KR100628058B1 - Total heat exchanger and ventilation system using the same - Google Patents

Abstract

The present invention is to provide a heat exchanger having a high heat transfer efficiency and a ventilation system using the same by increasing the heat exchange area. The present invention provides a heat exchange device that is installed in an area where an air supply passage that serves as a passage through which outdoor air is supplied to an indoor space and an exhaust passage that serves as a passage through which indoor air is discharged to the outside intersects the heat exchanger; An air supply fan connected to the air supply passage and configured to suck the outdoor air and discharge the indoor air; And an exhaust fan connected to the exhaust flow path for inhaling the indoor air and discharging the indoor air to the outside, wherein the cross section of the heat exchange element has a polygonal shape in which a horizontal or vertical length is longer than another in a direction perpendicular thereto. And a ventilation system using the same.

According to the above configuration, even if the height of the heat exchanger is not increased, the shape of the heat exchange element can be changed to increase the heat transfer efficiency.

Heat exchanger, heat exchange element, ventilation system

Description

Total heat exchanger and ventilation system using the same

1 is a perspective view showing the internal structure of a conventional total heat exchanger;

Figure 2 is a cross-sectional view showing a flow of air passing through the heat exchange element and the conventional heat exchange element.

3 is a cross-sectional view showing the flow of air passing through the heat exchange element and the heat exchange element according to the first embodiment of the present invention;

Figure 4a is a graph showing the temperature change according to the flow path length during indoor cooling operation;

Figure 4b is a graph showing the temperature change according to the flow path length during indoor heating operation;

5 is a perspective view showing the internal structure of the total heat exchanger according to the second embodiment of the present invention;

6 is a cross-sectional view showing the flow of air passing through the heat exchange element and the heat exchange element according to a second embodiment of the present invention;

7 is a perspective view showing the internal structure of the total heat exchanger according to the third embodiment of the present invention;

8 is a schematic view showing a ventilation system according to an embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

 10: supply flow path 11: supply flow path inlet

 12: Air supply passage outlet 13: Air supply fan

 17: supply side chamber 20: exhaust passage

 21: exhaust passage inlet 22: exhaust passage outlet

 23: exhaust fan 24: exhaust passage first inlet hole

 25: exhaust flow passage second inlet hole 26: exhaust bypass passage

 27: exhaust chamber 100: total heat exchanger

130: supply fan-motor assembly 131: supply fan

132: air supply flow path motor 200: total heat exchanger
230: exhaust fan-motor assembly 231: exhaust fan
232: exhaust passage motor 500: first duct portion
510: first duct portion diffuser 600: second duct portion
610: second duct unit diffuser

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The present invention relates to a total heat exchanger and a ventilation system using the same, and more particularly to a ventilation system that can increase the heat transfer efficiency by increasing the heat exchange area by improving the structure.

The air in a closed room is gradually polluted over time, such as by the breathing of a person active in the room. Therefore, indoor polluted air should be replaced with fresh air from time to time. For this purpose, a heat exchanger and a ventilation system using the same are generally used. The total heat exchanger is a device for supplying outside air and exhausting the indoor air while maintaining the temperature of the indoor air.

Referring to Figure 1, when describing the heat exchanger according to the prior art as follows.

The general heat exchanger is installed in an area where an air supply passage 10 serving as a passage through which outdoor air is supplied to an interior and an exhaust passage 20 serving as a passage through which indoor air is discharged to the outside are intersected. Is connected to the heat exchange element (5), the air supply passage (10) for the heat exchange, and the air supply fan (13) for sucking and discharging the outdoor air into the room, and connected to the exhaust flow path (20) to suck the indoor air. And an exhaust fan 23 for discharging to the outside.

The heat exchange element 5 is installed in a region where the air supply passage 10 and the exhaust passage 20 cross each other, and a heat passage (not shown) through which indoor air passes and outdoor air pass through the heat exchange element 5. A flow path (not shown) is formed. At this time, the total heat exchanger (1) heat-exchanges the indoor air and the outdoor air by using a temperature and humidity difference in the heat-exchange film forming the layers of different flow paths.

More specifically, the heat exchange element 5 allows each air having a temperature difference to pass through different flow paths, whereby moisture and sensible heat exchange latent heat by high-efficiency heat exchange membranes forming layers of the different flow paths. Follow the principle of electrothermal exchange by heat exchanging.

In addition, the heat exchange element 5 generally has a square pillar shape having a rectangular cross section.

On the other hand, one side of the heat exchange element 5 may be provided with a filter (not shown). The filter serves to filter out foreign substances contained in the air, which is generally detachably coupled to the heat exchanger. to be.

In addition, one end of the air supply passage 10 is formed with an air supply passage inlet 11 communicating with the outdoors, and the other end is formed with an air supply passage outlet 12 communicating with the interior. At one end of the exhaust flow path 20, an exhaust flow path inlet 21 communicating with the interior is formed, and at the other end, an exhaust flow path outlet 22 communicating with the outside is formed.

 In addition, the air supply passage 10 is provided with an air supply fan 13 for forcibly suctioning the outdoor air from the outside to the room, and on the exhaust flow path 20 to forcibly suck the polluted air in the room to discharge to the outside. An exhaust fan 23 is provided. In addition, the air supply fan 13 and the exhaust fan 23 are positioned inside each air supply / exhaust fan housing. On the other hand, a motor (not shown) for driving the fan is mounted on the front side of the air supply fan housing and the exhaust fan housing.

Referring to the operation of the ventilation system configured as described above are as follows.

First, when power is applied to the exhaust fan 23 when the indoor air is somewhat contaminated, the indoor air flows into the exhaust flow path 20 through the exhaust flow inlet 21 and passes through the exhaust flow path 20. Indoor air passes through the heat exchange element 5 in a diagonal direction. The indoor air passing through the heat exchange element 5 flows along the exhaust flow path 20, and then is discharged to the outside through the exhaust flow path outlet 22.

At the same time, the outdoor air flows into the air supply passage 10 through the air supply passage inlet 11, and then passes through the heat exchange element 5 in a diagonal direction. The outdoor air passing through the heat exchange element 5 flows along the air supply passage and then is supplied to the room through the air supply passage outlet 12.

Through this process, the indoor air and the outdoor air passing through the heat exchange element 5 are mutually heat exchanged so that outdoor air having an appropriate temperature is supplied to the room.

On the other hand, indoor air is largely exhausted to the outside through two directions. First, the air flowing into the exhaust flow path inlet 21 is heat-exchanged through the heat exchange element 5 and the outdoor air at the air supply flow path inlet 11 via the exhaust flow path first inlet 24 and then discharged to the outside. Alternatively, the outdoor air is directly discharged to the outside by the forced suction force of the exhaust fan 23 without passing through the heat exchange element 5.

In the latter case, it includes an exhaust bypass passage 26 so that the indoor air can be directly discharged to the exhaust passage outlet 22, and the air introduced through the exhaust passage inlet 21 is the exhaust passage second inlet hole ( Through 25, the bypass flow path 26 flows. In addition, a damper may be provided at the inlet of the exhaust passage to flow air into the bypass passage 26.

Through such a configuration, when the temperature and humidity difference between indoor and outdoor is small, such as spring and autumn, since the heat exchange element 5 does not go through, the pressure loss through the heat exchange element 5 does not occur, and as a result, Reduced load can save power consumption.

However, the above-mentioned heat exchanger had the following problems.

First, the height of the heat exchanger is limited due to the height limitation of the ceiling in the architectural design, and thus the height of the heat exchange element is limited. Therefore, due to the limitation of the height of the heat exchange element, there is a limit in the heat exchange area, as a result there was a problem that the heat transfer efficiency of the total heat exchanger is relatively low.

Second, because the flow rate of air passing through the heat exchange element is high, the heat exchange is not effective in the heat exchange element, the efficiency of the total heat exchanger was low.

Third, the heat exchange element has a large bending in the flow direction of the air supply passage and the exhaust passage, there was a problem that the pressure loss through the flow path is high.

The present invention is to solve the above problems, an object of the present invention is to increase the heat exchange area and the length of the flow path without increasing the height of the total heat exchanger, to increase the heat transfer efficiency of the total heat exchanger and the ventilation using the same heat exchanger To provide a system.

Another object of the present invention is to provide a total heat exchanger and a ventilation system using the same, in which heat exchange is effectively performed in a heat exchange element by lowering a flow rate of air.

Still another object of the present invention is to provide a total heat exchanger and a ventilation system using the same, by reducing the curvature on the flow path of the air supply passage and the exhaust passage, thereby reducing the pressure loss generated through the passage.

In order to achieve the above object, the present invention is installed in the area where the air supply passage which is a passage for supplying the outdoor air and the exhaust passage which is a passage for discharging the indoor air to the outside is intersected, Heat exchange elements for allowing indoor air to heat exchange; An air supply fan connected to the air supply passage and configured to suck the outdoor air and discharge the indoor air; And an exhaust fan connected to the exhaust flow path for inhaling the indoor air and discharging the indoor air to the outside, wherein the cross section of the heat exchange element has a polygonal shape in which a horizontal or vertical length is longer than another in a direction perpendicular thereto. To provide.

The cross section of the heat exchange element is preferably substantially rectangular. In addition, the cross section of the heat exchange element is more preferably made of a substantially rhombus shape.

 According to a second embodiment of the total heat exchanger according to the present invention, a plurality of heat exchange elements are provided, and each heat exchange element is arranged in series with respect to the flow direction of air. In addition, the air supply passage and the exhaust passage are preferably configured such that air flowing therein passes through the heat exchange elements arranged in series in a zigzag form.

On the other hand, the electrothermal heat exchanger, it is more preferred that the exhaust passage flow passage, the outdoor air does not pass through the heat exchange element, the exhaust bypass passage for exhausting directly to the outdoor by the forced suction force of the exhaust fan. The electrothermal heat exchanger may further include an air supply bypass passage, which is partitioned from the air supply passage, so that outdoor air is directly supplied to the room by a forced suction force of the intake fan without passing through the heat exchange element. In addition, the total heat exchanger, it is preferable to include a filter for filtering foreign matter contained in the outdoor air on the air supply passage.

According to the third embodiment of the total heat exchanger according to the present invention, the rotation axes of the air supply fan and the exhaust fan are perpendicular to the discharge direction of the outdoor air and the discharge direction of the indoor air, respectively. The air supply fan and the exhaust fan may be provided in plural numbers, and the plurality of air supply fans and the exhaust fan may be driven by one motor. In addition, the air supply fan side and the exhaust fan side is preferably provided with a chamber for storing the air discharged by the fan, respectively.

On the other hand, the ventilation system according to the present invention, the total heat exchanger; A first duct portion communicating with the air supply passage of the heat exchanger and the interior, and having a diffuser for supplying outdoor air at an end thereof; In addition, the exhaust passage of the total heat exchanger and the inside of the room, and comprises a second duct portion is provided with a diffuser for suctioning the indoor air at the end.

Hereinafter, with reference to the accompanying drawings, it will be described in detail a preferred embodiment of the vacuum cleaner according to the present invention.

2 to 4b, the first embodiment of the total heat exchanger according to the present invention will be described.

Figure 2 is a cross-sectional view showing a heat exchange element of the conventional total heat exchanger, Figure 3 is a cross-sectional view showing a heat exchange element of the total heat exchanger according to the present invention. And, Figure 4a is a graph showing a temperature change according to the passage length of the indoor air and outdoor air during the indoor cooling operation, Figure 4b is a schematic diagram of the temperature change according to the passage length of the indoor air and outdoor air during the indoor heating operation It is a graph.

The basic configuration of the first embodiment of the total heat exchanger according to the present invention is the same as that of the conventional total heat exchanger. That is, a heat exchange element 50a for exchanging outdoor air and indoor air and an air supply fan 13 connected to the air supply passage 10 to suck and discharge the outdoor air into the indoor air are connected to the exhaust air passage 20. And an exhaust fan 23 which sucks the indoor air and discharges it to the outside. However, the cross-sectional shape of the heat exchange element 50a is made of a polygon that is longer than the other length in which the horizontal or vertical length is orthogonal thereto, unlike the conventional art.

As described above, when the total heat exchanger is installed on the ceiling of the building, the height of the total heat exchanger is limited due to limitations in the architectural design. Therefore, the vertical length of the heat exchange element 50a directly connected with the height of the total heat exchanger also comes with limitations.

On the other hand, the heat transfer efficiency of the total heat exchanger depends on how efficiently the indoor air and the outdoor air can be heat exchanged in the heat exchange element (50a), so in order to obtain a predetermined heat transfer efficiency, the cross-sectional area of the heat exchange element (50a) must be increased. . However, there is a limit in increasing the vertical length of the heat exchange element 50b due to the limitation of architectural design.

As such, the improvement in heat transfer efficiency and the minimization of the vertical length of the heat exchange element 50a have a mutually conflicting relationship. In recognition of this problem, the present invention increases the cross-sectional area of the heat exchange element 50b without increasing the height of the heat exchange element 50a by increasing the horizontal length longer than the vertical length of the heat exchange element 50a. I figured it out.

By forming the cross-sectional area of the heat exchange element 50a, even if the height of the ceiling on which the heat exchanger is installed is increased, the amount of heat exchanged by the heat exchange element 50b can be increased and consequently, the heat transfer efficiency of the heat exchanger can be improved. have.

In addition, the length of the flow path of the air flowing through the heat exchange element 50a is increased by increasing the horizontal length of the heat exchange element 50b than the vertical length as described above, and by decreasing the flow velocity of the flowing air, the heat exchange element At 50a, heat exchange can be made more efficiently.

This advantage can be clearly seen through FIGS. 2 and 3. That is, comparing FIG. 2 showing the cross-sectional shape of the conventional heat exchange element 50a with FIG. 3 showing the cross-sectional shape according to the present invention, even if the height of the heat exchange element 50a is the same, the heat exchange element 50a according to the present invention. ) Can be seen that the cross-sectional area is larger, the length of the flow path is also increased.

In addition, although the polygonal shape of the heat exchange element 50a having the above technical characteristics is not limited, it is preferable that the cross section of the heat exchange element 50a has a rhombus shape in a rectangular cross section generally applied in the current heat exchanger. .

On the other hand, by forming the cross section of the heat exchange element 50a in a rhombus shape whose length in the horizontal direction is longer than the length in the vertical direction, it is possible to reduce the flow direction bending of the air supply flow path and the exhaust flow path, thereby reducing the pressure loss in the flow path relatively. There is an advantage to this.

Unlike the above, in the case of installing the total heat exchanger on the side of the building, the length in the vertical direction of the heat exchange element 5 should be formed longer than the length in the horizontal direction. In this way, while the horizontal length of the heat exchanger installed on the side is constant, the heat transfer efficiency can be increased by increasing the heat exchange area and the length of the flow path.

Referring to Figures 4a and 4b, the temperature change according to the flow path length of the conventional heat exchange element and the heat exchange element according to the present invention will be described.

First, assuming that the indoor cooling operation during the summer, the temperature of the indoor air is formed relatively lower than the temperature of the outdoor air. The temperature difference between the indoor temperature and the outdoor temperature is reduced by heat exchange by the heat exchange element 50a of the total heat exchanger. The outdoor air having a relatively high temperature exchanges with the indoor air discharged to the outside, and is lower than the actual outdoor air temperature. It is supplied indoors in a state. At this time, as shown in Figure 4a, the heat exchange occurs more effectively in the cross-sectional shape according to the present invention than the cross-sectional shape of the conventional heat exchange element, as a result, the temperature difference between the outdoor air supplied to the room and the indoor air discharged to the outdoor Can be further reduced.

In the indoor heating operation in winter, the temperature of the indoor air is formed relatively higher than the temperature of the outdoor air in contrast to the above. In this case, as shown in Figure 4b, the heat exchange occurs more effectively in the cross-sectional shape according to the present invention than the cross-sectional shape of the conventional heat exchange element 50a, as a result of the outdoor air supplied to the indoor and the indoor air discharged to the outdoor Can further reduce the temperature difference.

5 and 6, the second embodiment of the total heat exchanger according to the present invention will be described.

The basic configuration of the second embodiment of the total heat exchanger according to the present invention is the same as that of the first embodiment described above. However, a plurality of heat exchange elements 50b are formed, and each heat exchange element 50b is disposed in series with respect to the flow direction of air.

As described above, the vertical length of the heat exchange element is limited due to the limitation of the ceiling in the construction design, by arranging the heat exchange element 50b in series with the flow direction of air, the vertical direction of the heat exchange element 50b. It is possible to increase the heat exchange amount without increasing the length.

The internal flow air of the air supply passage 10 and the exhaust passage 20 passes through the series of heat exchange elements 50b arranged in a zigzag form as shown in FIG. 5, and consequently, the total heat exchange area and the length of the flow path. Will increase. In addition, the flow rate of air gradually decreases while passing through the heat exchange element 50b arranged in series, and such a decrease in flow rate has an advantageous effect in terms of heat exchange. As a result, it is possible to increase the heat transfer efficiency of the total heat exchanger by increasing the total heat exchange area and decreasing the air flow rate.

On the other hand, the heat exchange element is preferably detachably coupled to the heat exchanger. By this detachable structure, the heat exchange element can be easily assembled or separated.

The electrothermal heat exchanger includes an exhaust bypass passage 26 for exhaust gas. Through this, when the temperature and humidity difference between the indoor and outdoor is small, such as spring and autumn, the heat exchange element 50b does not go through, so that pressure loss does not occur through the heat exchange element 50b, thereby reducing power consumption by the load on the fan. You can save. In addition, although not shown in the drawing, it is more preferable that the heat exchanger also includes a bypass flow path for supplying air.

The electrothermal heat exchanger may further include a filter unit (not shown) that filters foreign substances contained in outdoor air on the air supply passage. Clean air can be supplied to the room while the outdoor air passes through the filter part through the filter part.

The filter unit, the photocatalyst air purifier is an antibacterial filter for removing bacteria in the air, a filter unit configured in the form of a fiber mat to collect large particles such as large dust, fine dust and volatile organic compounds passed through the filter unit It may be composed of a photocatalyst collector to remove the odor, a deodorizing filter to remove the odor, and anion generator, or a combination thereof.

Referring to Figure 7, a third embodiment of the total heat exchanger according to the present invention will be described.

In the present embodiment, the air supply fan-motor assembly 130 and the exhaust fan-motor assembly 230 are provided, respectively, and the rotation shafts of the air supply fan 131 and the exhaust fan 231 are discharge direction of the outdoor air and Each of them is perpendicular to the discharge direction of the indoor air. The air supply fan 131 and the exhaust fan 231 are provided in plural numbers, and the plurality of air supply fans 131 and the exhaust fan 231 are driven by one motor 132 and 232, respectively. In addition, an air supply passage chamber 17 and an exhaust flow passage chamber 27 for storing the air discharged by the fan are provided at the air supply fan 131 side and the exhaust fan 231 side.

The rotation shafts of the air supply fan 131 and the exhaust fan 231 were generally configured in the same direction as the discharge direction of the outdoor air and the discharge direction of the indoor air. However, in this embodiment, the rotation shafts of the air supply fan 131 and the exhaust fan 231 are configured perpendicularly to the discharge direction of the outdoor air and the discharge direction of the indoor air, respectively.

The air supply fan 131 and the exhaust fan 231 may be provided in plural, and the air supply fan 131 and the exhaust fan 231 may be driven by a single motor, thereby increasing the air volume. In Figure 6, the air supply fan 131 and the exhaust fan 231 is composed of two.

Meanwhile, an air supply passage chamber 17 and an exhaust flow passage chamber 27 for storing air discharged by the fan are provided at the air supply fan 131 side and the exhaust fan 231 side, respectively, and the amount of air discharged from the two fans is provided. Can be collected.

Referring to Figure 8, it will be described an embodiment of the ventilation system according to the present invention.

The ventilation system in the present embodiment includes the heat exchanger 1000, the first duct part 500, and the second duct part 600.

The first duct unit 500 communicates with the air supply passage of the total heat exchanger 1000 and the room, and the total heat exchanger 1000 is positioned on the first duct unit 500. A first duct diffuser 510 is provided at the end of the first duct unit 500 to supply outdoor air to the room. In addition, the second duct unit 600 is configured to communicate the discharge passage of the total heat exchanger 1000 with the room, and the total heat exchanger 1000 is positioned on the second duct unit 600. A second duct diffuser 610 for sucking indoor air is installed at the end of the second duct 600.

Through the above configuration, the indoor air and the outdoor air are exchanged with each other with high heat transfer efficiency without increasing the ceiling height, thereby supplying the outside air while maintaining the temperature of the indoor air, and exhausting the indoor air.

As described above, the preferred embodiments of the present invention have been described, and the fact that the present invention can be embodied in other specific forms in addition to the above-described embodiments without departing from the spirit or scope thereof has ordinary skill in the art. It is obvious to them.

Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and thus, the present invention is not limited to the above description and may be modified within the scope of the appended claims and their equivalents.

Referring to the effect of the heat exchanger and the ventilation system using the same according to the present invention described above are as follows.

First, by modifying the cross-sectional shape of the heat exchange element, and arranging a plurality of heat exchange elements in series, it is possible to increase the heat exchange area and the length of the flow path without increasing the height of the heat exchanger, thereby increasing the heat transfer efficiency of the heat exchanger.

Second, by reducing the flow rate of air passing through the heat exchange element, heat exchange is effectively performed in the heat exchange element.

Third, the power loss of the total heat exchanger can be reduced by reducing the pressure loss generated while passing through the flow path by reducing the curvature on the flow path of the air supply passage and the exhaust flow passage.

Fourth, it is possible to improve the fan-motor assembly structure, increase the air flow rate, and consequently increase the heat exchange amount between the indoor air and the outdoor air.

Claims (12)

A heat exchange element installed in a region where the air supply passage that serves as the passage of outdoor air to the interior and the exhaust passage that serves as the passage for discharging the indoor air are vertically intersected to allow heat exchange between the outdoor air and the indoor air; An air supply fan connected to the air supply passage and configured to suck the outdoor air and discharge the indoor air; And, And an exhaust fan connected to the exhaust flow path and sucking the indoor air and discharging the indoor air to the outside. The cross section of the heat exchange element is a heat exchanger, characterized in that the horizontal or vertical length is formed in a rhombus shape longer than the length of the other direction perpendicular to it. delete delete The method of claim 1, The heat exchange element is provided with a plurality, each heat exchange element characterized in that arranged in series with respect to the flow direction of air. The method of claim 4, wherein And the air supply passage and the exhaust passage are configured to allow air flowing therein to pass through the heat exchange elements arranged in series in a zigzag form. The method of claim 1, The total heat exchanger, And an exhaust bypass passage which is partitioned from the exhaust passage and in which indoor air is discharged to the outside directly by the forced suction force of the exhaust fan without passing through the heat exchange element. The method of claim 1, The total heat exchanger, And an air supply bypass passage, which is partitioned from the air supply passage, in which outdoor air is directly supplied to the room by a forced suction force of the intake fan without passing through the heat exchange element. The method of claim 1, The total heat exchanger, Electrothermal heat exchanger further comprises a filter for filtering foreign matter contained in the outdoor air on the air supply passage. The method of claim 1, The rotation shaft of the air supply fan and the exhaust fan is perpendicular to the discharge direction of the outdoor air and the discharge direction of the indoor air, respectively. The method of claim 9, The air supply fan and the exhaust fan is provided with a plurality, the plurality of air supply fan and the exhaust fan is characterized in that driven by a single motor. The method of claim 10, And a chamber for storing the air discharged by the fan on the air supply fan side and the exhaust fan side, respectively. A total heat exchanger of any one of claims 1 to 11; A first duct portion communicating with the air supply passage of the heat exchanger and the interior, and having a diffuser for supplying outdoor air at an end thereof; And, And a second duct portion communicating with the discharge flow path of the heat exchanger and the room, and having a diffuser installed at the end thereof to suck the indoor air.

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