KR20210027767A - heat exchanger for air purification - Google Patents

Abstract

The present invention relates to a total heat exchange apparatus for air purification which can increase purification performance. The total heat exchange apparatus for air purification comprises: a total heat exchange unit formed to exchange heat between air entering in a first direction and air entering in a direction perpendicular to the first direction without being mixed with each other; a housing allowing the total heat exchange unit to be mounted in the middle thereof, and having a first and a second division space divided on both sides of the total heat exchange unit in the first direction with respect to the total heat exchange unit to communicate with the opposing total heat exchange unit for ventilation, a third and a fourth division space divided on both sides of the total heat exchange unit in a second direction to communicate with the opposing total heat exchange unit for ventilation, an inside air outlet formed in the first division space, an inside air inlet formed in the second division space, an outside air inlet formed in the third division space, and an outside air outlet formed in the fourth division space; a first air-blowing fan installed in the first division space to discharge inflow air through the inside air outlet; a second air-blowing fan installed in the fourth division space to discharge inflow air through the outside air outlet; and a plasma lamp which is installed in the fourth division space and emits ultraviolet light to inflow air to perform air sterilization and purification.

Description

Total heat exchanger for air purification {heat exchanger for air purification}

The present invention relates to a total heat exchange device for air purification, and more particularly, to a total heat exchange device for air purification capable of improving air purification performance while supporting internal air circulation.

In general, the total heat exchange device is used as a component of a building's air conditioning system. Indoor air is discharged to the outside for ventilation inside the building, and the indoor air and the inhaled outdoor air are It is a device provided to reduce heat loss generated during ventilation by allowing heat exchange with each other.

This total heat exchange device has a structure in which an exhaust passage for exhausting indoor air and an intake passage for inhalation of outdoor air cross each other inside, and an exhaust fan and an intake fan are installed on one side of the exhaust passage and the intake passage, respectively. have. In addition, in the total heat exchange device, a total heat exchange unit is installed in an area at the intersection of the exhaust passage and the intake passage so that indoor air and outdoor air exchange heat without being mixed with each other.

Such a total heat exchange device has been proposed in various ways, such as Korean Patent No. 10-0600621.

However, in the conventional total heat exchange device, a filter that filters air is applied to purify the air circulating through the total heat exchange unit. However, in this case, the sterilization ability cannot be exhibited, thus improving the purification ability and providing the sterilization ability. Structure is being demanded.

An object of the present invention is to provide a total heat exchange device for air purification that has been invented to solve the above requirements, and in detail, can sterilize air in circulation and can improve purification performance.

In order to achieve the above object, the total heat exchange device for air purification according to the present invention allows heat exchange to be performed without mixing air introduced through a first direction and air introduced through a direction orthogonal to the first direction. A total heat exchange unit formed in a rectangular shape; The total heat exchange unit is mounted in the center, and the total heat exchange unit is partitioned on both sides of the total heat exchange unit along the first direction so that ventilation is achieved with the total heat exchange unit facing each other. Is formed, and has third and fourth compartments to allow ventilation from the total heat exchange units facing each other by being partitioned on both sides of the total heat exchange unit along the second direction, and the first compartment has a bet discharge port A housing having an internal air inlet in the second compartment, an outside air inlet in the third compartment, and an outside air outlet in the fourth compartment; A first blowing fan installed in the first compartment and discharging the introduced air through the air outlet; A second blowing fan installed in the fourth compartment and discharging the introduced air through the outside air outlet; And a plasma lamp installed in the fourth compartment and performing air sterilization and purification by irradiating ultraviolet light to the introduced air.

Preferably, a circulation passage formed to communicate air between the second compartment and the third compartment of the housing; A first damper installed to open and close the circulation passage according to a control signal; A second damper mounted on the bet discharge port to open and close the bet discharge port; A third damper mounted on the outside air inlet and opening and closing the outside air inlet; An operation unit configured to select an opening/closing position of the first to third dampers; And a control unit for controlling the first †T third damper to correspond to a manipulation signal of the manipulation unit.

In addition, the control unit supports to select an outside air intake mode, an inside air discharge mode, and an inside air circulation mode, and the control unit controls the second blowing fan to be operated when the outside air intake mode is selected, and the inside air discharge mode is selected. When the first ventilation fan is controlled to be operated, the first damper controls the circulation passage to open when the internal air circulation mode is selected, and the second and third dampers close the internal air outlet and the outside air inlet. It is preferable to control the second blowing fan to operate.

According to the total heat exchange device for air purification according to the present invention, air sterilization and air purification are performed by an oxidation-reduction reaction by radicals and ions generated by photodissociation of oxygen and moisture molecules in the air by ultraviolet light irradiated from a plasma lamp. As a result, it provides an advantage that can improve air purification performance and sterilization efficiency.

1 is a perspective view showing a total heat exchange device for air purification according to the present invention,
2 is a cross-sectional view of the total heat exchange device for air purification of FIG. 1.

Hereinafter, a total heat exchange device for air purification according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a perspective view showing a total heat exchange device for air purification according to the present invention, and FIG. 2 is a cross-sectional view of the total heat exchange device for air purification of FIG. 1.

1 and 2, the total heat exchange device 100 for air purification according to the present invention includes a housing 110, a total heat exchange unit 150, a filter 160, and first and second blowing fans 171 ( 172), a plasma lamp 180, an operation unit 191 and a control unit 195 are provided.

The housing 110 constitutes a main body and is formed in the shape of a rectangular box having an inner space, and a total heat exchange unit 150 is mounted in a diagonal direction at the center of the inner space.

The housing 110 is formed to have first to fourth compartments so that an exhaust passage for discharging indoor air and an intake passage for inhaling outdoor air may be formed to cross each other inside.

The housing 110 is formed in a structure having a border portion 112 formed in a rectangular shape, and first to fourth partition walls 115a to 115d extending from each side of the border portion 112 toward the center. . Here, the first to fourth partitions 115a to 115d are in the crossing space, which is an area where the exhaust flow path and the intake flow path cross each other so that the exhaust flow path for exhausting indoor air and the intake flow path for inhaling outdoor air cross each other. It only extends to the applicable area. A total heat exchange unit 150, which will be described later, is mounted in the cross-space 116.

The first compartment 117a formed in the housing 110 by this structure is a space formed by being partitioned on one side of the total heat exchange unit 150 along the first direction with respect to the total heat exchange unit 150. It is a space formed between the two partition walls 115a and 115b. In the rim part 112 forming the first compartment 117a, the bet discharge port 118a is formed to be exposed to the outside.

The second compartment 117b is a space formed by being partitioned on the other side of the total heat exchange unit 150 along the first direction with respect to the total heat exchange unit 150, and is formed between the third and fourth partition walls 115c and 115d. It is a space to become. In the border part 112 forming the second compartment 117b, the bet inlet 118b is formed to be exposed to the outside.

The first and second compartments 117a and 117b are mutually ventilated in the first direction X which is a diagonal direction by the total heat exchange unit 150 mounted opposite to the crossing space 116.

The third compartment 117c is a space formed by being partitioned on one side of the total heat exchange unit 150 along a second direction orthogonal to the first direction with respect to the total heat exchange unit 150, and the second and third partition walls 115b It is a space formed between (115c). The outer air inlet 118c is formed to be exposed to the outside in the border part 112 forming the third compartment 117c.

The fourth compartment (117d) is a space formed by being partitioned on the other side of the total heat exchange unit (150) along the second direction with respect to the total heat exchange unit (150), and is formed between the fourth and first partition walls (115d) (115a). It is a space to become. The outer air outlet 118d is formed to be exposed to the outside in the border part 112 forming the fourth compartment 117d.

The third and fourth compartments 117c and 117d allow mutual ventilation in the second direction Y, which is another diagonal direction by the total heat exchange unit 150 mounted opposite to the crossing space 116. do.

The circulation passage 131 is provided to be used when circulating the inside air, and is formed through the third partition wall 115c so that air communicates between the second and third compartments 117b and 117c. .

In the housing 110 of this structure, the area in which the internal air inlet 118b and the outdoor air outlet 118d are formed is disposed on the indoor side of the building, and the area in which the outdoor air inlet 118c and the internal air outlet 118a are formed is the outdoor side of the building. It just needs to be installed to be placed in

The first damper 141 is installed to open/close, that is, open or close the circulation passage 131 according to a control signal from the controller 195. The first damper 141 includes a first opening and closing plate 141a for opening and closing the circulation passage 131 by rotation within the circulation passage 131, and a first motor 141b for rotatingly driving the first opening and closing plate 141a. ) Can be built.

The second damper 142 is mounted on the air outlet 118a to open and close the air outlet 118a according to a control signal from the control unit 195. The second damper 142 may also be constructed with a second opening/closing plate 142a for opening and closing the bet discharge port 118a by rotation, and a second motor 142b for rotatingly driving the second opening/closing plate 142a.

The third damper 143 is mounted on the outside air outlet 118c to open and close the outside air outlet 118c according to a control signal from the control unit 195. The third damper 143 may also be constructed with a third opening/closing plate 143a for opening and closing the outside air outlet 118c by rotation, and a third motor 143b for rotatingly driving the third opening/closing plate 143a.

The total heat exchange unit 150 is mounted in the intersecting space 116 of the housing 110 and flows in through the first direction (X), and the second direction (Y), which is a direction orthogonal to the first direction (X). It is formed in a rectangular shape so that heat exchange is performed without mixing the air introduced through the air.

The total heat exchange unit 150 may be formed in a variety of known structures such as a stacked structure in which unit heat exchanged sheets extending in a wave form are vertically arranged orthogonally to each other. The detailed structure of the total heat exchange unit 150 is disclosed in various ways, such as Registration Utility Model No. 20-0462636, so a description of the detailed structure is omitted.

The filter 160 is mounted in the outside air inlet region along the second direction of the total heat exchange unit 150 to filter foreign substances contained in the air. As an example, as the filter 160, a HEPA filter, a medium filter, a pre-filter, etc. capable of filtering foreign substances while allowing the passage of air due to porosity may be applied in an array in order.

The first blowing fan 171 is installed in the first compartment 117a to discharge the introduced air through the air outlet 118a.

The second blowing fan 172 is installed in the fourth compartment 117d to discharge the introduced air through the outside air outlet 118d.

Sirocco fans may be applied to the first and second blowing fans 171 and 172.

The plasma lamp 180 is installed in the fourth compartment 117d and performs air sterilization and purification by irradiating ultraviolet light to the introduced air. The plasma lamp 180 is formed to emit vacuum ultraviolet light having a high energy of 100 to 200 nm that can cause a low-temperature oxygen plasma, and causes a plasma reaction to photodissociate oxygen and moisture molecules in the air by the irradiated light. It sterilizes air and removes odor components by oxidation-reduction reaction of radicals and ions generated in

The operation unit 191 supports to select an opening/closing position of the first to third dampers 141, 142, and 143. Preferably, the operation unit 191 supports to select an outside air inlet mode, an inside air discharge mode, and an inside air circulation mode.

The controller 195 controls the first to third dampers 141 and 142 to correspond to the manipulation signal of the manipulation unit 191.

The control unit 195 controls the second blowing fan 172 to be operated while the third damper 143 is controlled to be opened when the outside air inflow mode is selected from the control unit 191, and the inside air discharge mode is performed by the control unit 191. When is selected, the first blowing fan 171 is controlled to be operated while the second damper 142 is controlled to be opened. Unlike this, the control unit 191 supports the selection of one outdoor air inflow and internal air discharge mode, and the control unit 195 opens both the second and third dampers 142 and 143 when the external air inflow and internal air discharge modes are selected. It can be built to operate both the first and second blowing fans 171 and 172 in a controlled state.

In addition, the control unit 195 controls the first damper 141 to open the circulation passage 131 when the bet circulation mode is selected from the control unit 191, and the second damper 142 and the third damper 143 are The second blowing fan 172 is controlled to be operated while the internal air outlet 118a and the outside air inlet 118c are controlled to be closed. In this case, the indoor air through the internal air inlet (118b), the circulation passage (131), the third compartment (117c), the total heat exchange unit (150) and the fourth compartment (117d) through the outside air outlet (118d) By being discharged into the room, it is possible to purify the air while circulating the inside air.

According to the total heat exchanger for air purification described above, air sterilization and air purification are performed by an oxidation-reduction reaction by radicals and ions generated by photodissociation of oxygen and moisture molecules in the air by ultraviolet light irradiated from a plasma lamp. As a result, air purification performance and sterilization efficiency can be improved.

110: housing 150: total heat exchange unit
160: filters 171, 172: first and second blowing fans
180: plasma lamp 191: operation unit
195: control unit

Claims (3)

A total heat exchange unit formed in a rectangular shape such that heat exchange is performed while air introduced through a first direction and air introduced through a direction orthogonal to the first direction are not mixed with each other;
The total heat exchange unit is mounted in the center, and the total heat exchange unit is divided along both sides of the total heat exchange unit along the first direction so that ventilation is made with the total heat exchange unit facing each other. Is formed, and has third and fourth compartments to allow ventilation from the total heat exchange units facing each of the total heat exchange units divided along the second direction, and the first compartment has a bet discharge port A housing having an internal air inlet in the second compartment, an outside air inlet in the third compartment, and an outside air outlet in the fourth compartment;
A first blowing fan installed in the first compartment and discharging the introduced air through the air outlet;
A second blowing fan installed in the fourth compartment and discharging the introduced air through the outside air outlet;
And a plasma lamp installed in the fourth compartment and performing air sterilization and purification by irradiating ultraviolet light to the introduced air. The method of claim 1, further comprising: a circulation passage formed to communicate air between the second compartment and the third compartment of the housing;
A first damper installed to open and close the circulation passage according to a control signal;
A second damper mounted on the bet discharge port to open and close the bet discharge port;
A third damper mounted on the outside air inlet and opening and closing the outside air inlet;
An operation unit configured to select an opening/closing position of the first to third dampers;
And a control unit for controlling the first †T third damper in response to an operation signal of the operation unit. The method of claim 2, wherein the control unit supports to select an outdoor air inflow mode, an internal air discharge mode, and an internal air circulation mode, and the control unit controls the second blowing fan to be operated when the external air inflow mode is selected, and When the discharge mode is selected, the first ventilation fan is controlled to be operated, and when the internal air circulation mode is selected, the first damper controls the circulation passage to be opened, and the second and third dampers close the internal air outlet and the outside air inlet. A total heat exchange device for air purification, characterized in that controlling to operate the second blowing fan in one state.

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