreign matter and the pollution degree of the moving filter member 50a and transmits the measured foreign matter and the pollution degree to the controller 80. The controller 80 controls the lower part of the second rotating bar 52 The movable filter member 50a is moved from the first rotating bar 51 to the second rotating bar 52 by driving the motor 60a provided in the second rotating bar 51. [

Therefore, the new moving filter member 50a, which is not contaminated with foreign matter and dust, covers the upper surface of the suction surface 21 of the total enthalpy heat exchanging element 20 and moves by an area enough to filter contamination of foreign matter and dust And the movable filter member 50a, which is contaminated with foreign matter and dust, is configured to be depressurized around the outer periphery of the second pivot bar 52.

The control unit 80 is configured to control the motor 60a, the driving motor 65c, and the contamination detection sensor 70. [

The motor 60a, the driving motor 65c and the contamination detecting sensor 70, the intake fan 40a and the exhaust fan 40b are always driven by a power source, and the motor 60a, The motor 65c and the contamination detecting sensor 70, the intake fan 40a and the exhaust fan 40b are controlled by the controller 80. [

The present invention is characterized in that the indoor air intake port 12a, the indoor air outlet port 13a, the outdoor air inlet port 12b, the genital outdoor outlet port 13b, the total heat exchange element 20, the support partition 30, (12a) communicating with the indoor exhaust port (13a) and the indoor air intake port (12a) on the upper surface of the main body (10) having the exhaust fan (40a), the exhaust fan The filter of the total enthalpy heat exchanger is fouled in a short period of time. In order to prevent contamination of the filter, the outdoor air inlet port 12b and the outdoor air outlet port 13b are shut off on a lot of fine dust particles, And the efficiency of the filter is improved by increasing the filter contamination time of the total enthalpy heat exchanger by the return to the room to increase the efficiency of the filter and to provide the outdoor air inlet 12b and the outdoor air outlet 13b (10), and the air introduced into the indoor air inlet And indoor air used as a warm air is filtered by a filter member (50) of the total enthalpy heat exchanger without heat loss, so that indoor air return means (60) for returning indoor air return means (60) Returning the room back to the room so that the cold air of summer (pole clerk) is returned to the room without discharging to the outside, thereby increasing the cooling efficiency and blocking the inflow of fine dust into the room, It is intended to reduce the energy cost to produce air-conditioning in summer and winter, and to reduce energy consumption in summer and winter, by raising the heating efficiency by returning to the indoor without returning hot air to the outside.

It will be apparent to those skilled in the art that various modifications and equivalent arrangements may be made therein without departing from the scope of the present invention. . Therefore, it is to be understood that the present invention is not limited to the above-described embodiments.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

10: main body 11a:
11b: discharge flow path 12a: indoor intake port
12b: outdoor air intake port 13a: indoor air outlet port
13b: Outside outlet 20: Total heat exchanging element
21: suction surface 30: support partition
40a: intake fan 40b: exhaust fan
50: filter member 50a: moving filter member
51: first rotating bar 51a, 51b: upper exposed portion
51b, 52b: lower exposed portion 52: second rotating bar
53a: upper horizontal bar 54a: lower horizontal bar
55: pivot hole 56: pressure guide rod
60: indoor air return means 60a: motor
61a, 61b: first and second coupling holes 62a, 62b: first and second air inlet /
63: connector tube 64: lower inlet
64a: flange portion 65: upper discharge portion
65a: rotation bar 65b: opening / closing member
65c: drive motor 70: contamination detection sensor

Claims (10)

A main body 10 having a suction passage 11a, a discharge passage 11b, an indoor suction port 12a, an outdoor suction port 12b, an indoor discharge port 13a, and an outdoor discharge port 13b;
A total heat-exchanging element (20) disposed inside the main body (10) for exchanging heat between the outdoor air and the room air;
A support partition 30 disposed at the center of the inner slope of the main body 10 and partitioning the suction passage 11a and the discharge passage 11b supporting the total heat-exchanging element 20;
An intake fan 40a and an exhaust fan 40b installed at the outlets of the intake passage 11a and the exhaust passage 11b, respectively;
An indoor air return provided on both sides of the total heat-exchanging element 20 and a filter member 50 provided on both sides of both the suction surfaces 21 to remove foreign matter, dust and fine dust In the total heat exchanger having a clean function,
A first coupling hole 61a provided at a right angle with the indoor intake port 12a and formed on the upper surface of the main body 10 and a first air inlet / outlet opening / closing part 62a coupled to the first coupling hole 61a, A second coupling hole 61b formed on the upper surface of the main body 10 at a right angle to the indoor discharge port 13a and a second air inlet / outlet opening / closing portion coupled to the second coupling hole 61b And an indoor air returning means (60) comprising a connecting pipe (63) connecting the first air inlet / outlet opening / closing portion (62a) and the second air inlet / outlet opening / closing portion (62b)
The first and second air inlet and outlet opening and closing portions 62a and 62b include a lower inlet portion 64 and a main outlet portion 65 having an upper outlet portion 65 bent at a right angle in the lower inlet portion 64, A rotary bar 65a horizontally penetrating the inner periphery of the upper discharge portion 65 and an opening and closing member 65b provided in the rotary bar 65a; And a driving motor 65c provided on the outer periphery of the upper discharge portion 65 in cooperation with the pivoting bar 65a,
The upper and lower portions of the first rotating bar 51 are inserted into a pivot hole 55 formed at one side of the upper and lower horizontal bars 53a and 54a fixed to the upper and lower surfaces of the suction surface 21 And the upper portion of the second rotating bar 52 is inserted into the pivot hole 55 formed in the upper horizontal bar 53a provided on the front upper surface of the suction surface 21, The lower part is connected to a motor 60a provided on the main body 10 through a pivot hole 55 formed in the lower horizontal bar 54a on the front lower surface of the suction surface 21,
The first rotating bar 51 is provided on one side between the upper horizontal bar 53a and the lower horizontal bar 54a and passes through the pivot hole 55 formed in the upper horizontal bar 53a, A nut n formed on the outer periphery of the upper exposed portion 51a of the first turning bar 51 and a nut m screwed on the thread n, A screw thread n formed on an outer periphery of a lower exposed portion 51b of the first pivot bar 51 exposed through the pivot hole 55 formed therein and a nut m provided on the thread n, ;
The second turning bar 52 is provided on the other side between the upper horizontal bar 53a and the lower horizontal bar 54a and passes through the pivot hole 55 formed in the upper horizontal bar 53a, A nut n formed on the outer periphery of the upper exposed portion 52a of the second turning bar 52 and a nut m screwed on the thread n, And the lower exposed portion (52b) of the second rotating bar (52) exposed through the formed pivot hole (55) is connected to the motor (60a). delete delete delete delete delete delete delete delete delete

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