KR101571142B1 - Ventilation device having heat exchanger - Google Patents

Abstract

Disclosed is a heat exchange system with high efficiency capable of improving the comfortableness of a life and reducing fuel costs by remarkably increasing the heat exchange efficiency of a temperature and moisture by forming a heat exchanger to form a multilayer heat exchange structure and exchanging heat several times by exchanging indoor air with outdoor air in the heat exchange structure of the heat exchanger.

Description

TECHNICAL FIELD [0001] The present invention relates to a ventilation system having a high efficiency heat exchanger,

The present invention relates to a ventilation system having a high efficiency heat exchanger, wherein a heat exchanger for forming a multi-layer heat exchange structure is provided, and the outdoor air and the room air cross each other in the heat exchange structure of the heat exchanger, And a ventilation system having a high efficiency heat exchanger structured such that the heat exchange efficiency of humidity is greatly increased, thereby reducing the fuel cost and improving the living comfort.

In general, the air in the closed space increases the content of carbon dioxide over time by the respiration of the living organism, thereby hindering the breathing of the living organism. Therefore, when many people, such as offices and vehicles, stay in a narrow space, the contaminated air in the room should be replaced with fresh air outdoors at any time.

Generally, a ventilation hole is installed in the inside of a building for ventilation of indoor air. The ventilation system of a typical building mainly has a structure in which air is discharged in a single direction, and outdoor air is naturally introduced through a space.

In other words, the ventilation facility which artificially energizes according to the conditions of use in daily life to discharge the contaminated air in the space formed by the cooling and heating to the outside, and the fresh air to the outside, sucks only the heat in the air, And the intake air is exchanged by mutual heat exchange to ventilate the indoor air contaminated in the space where the cooling and heating is formed, and to conserve energy used for cooling and heating the space.

In addition, a separate dust filter is applied to the ventilation system of the building so as to prevent impurities such as dust from entering during the inflow of outside air.

However, since the conventional ventilation system of the building has a structure in which the air is discharged in a usual single direction and the outdoor air naturally flows through the clearance of the space, the heat exchange effect There was a problem that it was slight. Therefore, energy conservation capacity of the space where the cooling and heating is formed is considerably deteriorated, and a great amount of energy is wasted to maintain it.

In addition, since the conventional ventilation system of the building has a dust filter integrally formed in the ventilation system, the structure is complicated and the operation of replacing the dust filter is complicated and difficult.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the problems described above, and it is an object of the present invention to provide a heat exchanger having a multi-layered heat exchange structure, in which outdoor air and indoor air cross each other in a heat exchange structure of the heat exchanger, Efficiency heat exchanger in which heat exchange efficiency of temperature and humidity is greatly increased, thereby reducing the fuel cost and improving the living comfort.

It is another object of the present invention to provide a ventilation system having a heat exchanger and a filter separately provided so as to have a high air purification capability, as well as a high-efficiency heat exchanger for checking contamination of the filter and for easily replacing the filter.

The object of the present invention is to provide an indoor unit air passage in which indoor air is repeatedly moved for each layer with a predetermined length and a heat exchanging plate spaced up and down by a predetermined distance, A heat exchange duct connected to one end of the heat exchange duct to supply air to the indoor air flow path and to be supplied through the outdoor air flow path, The air conditioner according to claim 1, further comprising: a first distributor configured to supply air to the room; and a second distributor connected to the other end of the heat exchange duct to discharge the air supplied through the indoor unit flow path to the outside, A heat exchanger configured to include a second distributor configured; An exhaust duct connected at one end to the indoor and coupled at the other end to the first distributor to guide indoor air exhausted from the indoor to the heat exchange duct; An air supply duct connected at one end to the indoor and connected at the other end to the first distributor to guide outdoor air supplied through the outdoor air flow path to the room; The air conditioner according to any one of claims 1 to 3, further comprising: an inlet duct connected at one end to the outdoor unit and connected to the second distributor at the other end thereof for guiding outdoor air sucked from the outdoor unit to the heat exchange duct, And an exhaust duct for guiding indoor air exhausted through the indoor unit flow path to the outside of the room. The ventilation system according to claim 1, wherein the ventilation system comprises a high efficiency heat exchanger.

Further, the above-mentioned object is achieved by a heat exchanger comprising a plurality of heat exchanging plates each having a predetermined length and spaced apart by a predetermined distance from each other, and a multi-layer flow path for moving air with the heat exchanging plate interposed therebetween, An indoor air flow path in which indoor air is repeatedly moved through each heat exchanging plate and an outdoor air flow path through which outdoor air flows are formed in the center of the air flow path and indoor air moved along the indoor air flow path is circulated in the middle, A heat exchange duct connected to one end of the heat exchange duct and supplied with air exhausted from the indoor space to the indoor unit flow path, The air circulated through the indoor unit circulating flow path is supplied to the outdoor air flow path, And the air supplied through the outdoor air flow path is supplied to the room, and the air supplied through the indoor air flow path is circulated and supplied to the indoor air circulation channel A heat exchanger comprising a fourth distributor configured to distribute heat; An exhaust duct connected to the indoor unit at one end and coupled to the third distributor to guide indoor air exhausted from the indoor unit to the heat exchange duct; An inlet duct connected at one end to the outdoor unit and connected at the other end to the third distributor to guide outdoor air sucked from the outside to the heat exchange duct; An outlet duct connected to the outdoor unit and connected to the third distributor to guide indoor air circulated through the indoor unit circulation duct to the outside of the room; An air supply duct connected to the indoor unit at one end and coupled to the fourth distributor to guide the outdoor air supplied through the outdoor unit flow path to the room; And a circulation duct coupled to the fourth distributor at both ends to circulate indoor air exhausted through the indoor unit flow path to the indoor unit circulation flow path.

The ventilation system having the high efficiency heat exchanger according to the present invention is provided with a heat exchanger forming a multi-layer heat exchange structure, and the outdoor air and the room air cross each other in the heat exchange structure of the heat exchanger, The heat exchange efficiency of the heat exchanger is significantly increased, thereby reducing the fuel cost and improving the comfort of life.

1 is a plan sectional view showing a ventilation system having a high efficiency heat exchanger according to a first embodiment of the present invention,
2 is a view for explaining a heat exchange duct in a ventilation system having a high efficiency heat exchanger according to a first embodiment of the present invention,
3 to 5 are views for explaining a first distributor in a ventilation system having a high efficiency heat exchanger according to a first embodiment of the present invention,
6 to 8 are views for explaining a second distributor in a ventilation system having a high efficiency heat exchanger according to a first embodiment of the present invention,
9 is a view for explaining a first connection port and a second connection port in a ventilation system having a high efficiency heat exchanger according to a first embodiment of the present invention;
10 and 11 are views for explaining a filter box in a ventilation system having a high efficiency heat exchanger according to a first embodiment of the present invention,
12 is a view for explaining the operation of a filter box in a ventilation system having a high efficiency heat exchanger according to a first embodiment of the present invention,
13 is a plan sectional view showing a ventilation system having a high efficiency heat exchanger according to a second embodiment of the present invention,
FIG. 14 is a view for explaining a heat exchange duct in a ventilation system having a high efficiency heat exchanger according to a second embodiment of the present invention; FIG.
15 to 17 are views for explaining a third distributor in a ventilation system having a high efficiency heat exchanger according to a second embodiment of the present invention,
18 to 20 are views for explaining a fourth distributor in a ventilation system having a high efficiency heat exchanger according to a second embodiment of the present invention,
FIG. 21 is a view for explaining a third connection port and a fourth connection port in a ventilation system having a high-efficiency heat exchanger according to a second embodiment of the present invention; FIG.
22 is a view for explaining the operation of a filter box in a ventilation system having a high efficiency heat exchanger according to the first embodiment of the present invention,

Hereinafter, a ventilation system having a high efficiency heat exchanger according to the present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

Referring to FIG. 1, a ventilation system having a high-efficiency heat exchanger according to a first embodiment of the present invention is installed inside a building to ventilate indoor air. Particularly, And installed for the purpose of ventilating an apartment space. Specifically, the ventilation system including the high efficiency heat exchanger according to the first embodiment of the present invention includes a heat exchanger 100, an exhaust duct 200, an air supply duct 300, an inlet duct 400 and an exhaust duct 500 .

The heat exchanger 100 is configured to exchange indoor air I discharged from the indoor unit 1 and outdoor air O received from the outdoor unit 3 through heat exchange. Here, the heat exchanger 100 is preferably installed in the veranda 3 of the apartment.

The heat exchanger 100 may include a heat exchanging duct 110, a first distributor 120, and a second distributor 130. Here, the heat exchange duct 110 has a plurality of heat exchange plates 111 having a predetermined length and spaced apart from each other by a predetermined distance. The indoor unit flow path 112 in which the indoor air I is repeatedly moved for each layer with the heat exchange plate 111 interposed therebetween and the outdoor air flow path 113 through which the outdoor air O moves are formed, I) and the outdoor air (O) are flowing.

The exhaust duct 200 has one end connected to the indoor 1 and the other end connected to the first distributor 120 so that the indoor air I exhausted from the indoor 1 is discharged to the heat exchange duct 110 . Here, the exhaust duct 200 is preferably installed on the inner wall 4 between the apartment house 1 and the verandah 3.

One end of the air supply duct 300 is connected to the indoor 1 and the other end is connected to the first distributor 120 so that outdoor air O supplied through the outdoor air flow path 113 flows into the indoor 1 So as to be guided in a radial direction. The air supply duct 300 is preferably installed on the inner wall 4 between the apartment room 1 and the veranda 3. Here, it is preferable that the exhaust duct 200 and the air supply duct 300 are installed on the inner wall 4 at a distance of about 1.5 meters.

One end of the inlet duct 400 is connected to the outdoor 2 and the other end is connected to the second distributor 130. The outdoor air O sucked from the outdoor 2 is supplied to the heat exchanging duct 110 . The inflow duct 400 is preferably installed on the outer wall 5 between the veranda 3 and the outdoor 2. [

One end of the exhaust duct 500 is connected to the outdoor unit and the other end thereof is coupled to the second distributor 130 so that indoor air O discharged through the indoor unit flow path 112 is discharged to the outdoor 2 . It is preferable that the exhaust duct 500 is installed on the outer wall 5 between the veranda 3 and the outdoor 2.

2, the heat exchange duct 110 is provided with a pair of left and right sides and a heat exchange plate 111 is stacked in a multilayer structure in a case 114 formed by bending in a substantially " . That is, a plurality of support protrusions 114a are formed at the inner side of the case 113, the support protrusions 114a having the support grooves 114b in which the end portions of the heat exchange plate 111 are fitted and supported, 113 are formed at a central end portion thereof with a hook portion 114c along the left and right direction and a hook groove 114d through which the hook portion is fitted so that the pair of cases 114 are fitted together. Therefore, since the heat exchange duct 110 is constructed as a prefabricated type, the heat exchange duct can be easily configured.

The first distributor 120 is connected to one end of the heat exchange duct 110 and supplies the air discharged from the indoor unit 1 to the indoor unit flow path 112 and the air supplied through the outdoor unit flow path 113 Is supplied to the indoor unit (1). The second distributor 130 is connected to the other end of the heat exchange duct 110 and discharges the air supplied through the indoor unit flow path 112 to the outdoor 2 and flows into the outdoor 2 And the air is supplied to the outdoor air flow path (113).

3 and 4A, the first distributor 120 is provided with a front opening 121a and a rear opening 121b at the front and rear sides thereof, and the front opening 121a An indoor unit inlet port 121c to which the other end of the exhaust duct 200 is coupled and an outdoor air inlet port 121d to which the other end of the air supply duct 300 is coupled is formed on one side of the center, The opening 121b is formed with a first distribution enclosure 121 to which one end of the heat exchange duct 110 is coupled.

4B, a front fitting pipe 121e is formed in front of the first distribution enclosure 121 so that the exhaust duct 200 and the air supply duct 300 are fitted and coupled, And a rear fitting pipe 121f is formed at the rear of the housing 121 so that one end of the heat exchanging duct 110 is fitted to the rear fitting pipe 121f.

As shown in FIG. 5, a triangular plate 122a, which is provided in the first distribution enclosure 121 and is formed in multiple layers vertically spaced apart from the heat exchange plate 111, is formed. Here, the triangular plate 122a is formed in such a shape that the width of the triangular plate 122a increases toward the rear end with respect to the center of the front opening 121a, and the rear end thereof is tightly coupled to the end of the corresponding heat exchange plate 111. [ That is, the rear end of the triangular plate 122a is configured to be closely fitted to the end of the heat exchange plate 111 while being inserted into the support groove 114b. The exhaust duct 200 is connected to the even layer between the triangular plates 122a via a first closing member 122b closing an odd layer end between the triangular plates 122a at one side of the triangular plate 122a An indoor unit inlet path 122c communicating with the indoor unit flow path 112 is formed and a second closing member 122d closing the even layer end between the triangular plates is formed on the other side of the triangular plate 122a, The first distribution portion 122 is formed in the odd-numbered layers of the outdoor unit inlet passage 122e to communicate with the air supply duct 300 and the outdoor unit flow passage 113. [ That is, the indoor air I discharged through the exhaust duct 200 is exhausted to the indoor air flow path 112 through the indoor air inflow path 122c and the outdoor air O supplied through the air supply duct 300, Is introduced into the outdoor air inflow path (122e) through the indoor unit flow path (113).

6 and 7, the second distributor 130 is provided with a front opening 131a and a rear opening 131b at the front and rear sides thereof, and the front opening 131a is provided with the heat exchange duct 110 And the other end of the inflow duct 400 is coupled to the other end of the inflow duct 400. The other end of the inflow duct 400 is coupled to the other end of the inflow duct 400, And a second distribution enclosure 131 in which the indoor unit outlet port 131d to which the other end is coupled is formed. A triangular plate 132a, which is provided in the second distribution enclosure 131 and is formed as a multi-layered structure vertically spaced apart from the heat exchange plate 111, is formed. The triangular plate 132a is provided with a triangular plate 132a whose width gradually increases toward the front end with respect to the center of the rear opening 131b and the front end of the triangular plate 132a is in tight contact with the end of the corresponding heat exchange plate 111 .

8, on one side of the triangular plate 132a, an odd-numbered layer between the triangular plates 132a is provided with a third closing member 132b closing the odd-numbered layer ends, And the outdoor unit discharge path 132c communicating with the duct 300 and the outdoor unit flow path 113. The other end of the triangular plate is connected to the triangular plate through a fourth closing member 132d closing the odd- And a second distribution part 132 forming an indoor unit discharge passage 132e communicating with the discharge duct 500 and the indoor unit flow passage 112 in an even number of layers between the plates. That is, the outdoor air O flowing through the outdoor air flow path 113 is supplied to the air supply duct 300 through the outdoor air discharge path 132e and the indoor air I discharged through the indoor air flow path 112, Is discharged to the discharge duct (500) through the indoor unit discharge path (132e).

9, a first connector 140 may be further provided between the first distributor 120 and the exhaust duct 200 and the air supply duct 300. That is, the first connection port 140 includes a side plate 141b bent downward from a side end of the upper plate 141a and a lower plate 141a, and a partition plate 141c extending downward from the center of the upper plate to partition both sides, . A front exhaust port 141d is formed on one side of the front surface of the first connection port 130 to connect the exhaust duct 200. A front inlet port 141e is formed on the other side of the front surface of the first connection port 130, A rear exhaust port 141f connected to the indoor air inlet port 121c is formed at a rear side of the rear surface of the vehicle body and a rear inlet port 141g connected to the outdoor air inlet port 121d is formed at the rear side of the rear surface. A lower plate 142a having a water discharge hole 142b and a lower plate 142b which is formed to close the lower end of the connector body 141 and which is upwardly extended from a side end of the lower plate 142a and is in close contact with the outer surface of the side plate 141b And a water receptacle 143 that is connected to the lower side of the connector cover 142 and stores condensed water discharged through the water discharge hole 142b . That is, the first connection port 140 connects the first distributor 120 to the exhaust duct 200 and the inlet duct 400, and the condensation water generated during the heat exchange of the heat exchange duct 110 is connected to the first connection port 140 And discharged through the water discharge hole 142b so as to be collected in the water receiver 143.

A second connection port 150 is formed between the second distributor 130 and the inlet duct 400 and the outlet duct 500. The second connection port 150 is connected to the upper plate 151a and the upper plate 151a And a partition plate 151c extending downward from the center of the upper plate and partitioning both sides of the upper plate 151b. A front face air supply mechanism 151d connected to the outdoor air supply mechanism 131c is formed on one side of the front face of the second connector 150 and a front air outlet 151e connected to the indoor air outlet 131d is formed on the other side of the front face And a rear outlet 151e connected to the outlet duct 500 is formed on the other rear side of the second connection port 150. The rear outlet 151e is connected to the inlet duct 400, A connector body 151 is formed. A lower plate 152a having a water discharging hole 152b formed therein and an upper end extending upward from a side end of the lower plate and being in close contact with an outer surface of the side plate 151b, And a water receiver 153 which is connected to a lower side of the connector cover 152 and stores condensed water discharged through the water discharge hole 152b. That is, the second connector 150 connects the second distributor 130 to the air supply duct 300 and the discharge duct 500, and the condensation water generated during the heat exchange of the heat exchange duct 110 is connected to the second connector 150 Through the water discharge hole 152b to be collected in the water receiver 153.

On the other hand, an inlet fan F1 is further installed on the inlet duct 400 so that the outdoor air O is forcibly supplied to the heat exchange duct 110. On the outlet duct 500, It is preferable that a discharge fan F2 is installed so as to be forcedly discharged through the duct 500. [ That is, the outdoor air O and the indoor air I are easily supplied and discharged through the inlet fan F 1 installed in the inlet duct 400 and the outlet fan F 2 installed in the outlet duct 500 .

10 and 11, it is preferable that a filter box 600 for filtering impurities from the outside air introduced from the outside is installed on the inflow duct 400. Specifically, the filter box 600 is formed with an opening / closing door 611 at the front, an installation space is formed therein, and an inlet duct 400 is connected to an upper end of a rear side of the filter box 600 to introduce inflow air (O) A filter housing 610 in which an inlet duct 400 is connected to the upper center of the front face to form a discharge hole 613 through which filtered external air is discharged, And the air introduced into the inlet hole 612 from the air inlet chamber 622 to the filter chamber 621 is divided into a filter chamber 621 and an air inlet chamber 622, A partition plate 623 having a filter chamber 623a formed therein and a filter mounting plate 630 formed inside the filter chamber 621 and having a fitting groove 632 through which the upper and lower ends of the filter 631 are selectively fitted, . That is, the filter box 600 receives the outdoor air O received through the inflow hole 612 into the air inflow chamber 623 and then through the communication hole 623a of the partition partition to the filter chamber 612 And the clean air is supplied to the inflow duct 400 through the discharge hole 613 after the foreign matter is filtered while being moved backward from the front side of the filter 631. It is preferable that a transparent window 611a is formed on the front surface of the opening and closing door 611 so that the internal filter 631 can be confirmed. Here, the present invention is advantageous in that not only the heat exchanger and the filter box are separately formed, but also the air purifying ability is excellent, the contamination status of the filter can be easily checked, and the filter can be easily replaced in the filter box.

In the ventilation system having the high efficiency heat exchanger according to the first embodiment of the present invention, as shown in FIG. 12, there is provided a heat exchanger 100 forming a heat exchange structure through a multi-layered heat exchange plate 111 , The outdoor air (O) flowing through the outdoor air flow path in the heat exchange structure of the heat exchanger and the indoor air (I) moving through the indoor air flow path are crossed to perform heat exchange a number of times, So that the fuel cost can be reduced and the comfort of life can be improved.

13 to 22 show a second embodiment of a ventilation system with a high efficiency heat exchanger according to the present invention. The second embodiment according to the present invention differs from the first embodiment in the structure of the heat exchanger and the structure of the indoor air circulation, and other constituent elements and actions and effects are the same.

Referring to FIG. 13, a ventilation system having a high efficiency heat exchanger according to a second embodiment of the present invention includes a heat exchanger 100, an exhaust duct 200, an inlet duct 400, an outlet duct 500, 300 and a circulating duct 700. [

The heat exchanger 100 is a part configured to exchange heat while exchanging indoor air I discharged from the indoor 1 and outdoor air O flowing through the outdoor 2. Here, the heat exchanger 100 is preferably installed in the veranda 3 of the apartment.

The heat exchanger 100 may include a heat exchanging duct 150, a third distributor 160, and a fourth distributor 170. Here, the heat exchange duct 150 has a multilayer structure in which a plurality of heat exchange plates 151 having a predetermined length are spaced apart from each other by a predetermined distance, and a multi-layer flow path is formed in which air moves through the heat exchange plate 151 do. The middle layer portion of the flow path includes an indoor unit flow passage 152 in which the indoor air I is repeatedly moved for each layer with the heat exchange plate 151 interposed therebetween and an outdoor air flow passage 153 through which the outdoor air O moves. And the indoor air circulation flow path 154 in which the indoor air I moved along the indoor air flow path is circulated is formed in the middle of the flow path and the uppermost layer and the lowermost layer, So that the heat exchange is performed.

One end of the exhaust duct 200 is connected to the indoor 1 and the other end is coupled to the third distributor 160 so that the indoor air I exhausted from the indoor 1 is discharged to the heat exchange duct 150 . Here, the exhaust duct 200 is preferably installed on the inner wall 4 between the apartment house 1 and the verandah 3.

One end of the inlet duct 400 is connected to the outdoor 2 and the other end is connected to the third distributor 160 of the heat exchanger 100 so that the outdoor air O sucked from the outdoor 2 To be supplied to the duct (150). The inflow duct 400 is preferably installed on the outer wall 5 between the veranda 3 and the outdoor 2. [

The indoor air I discharged through the indoor unit circulation channel 152 is discharged to the outside 2 through the indoor air circulation passage 152, As shown in FIG. It is preferable that the exhaust duct 500 is installed on the outer wall 5 between the veranda 3 and the outdoor 2.

One end of the air supply duct 300 is connected to the indoor 1 and the other end of the air supply duct 300 is connected to the fourth distributor 170 so that the outdoor air O supplied through the outdoor air flow path 153 flows into the indoor 1 So as to guide the supply. The air supply duct 300 is preferably installed on the inner wall 4 between the apartment room 1 and the veranda 3.

The circulation duct 700 is coupled to the fourth distributor 170 at both ends thereof to circulate the indoor air I discharged through the indoor unit flow path 152 to the indoor unit circulation flow path 154.

14, the heat exchange duct 150 is provided with a pair of left and right sides and a heat exchange plate 151 is stacked in a multilayer structure in a case 155 which is bent in a substantially " . A plurality of support protrusions 155a are formed at the inner side of the case 155 so that the end portions of the heat exchange plate 151 are fitted and supported in the vertical direction. (155c) and a hook groove (155d) to which the hook is fitted, and the pair of cases (155) are fitted to each other. Therefore, since the heat exchange duct 150 is constructed as a prefabricated type, the heat exchange duct can be easily configured.

The third distributor 160 is connected to one end of the heat exchange duct 150 so that the air discharged from the indoor unit 1 is supplied to the indoor unit flow path 152 and the air introduced from the outdoor unit 2 flows into the outdoor unit flow path 152. [ And the air circulated through the indoor unit circulation flow path 154 is discharged to the outside of the room. The fourth distributor 170 is connected to the other end of the heat exchange duct 150 so that the air supplied through the outdoor air flow path 153 is supplied to the indoor space 1 and flows through the indoor air flow path 152 And the air to be supplied is circulated and supplied to the indoor unit circulating flow path 154.

15 and 16A, the third distributor 160 is provided with a front opening 161a and a rear opening 161b at the front and rear sides thereof, and the front opening 161a An indoor unit exhaust port 161c to which the other end of the exhaust duct 200 is coupled is formed at the center and an outdoor air inlet port 161d to which the other end of the inlet duct 400 is coupled is formed at one side of the indoor unit exhaust port 161c And an outdoor air discharge port 161e to which the other end of the discharge duct 500 is coupled is formed on the other side of the indoor unit exhaust port 161c. In the rear opening 161b, A distribution enclosure 161 is constructed. 16B, a front fitting pipe 161i is fitted to the front of the third distribution enclosure 161 so that the exhaust duct 200, the inlet duct 400, and the exhaust duct 400 are fitted and engaged with each other. And a rear fitting pipe 161j is formed at the rear of the first distribution enclosure 121 so that one end of the heat exchanging duct 150 is inserted and coupled.

17, a third distribution unit 162 is provided in the third distribution enclosure 161. In addition, First, the third distributor 162 is provided with a triangular plate 162a having a plurality of layers spaced apart from each other by a predetermined distance in correspondence with the heat exchange plate 151 and having a width widened toward the rear end, And is tightly coupled to the end of the corresponding heat exchange plate 151. That is, the rear end of the triangular plate 162a is configured to be closely fitted to the end of the heat exchange plate 151 while being inserted into the support groove 155b.

The triangular plate, the uppermost layer and the lowermost triangular plate 162a-1 located in the middle of the triangular plate 162a starts from the other end of the indoor exhaust port 161c and is expanded in width toward both ends of the rear opening portion 161b The triangular plate 162a-2 between the triangular plate located in the center and the uppermost and lowermost triangular plates 161a-1 starts from one end of the indoor exhaust port 161c and extends to both ends of the rear opening 161b It has a shape that has a widened width.

Further, a triangular plate 162a-2 between the triangular plate located at the center and the triangular plate 162a-2 between the uppermost and lowermost triangular plates 162a-1 is provided with a middle layer between the triangular plates 162a-2 and a fifth The middle layer between the triangular plates 162a-2 through the closing member 162b and the outdoor air inflow path 162c communicating with the inflow duct 400 and the outdoor unit flow path 153 are formed in the uppermost layer and the lowermost layer, The exhaust duct 200 and the indoor unit flow path 152 are formed on the upper and lower layers between the triangular plates 162a-2 via the sixth closing member 162d closing the upper and lower ends of the plates 162a-2, Thereby forming an indoor unit inflow passage 162e communicating therewith.

One end portion of the uppermost triangular plate 161a-1, the upper one of the uppermost triangular plate 161a-1, the uppermost triangular plate 161a-1, 1 and the lowest triangular plate 161a-1 between the triangular plates 161a-1 located in the center via the seventh closing member 162f closing the other end between the lowest triangular plate 161a-1 and the lowest triangular plate 161a-1, The indoor unit discharge passage 162g communicating with the indoor unit circulation passage 154 and the discharge duct 500 is formed at the upper and lower sides of the indoor unit discharge passage 162g.

That is, the indoor air I exhausted through the exhaust duct 200 is exhausted to the indoor air flow path 152 through the indoor air inflow path 162e, and the outdoor air O flowing through the inflow duct 400 The indoor air I circulated through the indoor unit circulation passage 154 is discharged to the discharge duct 500 through the indoor unit discharge passage 162g through the outdoor unit inlet 162c, .

18 and 19, the fourth distributor 170 is provided with a front opening 171a and a rear opening 171b at the front and the rear, and the front opening 171a is connected to the heat exchanging duct 150 And a circulation inlet 171c through which one end of the circulation duct 700 is coupled to the center is formed in the rear opening 171b and the circulation duct 171c is connected to one end of the circulation duct 171c And the other end of the air supply duct 300 is connected to the other side of the circulation inlet 171c. The fourth distribution container 171d is formed at the other side of the circulation inlet 171c, and the other end of the air supply duct 300 is connected to the other end of the circulation inlet 171c. ).

20, the fourth distribution unit 172 is formed inside the fourth distribution enclosure 171, and the fourth distribution unit 172 is connected to the heat exchange plate 151, A triangular plate 172a having a width corresponding to the front end is provided so that the front end of the triangular plate 172a is closely contacted with the end of the corresponding heat exchange plate 151 do.

The triangular plate, the uppermost layer and the lowermost triangular plate 172a-1 located in the middle of the triangular plate 172a starts from one end of the circulation inlet 171c and expands in width toward both ends of the front opening 171a The triangular plate 172a-2 between the triangular plate located at the center and the uppermost and the lowest triangular plates 172a-1 starts to move from the other end of the circulation inlet 171c to both ends of the front opening 171a It has a shape that has a widened width. The triangular plate 172a-2 between the uppermost triangular plate 172a-1 and the uppermost triangular plate 172a-1 is provided with a middle layer between the triangular plates and an eighth closing member And the outdoor unit discharge passage 172c communicating with the air supply duct 153 and the air supply duct 300 are formed in the uppermost layer and the lowermost layer through the middle layer between the triangular plates 172a and 172b, It is preferable to form the indoor unit exhaust passage 172e communicating with the circulating duct 700 and the indoor unit flow passage 152 in the upper and lower layers between the triangular plates through the ninth closing member 172d closing the upper and lower ends .

The other end between the triangular plates 172a-1 located in the center and the other end of the uppermost triangular plate 172a-1, the lower end of the lowest triangular plate and one end between the uppermost triangular plate and the lowest triangular plate The circulation duct 700 and the indoor unit circulation flow path 154 (see FIG. 4) are provided above and below the uppermost and lowermost triangular plate 172a-1 between the triangular plates 172a-1 located in the center via the finishing tenth closing member 172f, The indoor unit circulation path 172g communicating with the indoor unit circulation path 172g is formed.

21, it is preferable that a third connection port 180 is further provided between the third distributor 160 and the exhaust duct 200, the inlet duct 400 and the outlet duct 500 . That is, the third connection port 180 includes a side plate 181b bent downward from a side edge of the upper plate 181a and the upper plate 181a, a partition plate 181b extending downward from both sides of the center of the upper plate, (181c). A front exhaust port 181d is formed at the center of the front surface of the third connection port 180. The front exhaust port 181e is connected to one end of the front exhaust port 181e. And a rear exhaust port 181g connected to the indoor air exhaust port 161c is formed at the rear center of the third connection port 180. The rear exhaust port 181g is connected to the rear exhaust port 181g, A rear inlet 181h connected to the outdoor air inlet 161d is formed at one side of the rear outlet 181g and a rear outlet 181i connected to the outdoor outlet 161e is connected to the rear outlet 181g, 181). A third connection cover 182 formed to close the lower side of the third connection port body 181 and having a water discharge hole 182b and a second connection port cover 182 coupled to the lower side of the third connection port cover 182b, And a water receiver 183 for storing the condensation water discharged through the discharge hole 182b. That is, the third connector 180 connects the third distributor 160 to the exhaust duct 200, the inlet duct 400 and the outlet duct 500, and at the same time, the number of condensed water generated during the heat exchange of the heat exchange duct Through the connection port 180, through the water discharge hole 182a, and to be collected in the water receiver 183.

A fourth connector 190 is further provided between the fourth distributor 170 and the air supply duct 300 and the circulating duct 700. That is, the fourth connector 190 includes a side plate 191b bent downward from a side edge of the upper plate 191a and the upper plate 191a, a partition plate 191b extending downward from both sides of the center of the upper plate, (191c). The fourth connection port 190 is formed with a front circulation inlet 191d connected to the circulation inlet 171c at the center of the front and a front side circulation inlet 191d connected to the circulation outlet 171d at one side of the front circulation inlet 191d. A circulation outlet 191e is formed and a front feed mechanism 191f connected to the outdoor air supply mechanism 171e is formed on the other side of the front circulation inlet 191e and connected to one end of the circulation duct 700 A rear circulation outlet 191h is formed at one side of the rear circulation inlet 191g and a rear circulation outlet 191h connected to the other end of the circulation duct 700. The rear circulation inlet 191g is connected to the rear circulation inlet 191g, And a fourth connector body 191 having a rear side air feed mechanism 191 i connected to the air supply duct 300 on the other side. A fourth connection cover 192 is formed on the lower side of the fourth connection port body 191 and has a water discharge hole 192b. The fourth connection port cover 192 is connected to the lower side of the fourth connection port cover 192, And a water receiver 193 for storing the condensation water discharged through the discharge hole 192b.

On the other hand, an inlet fan F1 is further installed on the inlet duct 400 so that the outdoor air O is forcibly supplied to the heat exchange duct 110. On the outlet duct 500, It is preferable that a discharge fan F2 is installed so as to be forcedly discharged through the duct 500. [ That is, the outdoor air O and the indoor air I are easily supplied and discharged through the inlet fan F 1 installed in the inlet duct 400 and the outlet fan F 2 installed in the outlet duct 500 .

Further, it is preferable that a filter box 600 for filtering impurities from outside air introduced from the outside is further provided on the inflow duct 400. Specifically, the filter box 600 is formed with an opening / closing door 611 at the front, an installation space is formed therein, and an inlet duct 400 is connected to an upper end of a rear side of the filter box 600 to introduce inflow air (O) A filter housing 610 in which an inlet duct 400 is connected to the upper center of the front face to form a discharge hole 613 through which filtered external air is discharged, And the air introduced into the inlet hole 612 from the air inlet chamber 622 to the filter chamber 621 is divided into a filter chamber 621 and an air inlet chamber 622, A partition plate 623 having a filter chamber 623a formed therein and a filter mounting plate 630 formed inside the filter chamber 621 and having a fitting groove 632 through which the upper and lower ends of the filter 631 are selectively fitted, . That is, the filter box 600 receives the outdoor air O received through the inflow hole 612 into the air inflow chamber 623 and then through the communication hole 623a of the partition partition to the filter chamber 612 And the clean air is supplied to the inflow duct 400 through the discharge hole 613 after the foreign matter is filtered while being moved backward from the front side of the filter 631. It is preferable that a transparent window 611a is formed on the front surface of the opening and closing door 611 so that the internal filter 631 can be confirmed. In addition, the inflow hole 612 can be formed through a pore by appropriately adjusting its position. In addition, the inflow hole 612 can be formed through a pore by appropriately adjusting its position. Here, the present invention is advantageous in that not only the heat exchanger and the filter box are separately constructed, but also the air purifying ability is excellent, the contamination state of the filter can be easily checked, and the filter can be easily replaced in the easy filter box.

In the ventilation system having the high efficiency heat exchanger according to the second embodiment of the present invention, as shown in FIG. 22, a heat exchanger 150 for forming a heat exchange structure is provided through a multi-layered heat exchange plate 151, The outdoor air O flowing through the outdoor air flow passage 153 and the indoor air I flowing through the indoor air flow passage 152 are crossed and heat exchanged many times in the heat exchange structure of the heat exchanger, Not only the heat exchange efficiency of the indoor air I is greatly increased but also the indoor air I discharged is circulated once again through the indoor unit circulation flow passage 154 to perform heat exchange with the outdoor air O moved through the outdoor air flow passage 153 And the heat exchange efficiency is further increased. Thus, it is advantageous in that the fuel cost can be reduced and the comfort of life can be improved.

100: Heat exchanger 200: Exhaust duct
300: inlet duct 400: outlet duct
500: Supply duct 600: Filter box
700: Circular duct

Claims (12)

An indoor unit flow path in which room air is repeatedly moved for each layer with the heat exchange plate therebetween, and an outdoor air flow path through which outdoor air flows are formed so as to have a predetermined length, And a heat exchange duct configured to perform outdoor air exchange with heat exchange;
A first distributor coupled to one end of the heat exchange duct and configured to supply air exhausted from the room to the indoor air flow path and air supplied through the outdoor air flow path to the room; and a second distributor coupled to the other end of the heat exchange duct A second distributor configured to discharge the air supplied through the indoor unit flow path to the outside, and to supply the air introduced from the outside to the outdoor unit flow path;
An exhaust duct connected at one end to the indoor and coupled at the other end to the first distributor to guide indoor air exhausted from the indoor to the heat exchange duct;
An air supply duct connected at one end to the indoor and connected at the other end to the first distributor to guide outdoor air supplied through the outdoor air flow path to the room;
An inlet duct connected at one end to the outdoor unit and connected to the second distributor at the other end to guide outdoor air sucked from the outdoor unit to the heat exchange duct,
And an exhaust duct connected to the outdoor, one end of which is coupled to the second distributor, and the indoor air exhausted through the indoor air flow path is discharged to the outside of the room,
Wherein the heat exchange duct is formed by a pair of left and right sides and is bent in a substantially "C" shape so that a plurality of heat exchange plates are stacked in a multilayer structure, and an end of the heat exchange plate A plurality of support protrusions each having a support groove for receiving and supporting each of them is formed, and at the center end of the case, a hook portion and a hook groove to be engaged with the hook portion are formed along the left and right direction, respectively, Wherein the high-efficiency heat exchanger is configured such that the high-efficiency heat exchanger is constructed to be a high-efficiency heat exchanger.
delete The method according to claim 1,
Wherein the first distributor comprises:
And an outdoor unit inlet port through which the other end of the air supply duct is coupled to the other end of the indoor unit inlet port is formed in the front opening portion, A first distribution body in which one end of the heat exchange duct is coupled to the rear opening,
And a triangular plate which is provided in the first distribution enclosure and is spaced apart from the heat exchange plate by a predetermined distance so as to be widened toward a rear end with respect to a center of the front opening, And an indoor unit connected to the exhaust duct and the indoor unit flow path is connected to the even-numbered layer between the triangular plates through a first closing member that closes the odd-numbered floor end between the triangular plates at one side of the triangular plate, And an outdoor air inflow path communicating with the air supply duct and the outdoor air flow path is formed in the odd number layer between the triangular plates through the second closing member closing the even layer end between the triangular plates at the other side of the triangular plate And a first distributor,
Wherein the second distributor comprises:
The front opening and the rear opening are formed at the front and rear sides, the other end of the heat exchange duct is coupled to the front opening, and the outdoor air supply mechanism is formed at the rear opening to connect the other end of the inflow duct to one side with respect to the center A second distribution enclosure having an outlet port for the indoor unit to which the other end of the discharge duct is coupled,
A triangular plate provided in the second distribution enclosure and formed in a multi-layered structure spaced vertically and spaced apart from the heat exchange plate in correspondence with the heat exchange plate, the triangular plate having a wider width toward the front end with respect to a center of the rear opening, And a third closing member closing an even layer end between the triangular plates is connected to the odd number layer between the triangular plates at one side of the triangular plate so as to be in intimate contact with the end of the heat exchange plate. An exhaust duct and an indoor unit exhaust passage communicating with the indoor unit flow path are formed in the even-numbered layers between the triangular plates through the fourth closing member closing the odd-numbered floor end between the triangular plates at the other side of the triangular plate And a second distributor for distributing the heat to the heat exchanger.
The method of claim 3,
A first connector is further provided between the first distributor and the exhaust duct and the air supply duct,
The first connector is composed of a side plate bent downward from a side end of the upper plate and the upper plate, and a partition plate extending downward from the center of the upper plate to divide both sides of the upper plate, and a front exhaust port connected to the exhaust duct is formed at one side of the front And a rear inlet port connected to the indoor air inlet port on one side of the rear side and a rear inlet port connected to the outdoor air inlet port on the rear side of the rear side,
A connection cover formed by closing a lower side of the connector body and having a lower plate formed with a water discharge hole and a latch piece extending upward from a side end of the lower plate to closely contact the outer surface of the side plate; And a water receiver for storing condensation water discharged through the water discharge hole,
A second connector is formed between the second distributor and the inlet duct and the outlet duct,
The second connecting port includes a side plate bent downward from a side end of the upper plate and the upper plate, and a partition plate extending downward from a center of the upper plate to partition the upper and lower plates. And a rear outlet port connected to the outlet duct is formed on the other side of the rear side of the rear outlet port, and a rear outlet port connected to the outlet duct is formed on the rear side of the rear outlet port.
A connection cover formed by closing a lower side of the connector body and having a lower plate formed with a water discharge hole and a latch piece extending upward from a side end of the lower plate to closely contact the outer surface of the side plate; And a water receiver for storing condensation water discharged through the water discharge hole.
The method according to claim 1,
An inlet fan is further installed on the inlet duct so that outdoor air is forcedly supplied to the heat exchange duct,
And a discharge fan is installed on the discharge duct so that room air is forcibly discharged through the discharge duct.
The method according to claim 1,
A filter box for filtering impurities from outside air introduced from the outside is further provided on the inflow duct,
The filter box has an opening and closing door formed at a front side thereof, an installation space formed therein, an inlet duct connected to an upper end of a rear side of the rear side to form an inflow hole for introducing outside air, A filter chamber provided at one side of the inside of the filter housing to divide the filter chamber into an air inlet chamber and a communication hole through which external air introduced into the inlet hole in front of the lower end portion is transferred from the air inlet chamber to the filter chamber, And a filter mounting plate formed in the filter chamber and having a fitting groove for selectively engaging upper and lower ends of the filter.
delete delete delete delete delete delete

Images