KR20120037734A - Heat exchange media and energy recovery ventilator using the same - Google Patents

Abstract

PURPOSE: A heat exchange media and an energy recovery ventilation device using the same are provided to maximize contact frequency between air and a metal surface and increase time that the air is stayed in the heat exchange media, thereby improving heat exchange efficiency. CONSTITUTION: A heat exchange media(1) has a coiled structure in multi stage. The metal foil is stretched in vertical direction of the blade scars to form tridimensional diamond shaped air gaps in a state where a metal foil has blade scars in predetermined intervals. The air flowed in from the outside passes through the air gaps and gets in contact with a metal surface so that heat exchange is implemented. The angle between the air gaps and the air flow is within 40 to 50 degree.

Description

Heat exchange media and energy recovery ventilator using the same

The present invention provides a heat exchange medium for preserving cooling / heating energy of the room by performing heat exchange with respect to the exhausted and supplied air in the room and the outside for indoor ventilation, and to prevent energy loss due to ventilation during cooling / heating of the room. An energy recovery ventilator for performing ventilation using the heat exchange medium.

Hazardous substances from building materials in new houses, buildings, or school classrooms are causing social pollution, a so-called 'Sick House Syndrome', as a social problem. Not only sick house syndrome, but also the syndrome of congestion caused by harmful substances in old buildings, and cooling disease caused by excessive cooling are all collectively referred to as 'Sick Building Syndrome'.

Such building disease syndrome can be almost completely prevented by properly ventilating indoor air, but due to energy saving problems, sufficient ventilation is not achieved. In addition, in the case of school classrooms, opening the window for ventilation may cause other problems, such as disturbing learning due to external noise.

In order to solve these problems, an energy recovery ventilator (ERV) has been developed. The energy recovery ventilator is installed in a place where cooling or heating is performed to vent air from the room. Heat exchange between the air and the air supplied from the outside is a device that recovers the energy lost during ventilation. This energy recovery ventilator is also called heat recovery ventilator (HRV), and has the advantage of proper ventilation and energy saving in the room.

Republic of Korea Patent No. 0305431 (name: Ventilation device using a rotating cylindrical heat exchange medium) is a representative example of the energy recovery ventilator developed by the inventor of the present invention, the air is discharged to the outside by the rotating cylindrical heat exchange medium and sucked into the room The heat exchange between the air is continuously made to maximize the cooling / heating efficiency of the building. That is, the heat exchange is performed in the process of passing the heated or cooled indoor air into the air supply duct and passing through the cylindrical heat exchange medium, and the indoor air heat-exchanged with the heat exchange medium is discharged to the outside through the exhaust duct.

The present invention was developed in order to more specifically embody the heat exchange medium disclosed in the above-mentioned ventilator of Patent No. 0305431 and to exhibit an efficient function. The object of the present invention is to provide sufficient heat exchange between the indoor and outdoor exhaust air and intake air. It is to provide a heat exchange medium and an energy recovery ventilator using the same to maximize the cooling / heating efficiency of the room by being made.

In the heat exchange medium of the present invention for achieving the above object, the metal sheet is stretched in the direction perpendicular to the cut in a state in which the cut is formed on the metal sheet at regular intervals, so that the cut forms a three-dimensional rhombic void. It has a multi-layer winding structure in a ring shape, characterized in that the air flowing from the outside is in contact with the metal surface while passing through the pores for each layer to perform heat exchange. In particular, the voids are preferably formed to form an angle of 40 ~ 50 ° with the flow of air.

The energy recovery ventilator of the present invention using the heat exchange medium has a support member coupled to the bottom of the heat exchange medium and one side edge of the wound surface of the heat exchange medium facing the bottom to be rotatable with the heat exchange medium. It includes a heat exchanger comprising. In addition, the heat exchanger is accommodated and installed in the ventilation position between the indoor and outdoor, and provided with an air supply unit for supplying the heat exchanged air to the room while sucking the outdoor air through the heat exchanger, and intakes the indoor air to heat exchange A casing having an exhaust unit for discharging the heat-exchanged air to the outside while passing through the machine is provided. In addition, the heat exchanger is disposed in a form split in half between the air supply unit and the exhaust unit to separate the air supply unit and the exhaust unit, and extends inside and outside of the heat exchanger to block air from being exchanged in the air supply unit and the exhaust unit. A partition member having blocking walls is provided. A rotational driving motor is installed on the partition member to connect the drive shaft to the support member of the heat exchanger so as to rotate the heat exchanger in the forward direction in which the indoor side inflow of outdoor air and the outdoor side discharge of the indoor air are performed. In addition, it is installed to shield the outside of the heat exchanger, the vents are formed in the lower side corresponding to each of the parts facing the outdoor side of the air supply portion and the exhaust portion, the air supply portion and the portion facing the interior side of the exhaust portion Vents are also formed on the upper sides, respectively, and the inner side of the upper end is in contact with the upper surface of the partition member, and has an air flow guide member for inducing air flow of the air supply unit and the exhaust unit.

In the energy recovery ventilator, the air supply unit is provided to be close to the air supply inlet where the outdoor air is sucked into the casing, the air supply outlet where the heat-exchanged air is supplied to the indoor side, and between the air supply inlet and the air supply outlet. And an air blower for blowing heat-exchanged air to the indoor side while forcibly sucking outdoor air into the casing, and the air sucked near the air supply inlet and sucked into the air supply inlet is supplied to the air supply outlet through the air supply blower via the heat exchanger. It may be composed of a configuration including an air supply guide wall to guide the flow. In addition, the exhaust portion is provided in an exhaust inlet in which indoor air is sucked into the casing, an exhaust outlet through which heat-exchanged air is discharged to the outdoor side, and between the exhaust inlet and the exhaust outlet, so as to be close to the exhaust outlet, to bring the indoor air into the casing. An exhaust blower that blows heat-exchanged air to the outside while forcibly suctioning it, and an exhaust induction that induces a flow such that the air sucked into the exhaust inlet and supplied to the exhaust inlet is supplied to the exhaust outlet through the exhaust blower via a heat exchanger. It may consist of a configuration including a wall.

In addition to the above configuration, the air supply unit may be further provided with a bypass duct for conveying a part of heat-exchanged air supplied to the room to the casing side. In addition, a blower for pollutant discharge may be further provided to suck the pollutant in the air passing through the inside and the outside of the heat exchanger to discharge the pollutant to the outside.

In the heat exchange medium of the present invention, the air introduced from the outside exchanges heat by contacting the metal surface around the air gap while passing through the air gap of the heat exchange medium. At this time, since the metal sheet forming the heat exchange medium is wound to overlap with several layers, the frequency of contact with the metal surface is maximized as the air passes through each layer, and the time for the air to pass through stays in the heat exchange medium. As a result, it exhibits high heat exchange efficiency. Therefore, when the heat exchange medium of the present invention using such a heat exchange medium is applied to an air conditioning or ventilation device, there is an effect of maximizing the cooling / heating efficiency of the room.

In addition, since the energy recovery ventilator of the present invention does not require facilities such as a cooling tower, a boiler, and a ventilation duct necessary for a conventional air conditioning / heating air conditioning system, a significant reduction in energy consumption as well as facility and construction costs for installation of these facilities is required. In addition, since the installation of these facilities is excluded, there is an effect of lowering the height of the building and increasing space utilization.

1 is a view illustrating a manufacturing process of a heat exchange medium according to the present invention.
2 is a perspective view and a partially enlarged view of an embodiment of a heat exchange medium according to the invention.
FIG. 3 is a schematic two-dimensional representation of the flow structure of air passing through the heat exchange medium of FIG.
4 is an exploded perspective view showing the energy recovery ventilator of the present invention using the heat exchange medium of FIG.
FIG. 5 is a cross-sectional plan view of the coupled state of the energy recovery ventilator of FIG.
6 is a view showing a flow of air heat exchanged in the energy recovery ventilator of FIG.
Figure 7 is a schematic diagram showing another embodiment of the energy recovery ventilator of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it should be understood that the following embodiments are provided so that those skilled in the art can understand the present invention without departing from the scope and spirit of the present invention. It is not.

First, a preferred embodiment of the heat exchange medium according to the present invention will be described with reference to FIGS. 1 is a view illustrating a manufacturing process of a heat exchange medium according to the present invention, FIG. 2 is a perspective view and a partially enlarged view showing an embodiment of the heat exchange medium according to the present invention, FIG. Schematic diagram of two-dimensional representation of the flow structure of air.

The heat exchange medium of the present invention is made of a metal such as aluminum, copper, stainless steel, or the like, which has good or good thermal conductivity and can eliminate static electricity.

In particular, a heat exchange medium is formed from a metal sheet made of a thin plate of such a metal material, and as shown in FIG. 1, the cut sheet 1a is cut out at a predetermined interval on the metal sheet 1, and the cut sheet 1a is formed. When the thin metal plate 1 is stretched in a right angle direction, the cut 1a is deformed into a three-dimensional rhombic void 1a '. Thus, the heat exchange medium 1 'of the present invention as shown in FIG. 2 is produced by winding several layers of the metal thin plate 1 in which many voids 1a' are formed in a ring type.

The heat exchange medium 1 ′ of the present invention manufactured as described above undergoes heat exchange by contacting a metal surface while passing through the air gap 1 a ′ for each layer wound in multiple layers when air flowing from the outside passes. . That is, as can be seen in FIG. 3, air introduced from outside of the heat exchange medium 1 ′ contacts the metal surface around the air gap 1 a ′ while passing through the air gap 1 a ′ of the heat exchange medium 1 ′. The heat exchange is performed. Since the thin metal sheets forming the heat exchange medium 1 'are stacked and wound in several layers, the frequency of contact with the metal surface is maximized as the air passes through each layer, and the air passing through the heat exchange medium ( 1 ') shows a high heat exchange efficiency because the retention time is long.

The air gap 1a 'is preferably formed at an angle of 40 to 50 ° with respect to the flow of air, and is preferable in terms of heat exchange efficiency, and is illustrated at an angle of 45 ° in this embodiment. In addition, it is advantageous in the breathability to form the space | gap 1a 'about 2-3 mm in length.

Next, an embodiment of the energy recovery ventilator of the present invention using the heat exchange medium as described above will be described.

Figure 4 is an exploded perspective view showing the energy recovery ventilator of the present invention using the heat exchange medium described above, Figure 5 is a cross-sectional view of the coupled state of the energy recovery ventilator of Figure 4, Figure 6 is the energy recovery ventilator of Figure 4 A diagram showing the flow of air heat exchanged in the apparatus.

As illustrated in FIG. 4 to FIG. 6, the energy recovery ventilator of the present embodiment includes a heat exchanger 10 and a casing 20 accommodating the heat exchanger 10, and an air supply unit in the casing 20. The partition member 23 separating the 21 and the exhaust 22, the rotary drive motor 25 for rotating the heat exchanger 10, and the air flow from the air supply 21 and the exhaust 22 Inducing air flow guide member 24 is provided, and specifically, is configured as follows.

First, the heat exchanger 10 is formed at the bottom of the heat exchange medium 11 in a state where the ring-shaped heat exchange medium 11 having the above-described configuration and one side edge of the wound surface of the heat exchange medium 11 face the bottom. It is composed of a support member 12 that is coupled to rotate with the heat exchange medium (11). In particular, the central portion of the support member 12 is formed with a shaft groove (12a) for connecting with the rotary drive motor 25, the rotary drive power of the rotary drive motor 25 is received to be driven to rotate. In addition, the bottom portion of the support member 12 is smoothly rotated by being supported by the rotating support means 12b such as a bearing or a wheel in the casing 20.

The heat exchanger 10 is accommodated in the center of the casing 20, the casing 20 is divided into the air supply unit 21 and the exhaust unit 22 around the heat exchanger 10 located in the center. . The casing 20 is illustrated as a rectangular cross-sectional structure, which is installed in the ventilation unit (for example, a window or an air-conditioning installation area, such as a window or an air conditioning installation site) between the indoor and outdoor. The air supply unit 21 supplies the heat-exchanged air to the room by sucking outdoor air into the casing 20 and passing it through the heat exchanger 10. In addition, the exhaust unit 22 sucks indoor air into the casing 20 to pass through the heat exchanger 10 to discharge the heat-exchanged air to the outside.

The partition member 23 divides the air supply unit 21 and the exhaust unit 22 by arranging the heat exchanger 10 in half between the air supply unit 21 and the exhaust unit 22. In particular, the upper surface portion of the partition member 23 is in contact with the inner upper end of the air flow guide member 24, which will be described later, the lower surface portion of the partition member 23 and the inner ring and the outer ring of the ring heat exchanger 10 Blocks 23a, 23b, 23c extending toward the support member 12 are provided at the contact portion. Accordingly, the upper surface portion of the partition member 23 and the blocking walls 23a, 23b, and 23c block air from being exchanged with each other in the air supply unit 21 and the exhaust unit 22.

The air supply unit 21 has a short air supply inlet 21a formed in a short pipe shape to suck outdoor air into the casing 20, and a short supply air supply to the indoor side of the intake air heat exchanged with the heat exchanger 10. The pipe-type air supply outlet 21b is provided. An air supply blower 21c is provided between the air supply inlet 21a and the air supply outlet 21b to forcibly suck outdoor air into the casing 20 to blow heat exchanged air to the indoor side. The air supply blower 21c is installed close to the air supply outlet 21b, and air sucked into the air supply inlet 21a is supplied to the air supply air blower 21c via the heat exchanger 10 at a side near the air supply inlet 21a. Air supply guide wall (21d) to guide the flow to be supplied to the air supply outlet (21b) through the () is provided.

In addition, the exhaust part 22 is a short pipe type exhaust inlet 22a for sucking indoor air into the casing 20 and a short exhaust pipe for discharging indoor suction air heat exchanged by the heat exchanger 10 to the outdoor side. A pipe exhaust outlet 22b is provided. An exhaust blower 22c is provided between the exhaust inlet 22a and the exhaust outlet 22b to exhaust the air by forcibly sucking indoor air into the casing 20 and blowing the heat-exchanged air to the outdoor side. The exhaust blower 22c is provided close to the exhaust outlet 22b, and on the side near the exhaust inlet 22a, the air sucked into the exhaust inlet 22a passes through the heat exchanger 10 to exhaust the blower 22c. The exhaust induction wall 22d for inducing the flow to be supplied to the exhaust outlet 22b is provided.

The air supply inlet 21a, the air supply outlet 21b, and the air inlet 22a and the air outlet 22b are located close to the four corner portions of the casing 20, respectively, and the air supply guide wall 21d is the air supply inlet 21a. It is formed to be inclined toward the heat exchanger 10 from the corner portion of the casing 20, which is located, so that the air sucked through the air supply inlet 21a is directed toward the heat exchanger 10. Similarly, the exhaust induction wall 22d is formed to be inclined toward the heat exchanger 10 from the corner portion of the casing 20 where the exhaust inlet 22a is located so that the air sucked through the exhaust inlet 22a is exchanged. Will be directed towards (10).

The heat exchanger 10 is rotated by the rotary drive motor 25, the rotational direction of which the outdoor air sucked into the air supply inlet 21a is directed toward the air supply fan 21c and at the same time the exhaust inlet ( The indoor air sucked into 22a) should be in a forward direction to the exhaust blower 22c side (see Fig. 5). Accordingly, the rotation drive motor 25 rotates the heat exchanger 10 in the forward direction in which the indoor side inlet of outdoor air and the outdoor side discharge of the indoor air are made.

The rotary drive motor 25 may be installed in a blocking wall 23c positioned at the center of the partition member 23, and the driving shaft 25a drawn downward from the rotary drive motor 25 may be formed in the heat exchanger 10. It is fitted into the shaft groove (12a) provided in the support member 12 is coupled. Therefore, when the rotary drive motor 25 is driven, the support member 12 connected to the drive shaft 25a rotates, and the heat exchanger 10 coupled with the support member 12 is rotated. Since the bottom portion of the support member 12 is supported by the rotation support means 12b such as a bearing or a wheel, the heat exchanger 10 can rotate smoothly.

The air flow guide member 24 is disposed on the outside of the heat exchanger 10 to shield the inside and the outside of the heat exchanger 10 to provide vents 24a, 24b, 24c, and 24d at specific portions of the air. It will direct the flow in a specific direction. That is, the air vents 24a and 24d are formed at the lower portions corresponding to the portions facing the outdoor side of the air supply portion 21 and the exhaust portion 22, respectively, and the air supply portion 21 and the exhaust portion 22 are indoors. Vents 24b and 24c are also formed in the upper portion corresponding to the portion facing the side, respectively. Therefore, when the heat exchange by the heat exchanger 10, as shown in Figure 6, the air flow in the air supply unit 21 and the exhaust 22 is made, which will be described in detail below.

Next, the operation of the energy recovery ventilator configured as described above will be described.

When the energy recovery ventilator of the present invention is operated, the heat exchanger 10 is rotated by the rotary drive motor 25, and the air supply blower 21c and the exhaust unit 22 of the air supply unit 21 are exhausted. The blower 22c is operated.

Accordingly, outdoor air is sucked into the air supply unit 21 inside the casing 20 through the air supply inlet 21a by the blowing pressure of the air supply blower 21c, and is directed to the heat exchanger 10. Then, the sucked outdoor air passes through the pores (1 a ′ of FIG. 1) formed in the heat exchange medium 11 of the rotating heat exchanger 10, and comes into contact with the metal surface of the heat exchange medium 11 to perform heat exchange. More specifically, as shown in FIG. 6, the outdoor air sucked into the air supply part inside the casing through the air supply inlet 21 a is transferred to the heat exchanger through the air vent 24 a provided under the air flow guide member 24. Heat exchange medium 11 is introduced into the heat exchange medium 11, heat exchanges while passing through the air gaps of the heat exchange medium 11, and then rises above the heat exchanger medium 11 to provide an air vent 24b provided above the air flow guide member 24. Through the air supply outlet 21b to the indoor side. For example, when the energy recovery ventilator of the present invention is operated in the summer, the outdoor hot air is cooled by the cold air deprived of heat energy by the heat exchange medium 11. The cooled air is supplied into the room through the air supply outlet 21b by the blowing pressure of the air supply blower 21c, thereby simultaneously cooling and ventilating the room.

In addition, the contaminated air in the room is sucked to the exhaust side inside the casing through the exhaust inlet 22a by the blowing pressure of the exhaust blower and is directed to the heat exchange medium 11 of the heat exchanger 10. That is, the indoor air sucked into the exhaust side inside the casing 20 through the exhaust inlet 22a rises from the outside lower side of the air flow guide member 24 as shown in FIG. 6 and is provided above the air flow guide member 24. Flows into the heat exchanger medium (11) through the vent (24c), and descends again to exchange heat while passing through the voids of the heat exchange medium (11), and then the air vent (24d) provided under the air flow guide member (24). Is discharged to the outdoor side through the exhaust outlet 22b. For example, in summer, the contaminated air in the room undergoes heat exchange with the heat exchange medium 11 while passing through the pores formed in the heat exchange medium 11 of the heat exchanger 10, where the heat exchanger 10 rotates the driving motor 25. And the exhaust inlet 22a is opened as soon as the corresponding portion of the heat exchange medium 11 whose temperature has risen by heat exchange with the outdoor air in the air supply unit 21 is rotated and positioned in the exhaust unit 22. It is cooled by the cold air of the room which is sucked into the exhaust 22 through. And by rotating to the air supply unit 21 side again, the outdoor air sucked into the air supply unit 21 through the air supply inlet 21a is cooled by heat exchange. In addition, the indoor air in which the heat exchange medium 11 is cooled in the exhaust part 22 is discharged to the outside through the exhaust outlet 22b by the blowing pressure of the exhaust blower 22c.

As such, when the energy recovery ventilator of the present invention is operated not only in summer but also in winter, the heating and ventilation of the room is achieved by heat exchange in the opposite direction.

As described above, in the energy recovery ventilator of the present invention, the outdoor air and the indoor air are exchanged by the heat exchange medium 11 while passing through the air supply unit 121 and the exhaust unit 22, respectively, thereby cooling or heating the room and ventilating at the same time. Will be

On the other hand, Figure 7 is a schematic diagram showing another embodiment of the energy recovery ventilator of the present invention, which shows an example that can be applied in the case of a large capacity.

That is, the energy recovery ventilator shown in FIG. 7 includes a heat exchanger 110 having a ring-shaped heat exchange medium as in the above-described embodiment, and receives the heat exchanger 110 and the air supply unit 121. The exhaust part 122 includes a casing 120 which is provided separately. In FIG. 7, the rotation driving motor for rotating the heat exchanger 110 is omitted, but the same or similar rotation driving motor as the above-described embodiment is provided.

The air supply unit 121 has a long pipe-type air supply inlet 121a for sucking outdoor air into the casing 120, and the air sucked into the casing 120 through the air supply inlet 121a is a heat exchanger. It is provided with an air supply outlet 121b in the form of a long pipe to be supplied to the room side after heat exchange with the 110. On the air supply outlet 121b side, an air supply blower 121c forcibly sucking outdoor air into the casing 120 and blowing heat-exchanged air to the indoor side is provided. In particular, in order to be able to adjust the amount of air supplied to the room, a bypass duct 121d for conveying a part of the heat-exchanged air supplied to the room to the casing side is provided. The bypass duct 121d may communicate with the air supply inlet 121a to be mixed with the outdoor air sucked through the air supply inlet 121a.

The exhaust part 122 includes an exhaust inlet 122a in the form of a long pipe through which indoor air is sucked into the casing 120, an exhaust outlet 122b through which the heat-exchanged air is discharged to the outdoor side, and an interior from the exhaust outlet side. The exhaust fan 122c which blows heat-exchanged air to the outdoor side while forcibly suctioning air into the casing 120 is provided.

The air supply inlet 121a and the air exhaust 122a may be provided with filters 121e and 122d and a grill 121f for filtering dust or foreign matter from the air sucked in, respectively. In addition, dampers 121g, 121h and 122e capable of adjusting the air amount may be installed at the air supply inlet 121a, the bypass duct 121d and the exhaust outlet 122b.

Inside and outside of the heat exchanger 10 having a ring-shaped heat exchange medium, contaminants such as dust are attached when suctioning indoor air and outdoor air, and heat exchange efficiency is increased due to accumulated pollutants as the ventilation device is operated for a long time. Deteriorates. Therefore, in order to minimize such a problem, it is preferable to provide a pollutant discharge blower (131, 132) for sucking the pollutants in the air passing through the inside and outside of the heat exchanger (10) and discharge them to the outside. The pollutant discharge blowers 131 and 132 may be provided at the air supply unit 121 and the exhaust unit 122, respectively, and each of the pollutant discharge blowers 131 and 132 may be disposed inside the heat exchanger 10. Adsorbed pipes (131a, 131b, 132a, 132b) connected to the outside to adsorb dust by the blowing pressure of the blower for discharging the pollutants (131, 132).

On the other hand, the configuration of the bypass duct 121d, the filters 121e and 122d and the grill 121f, the dampers 121g, 121h and 122e, and the air blower 131 and 132 for discharging pollutants as described above is the only embodiment. In addition, it can be applied to the embodiment described with reference to FIGS. 4 to 6 described above, and the configuration of the air supply guide wall 21d and the exhaust guide wall 22d, which is not described in the present embodiment, is equally applicable to the present embodiment. Can be.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, This is possible.

10,110: heat exchanger 11: heat exchange medium
12: support member 12a: shaft groove
20,120: casing 21,121: air supply unit
21a, 121a: Air supply inlet 21b, 121b: Air supply outlet
21c, 121c: Air supply blower 21d: Air supply guide wall
22,122: exhaust 22a, 122a: exhaust inlet
22b, 122b: exhaust outlet 22c, 122c: exhaust blower
22d: exhaust guide wall 23: partition member
23a, 23b, 23c: barrier wall 24: air flow guide member
24a, 24b, 24c, 24d: Vent 25: Rotary drive motor
25a: drive shaft 121d: bypass duct
121e, 122d: Filter 121f: Grill
121g, 121h, 122e: Damper
131,132: Blowing device for pollutant discharge
131a, 131b, 132a, 132b: Suction Pipe

Claims (6)

It has a structure in which a multi-layer winding is formed in a ring shape, in which the thin metal plate is stretched in the direction perpendicular to the cut state in a state where the cut is made at a predetermined interval on the thin metal plate to form a three-dimensional rhombic void. A heat exchange medium in which air is brought into contact with a metal surface while passing through the pores for each layer.
The method of claim 1,
The air gap is characterized in that the air gap formed to form an angle of 40 ~ 50 ° with the flow of air.
A heat exchanger comprising a heat exchange medium according to claim 1 and a support member coupled to the bottom thereof in a state in which one side edge of the wound face of the heat exchange medium faces the bottom to be rotatable with the heat exchange medium;
It is installed in the ventilation position between the indoor and outdoor to accommodate the heat exchanger, provided with an air supply unit for supplying the heat exchanged air to the room while sucking the outdoor air through the heat exchanger, and through the heat exchanger by sucking the indoor air A casing having an exhaust unit for discharging the heat-exchanged air to the outside;
The heat exchanger is disposed in a form split in half between the air supply unit and the exhaust unit to separate the air supply unit and the exhaust unit, and extends inside and outside the heat exchanger to block air from being exchanged in the air supply unit and the exhaust unit. A partition member having barrier walls;
A rotary drive motor installed at the partition member so as to rotate the heat exchanger in the forward direction in which the indoor side inlet of the outdoor air and the outdoor side discharge of the indoor air are discharged, the drive shaft being connected to the support member of the heat exchanger;
Is installed to shield the outside of the heat exchanger, the vents are formed in the lower side corresponding to each of the parts facing the outdoor side of the air supply and the exhaust portion, respectively corresponding to the portion facing the interior side of the air supply and the exhaust portion Ventilation is also formed in the upper side, the upper inner surface is in contact with the upper surface of the partition member, the energy recovery ventilator comprising an air flow inducing member for inducing the air flow of the air supply and exhaust.
The method of claim 3,
The air supply unit may include a supply air inlet through which outdoor air is sucked into the casing, an air supply outlet through which heat-exchanged air is supplied to the indoor side, and a supply air outlet between the air supply inlet and the air supply outlet to be close to the air supply outlet. An air supply fan which blows heat-exchanged air to the indoor side while forcibly suctioning the air, and an air supply that is installed close to the air supply inlet and induces flow such that air sucked into the air supply inlet is supplied to the air supply outlet through the air supply fan via the heat exchanger. It consists of a configuration including a guide wall,
The exhaust portion is provided close to an exhaust outlet between an exhaust inlet through which indoor air is sucked into the casing, an exhaust outlet through which heat-exchanged air is discharged to the outdoor side, and an exhaust outlet between the exhaust inlet and the exhaust outlet to force indoor air into the casing. An exhaust blower that blows the heat-exchanged air to the outside while intake, and an exhaust induction that induces a flow so that air sucked into the exhaust inlet and supplied to the exhaust inlet is supplied to the exhaust outlet through the heat exchanger via the heat exchanger Energy recovery ventilator, characterized in that consisting of a wall.
The method of claim 3,
The air supply unit, the energy recovery ventilator further comprises a bypass duct for conveying a part of the heat-exchanged air supplied to the room to the casing side.
The method of claim 3,
An energy recovery ventilator, characterized in that the blower for discharging the pollutant for sucking the pollutant in the air passing through the inside and outside of the heat exchanger to discharge to the outside.

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