KR102130634B1 - Heat-recovery ventilator with electric dust filter - Google Patents

Abstract

The present invention relates to a ventilation device with an electric dust collection filter which removes fine dust and harmful substances from outside air and increases energy efficiency through heat exchange between inside air and outside air. The ventilation device with the electric dust collection filter according to the present invention comprises: a main body having a predetermined internal space; a first air moving unit for moving air introduced from the outside from one side to the other side of the main body; a second air moving unit for moving the indoor air to the outside in a direction opposite to the first air moving unit; a total heat exchange unit installed in the main body and exchanging heat between the air moving through the first air moving unit and the air moving through the second air moving unit; and an air purification unit installed at an entry on an inlet side of the first air moving unit to remove the fine dust and bacteria from the air introduced into the main body.

Description

Ventilation system equipped with an electrostatic dust filter {HEAT-RECOVERY VENTILATOR WITH ELECTRIC DUST FILTER}

The present invention relates to a ventilation device having an electrostatic precipitating filter, and more specifically, an electrostatic precipitating filter that removes fine dust and harmful substances from external air and improves energy efficiency through heat exchange between internal and external air. It relates to a ventilation system.

Recently, since modern people spend most of their time indoors, such as public buildings, underground facilities, and offices, interest in indoor air quality has increased due to the effect of indoor air on the human body. In addition, the main factors contaminating indoor air quality are mainly particulate matter such as fine dust, asbestos, and soil dust, and gaseous chemical substances such as formaldehyde and volatile organic compounds. And, among them, fine dust and volatile organic compounds adversely affect health when exposed to the human body.

As a method for removing contaminants, a method of exchanging indoor air with external air as a method of natural ventilation and mechanical ventilation through an air conditioning system has been mainly used. And as a dust collecting device using an air conditioning system, Korean Patent Publication No. 10-2015-0050851 (“Air Conditioning Filter Device” and Korean Patent Publication No. 10-2015-0014820 (“Air Conditioning Device with Air Purification Module”, etc.) This is disclosed.

However, the air conditioning apparatus using the HEPA filter has a problem in that the filter needs to be periodically replaced, and a lot of wind pressure is applied to the filtering, resulting in high energy consumption.

The technical problem to be solved by the present invention is to provide a ventilation device having an electrostatic dust filter that removes fine dust and harmful substances from external air and improves energy efficiency through heat exchange between internal air and external air.

Ventilation device having an electrostatic precipitating filter according to the present invention for solving the above-described technical problem, the main body having a constant internal space; A first air moving unit moving air introduced from the outside from one side of the main body to the other side; A second air moving unit moving indoor air to the outside in a direction intersecting with the first air moving unit; A total heat exchanger installed in the main body and exchanging heat between air moving the first air moving unit and air moving the second air moving unit; It is installed at the inlet side of the first air moving part, the air purifying part for removing fine dust and bacteria from the air flowing into the body.

And in the present invention, the air purification unit is installed across the inlet side, and it is preferable to purify the air by electrostatically spraying microdroplets in a direction perpendicular to the direction of movement of the contaminated air moving the first air movement unit. Do.

In addition, in the present invention, the air purification unit is installed on one side wall of the inlet side, and a microdroplet spraying unit spraying microdroplets into the inlet side by using a plurality of micro nozzles; An electrode portion spaced apart from the microdroplet spray portion at a position facing the microdroplet spray portion; It is preferable to include; a power source for forming an electric field between the micro-droplet spraying part and the electrode part.

In addition, in the present invention, the electrostatic spraying part is installed in front of the microdroplet spraying part, and includes a hole corresponding to the plurality of micronozzles and electrodes formed in each hole, for each nozzle of the microdroplet spraying part. It is preferable that an extraction plate for controlling spraying is further provided.

In addition, the ventilation device provided with the electrostatic precipitating filter according to the present invention is preferably installed in front of the electrostatic spraying part, and is further provided with an electrostatic filter for removing huge dust from contaminated air flowing into the electrostatic spraying part.

In addition, the ventilation device provided with the electrostatic precipitating filter according to the present invention is installed behind the electrostatic filter, and an activated carbon filter or photocatalytic device for removing non-aqueous gas and volatile organic compounds from contaminated air passing through the electrostatic filter is further provided. It is preferably provided.

In addition, in the present invention, it is preferable that the electrostatic filter is cleaned by water discharged through the electrostatic spraying unit.

In addition, in the present invention, the first air moving part is formed on one side of the main body, and an external air inlet passage for introducing external air into the main body; A first inlet side guide portion installed inside the main body and guiding external air passing through the external air inlet passage to the electrothermal exchange without leaking; A first discharge passage which is installed on the opposite side of the external air inlet passage and discharges air that has passed through the heat exchange part to the outside of the main body; A first discharge side guide portion installed on the opposite side of the first inlet side guide portion and guiding air passing through the heat exchange part to the first discharge passage; It is preferably installed on the first discharge side guide portion, the first pump to provide power to force the air to move to the first air moving portion; preferably comprises.

In addition, in the present invention, the second air moving part is formed on the other side of the main body, and the indoor air inlet passage for introducing indoor air into the main body; A second inlet side guide portion installed inside the main body and guiding indoor air passing through the indoor air inlet passage to the heat exchanger without leaking; A second discharge passage which is installed on the opposite side of the indoor air inlet passage and discharges air that has passed through the heat exchanger to the outside of the main body; A second discharge side guide portion installed on the opposite side of the second inlet side guide portion and guiding air passing through the heat exchanger portion to the second discharge passage; It is preferably installed on the second discharge side guide portion, a second pump that provides power to force the air to move to the second air moving portion.

In addition, in the present invention, it is preferable that the air purification unit is installed on the main body by a sliding method.

In addition, it is preferable that the ventilation device provided with the electrostatic precipitating filter according to the present invention is further provided with a sensor for detecting a replacement cycle of the air purification unit.

According to the ventilation device provided with the electrostatic precipitating filter of the present invention, the air pressure applied to the filtering is small, so energy consumption is low, and the energy of external air and internal air is recovered by using an electric heat exchanger, so that the energy efficiency is high, and the dust and the like are external. There is an advantage in that ventilation can be performed while all harmful substances in the air are removed.

1 is a perspective view showing a shape of a ventilation device having an electrostatic dust filter according to an embodiment of the present invention.
2 is a cross-sectional view showing the structure of a ventilation device having an electrostatic dust filter according to an embodiment of the present invention.
3 is a view showing the configuration of the air purification unit according to an embodiment of the present invention.
4 is a view showing the configuration of the electrostatic spray unit according to an embodiment of the present invention.
5 is a view showing the configuration of the heat exchanger according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Ventilation apparatus 100 having an electric dust collecting filter according to this embodiment, as shown in Figures 1 and 2, the main body 110, the first air moving unit 120, the second air moving unit 130, It may be configured to include a heat exchange unit 140 and the air purification unit 150.

First, as shown in FIGS. 1 and 2, the main body 110 has a shape of a box having a constant internal space, and preferably has a hexahedral shape as a whole. As shown in FIG. 2, the internal structure of the main body 110 is formed with partition walls 111 to divide the space into four centered around the heat exchanger 150.

Meanwhile, an installation part (not shown in the drawing) may be further provided on the outer surface of the main body 110 so that the main body 110 can be installed on a veranda ceiling or the like.

Next, the first air moving unit 120 is a component that moves air introduced from the outside from one side of the main body 110 to the other, as illustrated in FIGS. 1 and 2. That is, the first air moving unit 120 is to discharge air in the other direction of the body 110 after passing through the interior space of the body 110 after introducing air from the outside. Of course, in this process, air purification by the air purification unit 150 and heat exchange by the electrothermal exchange unit 140 are performed.

To this end, in this embodiment, the first air moving part 120 is specifically shown in FIG. 2, the external air inlet passage 121, the first inlet side guide part 122, and the first discharge passage 123 ), the first discharge side guide portion 124 and the first pump 125.

First, as shown in FIG. 1, the external air inflow passage 121 is formed on one side wall of the main body 110 and penetrates the main body 110 to introduce external air into the main body 110. It is a component. Therefore, the external air inlet passage 121 is installed so that the main body 110 is exposed to the external space in a state installed in the building. Of course, a separate inlet pipe (not shown in the drawing) may be connected.

Next, the inlet side guide portion 122 is installed inside the body 110, as shown in Figure 2, the outside air passing through the outside air inlet passage 121, the other space of the body 110 It is a component that guides all to the heat exchange part 140 without being discharged. Accordingly, the first inlet side guide portion 122 may be formed by the partition walls 111 or may be formed by a separate wall, as illustrated in FIG. 2.

Next, as shown in FIG. 2, the first discharge passage 123 is installed on the opposite side of the external air inlet passage 121 of the main body 110 and receives air passing through the heat exchanger 140. It is a component that discharges to the body 110 outside. Accordingly, the first discharge passage 123 is formed through the other side wall of the main body 110 and extends outside of the main body 110 to move external air that has undergone purification and heat exchange processes to each space in the room. .

Next, the first discharge side guide portion 124 is installed on the opposite side of the first inlet side guide portion 122 based on the total heat exchange portion 140, as shown in Figure 2, the heat exchange portion It is a component that guides the air that has passed through 140 to the first discharge passage 123. Therefore, the first discharge-side guide portion 124 may be formed by the partition walls 111 or may be formed by a separate wall.

Next, the first pump 125 is installed in the first discharge side guide 124, as shown in Figure 2, and provides power to force the air to the first air moving unit 120 Component. That is, the first pump 125 strongly discharges the air in the first discharge side guide portion 124 to the first discharge passage 123, so that external air flows through the external air inlet passage 121 and the first The inlet side guide portion 122 and the total heat exchange portion 140 are sequentially passed through the first outlet side guide portion 124 and finally discharged through the first outlet passage 123.

In this embodiment, the first pump 125 is provided with a pump having a capacity capable of sucking a sufficient amount of external air, and its structure can be variously changed.

Next, as illustrated in FIG. 2, the second air moving part 130 is a component that moves indoor air to the outside in a direction intersecting the first air moving part 120. That is, the second air moving unit 130 discharges the indoor air to the outside through the main body 110, but does not meet the external air passing through the first air moving unit 130, the indoor air in a staggered direction Is to move it.

To this end, in the present embodiment, the second air moving part 130 is specifically shown in FIG. 2, the indoor air inlet passage 131, the second inlet guide part 132, and the second outlet passage 133 ), the second discharge-side guide 134 and the second pump 135. First, the indoor air inlet passage 131 is formed on the opposite side of the external air inlet passage 121 of the main body 110, and penetrates the main body 110 to introduce indoor air into the main body 110. It is a component.

Therefore, the indoor air inlet passage 131 is installed through the main body 110, the end of which is connected to ducts or guide pipes (not shown in the figure) capable of moving the indoor air from the individual indoor spaces.

Next, the second inlet side guide portion 132 is installed inside the main body 110, as shown in Figure 2, the indoor air passing through the indoor air inlet passage 131, the main body 110 It is a component that guides the heat exchanger 140 without spillage to other spaces inside. Therefore, the second inlet side guide portion 132 may be formed by the dividing walls 111 or may be formed by a separate wall.

Next, the second discharge passage 133 is installed on the other side of the indoor air inlet passage 131 of the body 110, as shown in Figure 2, the air passing through the heat exchanger 140 It is a component that discharges to the body 110 outside. That is, since the second discharge passage 133 is for discharging indoor air that has passed through the main body 110 and the heat exchanger 140 to an external space, it is installed on the side wall of the external space side of the main body 110, Its end is installed to be exposed to the outer space.

Next, the second discharge-side guide portion 134 is installed on the opposite side of the second inlet-side guide portion 132, as shown in Figure 2, the air passing through the heat exchanger 140, the 2 It is a component that leads to the discharge passage (133). That is, the second discharge-side guide portion 134 is the indoor air inlet passage 131, the second inlet-side guide portion 132 and the indoor air passing through the heat exchanger 140 sequentially, the second discharge It is a path that moves to the passage 133. Therefore, the second discharge side guide portion 134 may be formed by the partition walls 111 or may be formed by a separate wall.

Next, the second pump 135 is installed in the second discharge side guide 134, as shown in Figure 2, and provides power to force the air to the second air moving unit 130 Component. That is, the second pump 135 strongly discharges the air in the second discharge-side guide portion 134 to the second discharge passage 133 so that indoor air flows through the indoor air inlet passage 131 and the second. The inlet side guide portion 132 and the total heat exchange portion 140 are sequentially passed through to the second outlet side guide portion 134.

In this embodiment, the second pump 135 is provided with a pump having a capacity capable of sucking a sufficient amount of external air, and its structure can be variously changed.

Next, the heat exchange unit 140 is installed in the main body 110, as shown in Figure 2, the air and the second air moving unit 130 for moving the first air moving unit 120 It is a component that exchanges heat between moving air. That is, when the temperature of the outside air passing through the heat exchanger 140 is higher than the temperature of the room air, the heat exchanger 140 allows the heat of the outside air to move to the room air, and the temperature of the room air When the temperature is higher than the outside air, the heat of the indoor air is transferred to the outside air.

To this end, in this embodiment, the heat exchanger 140 is a multi-layered heat exchange layer formed by mixing indoor air passages 142 and external air passages 144 in detail, as shown in FIG. 5. It has a structure to be formed, the indoor air passage 142 and the external air passage 144 has a structure that can move the gas in a direction orthogonal to each other.

Next, the air purification unit 150 is installed on the first inlet side guide portion 122 of the first air moving unit 130, as shown in Figure 2, flowing into the body 110 It is a component that removes fine dust and bacteria from the air. To this end, in the present embodiment, as shown in FIG. 2, the air purification unit 150 is installed across the first inlet side guide part 122 and moves the first air moving part 120. It is formed in a structure that purifies air by electrostatically spraying microscopic droplets having a fine size of about several μm to several tens of nm in a direction perpendicular to the direction of movement of external air. And in this embodiment, the air purification unit 150 is preferably installed in a sliding manner on the main body 110 because it can be easily replaced.

Specifically, as shown in FIG. 3, the air purification unit 150 may include a microliquid crystal spray unit 151, an electrode unit 152, and a power supply unit 153. First, the micro-droplet spray unit 151 is installed on one side wall of the first inlet side guide portion 122, as shown in Figure 3, the first inlet side guide portion using a plurality of micro nozzles (122) It is a component that sprays fine droplets inside.

Therefore, in this embodiment, the micro-droplet spraying unit 151 is a plurality of micro-nozzles 151a, as shown in FIG. 4, so that droplets can be sprayed with a fine size of several μm to several tens of nm as described above. ) Is preferably configured as a micro-nozzle array structure in which the use is arranged in a matrix form. At this time, the micro-nozzle 151a is formed to have a nozzle size of 100 μm or less, and may be formed using MEMS technology.

In addition, a plurality of pillars (not shown in the drawings) are formed to protrude around the micro-nozzle 151a, so that the surface of the micro-droplet spraying unit 151 is preferably hydrophobic.

Next, as shown in FIG. 3, the electrode part 152 is a component installed to be spaced apart from the microdroplet spray part 151 at a position facing the microdroplet spray part 151. The electrode unit 152 has a power supply in a condition in which an electric field such as a power supply having a polarity or ground or the same polarity opposite to the microdroplet spraying unit 151 or a relatively low size may be formed by the power supply unit 153. Is applied, so that an electric field is formed in the space between the micro-droplet spraying portion 151 and the electrode portion 152.

In this embodiment, the electrode part 152 is preferably a plate structure made of a porous material in which a plurality of fine through holes are formed or a net structure having a fine mesh structure. According to the electrode unit 152 having such a structure, the microdroplets sprayed from the microdroplet spray unit 151 move in the direction of the electrode unit 152 to perform air purification and sterilization, and the electrode unit 152 ), it has the advantage of being discharged to the outside.

Next, the power supply unit 153 is a component that forms an electric field between the microdroplet spraying unit 151 and the electrode unit 152. Specifically, the power supply unit 153 applies a high voltage to the microdroplet spraying unit 151 and configures the electrode unit 152 to ground, so that the charged microdroplets are transferred from the microdroplet division unit 151. It is preferable to continuously perform air purification and sterilization while continuously flowing in the direction of the electrode portion 152.

Meanwhile, in the present embodiment, the air purification unit 150 is preferably further provided with an extraction plate 151c. 4, the extraction plate 151c is installed in front of the microdroplet spraying unit 151, and a hole 151b and each hole 151b corresponding to the plurality of micronozzles 151a are provided. It is a component that controls the electrostatic spray for each nozzle of the microdroplet spray unit 151, including an electrode formed in.

When the extraction plate 151c is used in this way, as shown in FIG. 4, the microdroplets sprayed from the micronozzle 151a can be more finely divided.

In addition, it is preferable that the electrostatic filter 160 is further provided in the air purification unit 150 according to the present embodiment. The electrostatic filter 160 is installed in front of the air purification unit 150, as shown in FIG. 3, and is a component that removes huge dust from contaminated air flowing into the air purification unit 150. Since this huge dust is a cause of increasing the burden on the dust collecting performance of the air purification unit 150, it is removed before entering the interior of the housing 110.

In addition, the air purification unit 150 according to the present embodiment is preferably further provided with an activated carbon filter or a photocatalytic device 170. The activated carbon filter or photocatalyst device 170, as shown in Figure 3, is installed behind the electrostatic filter 160, the non-aqueous gas and volatile organic compounds in the contaminated air passing through the electrostatic filter 160 It is a component to be removed. Since the non-aqueous gas and the volatile organic compound are not removed by the micro-droplets by the air purification unit 150, they are previously removed using the activated carbon filter or photocatalytic device 170.

In this embodiment, the electrostatic filter 160 is preferably self-cleaned by the water passing through the air purification unit 150 and discharged. To this end, in the present embodiment, as shown in FIG. 3, a supply line 155 is formed to collect and purify the fine droplets passing through the electrode part 140 and supply the discharged water to the electrostatic filter 160. , It is preferable to self-clean the electrostatic filter 160.

Next, the ventilation device 100 according to this embodiment is preferably further provided with a sensor 180 for detecting the replacement cycle of the air purification unit 150. 2, the sensor 180 is installed inside the main body 110 to detect the degree of contamination of the air purification unit 150 to inform the replacement or cleaning time of the air purification unit 150. .

100: ventilation apparatus having an electrostatic dust filter according to an embodiment of the present invention
110: body 120: the first air moving unit
130: second air moving unit 140: heat exchange unit
150: air purification unit 160: electrostatic filter
170: photocatalyst device 180: sensor

Claims (4)

A body having a constant internal space;
A first air moving unit moving air introduced from the outside from one side of the main body to the other side;
A second air moving unit moving indoor air to the outside in a direction intersecting with the first air moving unit;
A total heat exchanger installed in the main body and exchanging heat between air moving the first air moving unit and air moving the second air moving unit;
It is installed at the inlet of the inlet side of the first air moving part, and an air purifying part for removing fine dust and bacteria from the air flowing into the main body.
The air purification unit,
A microdroplet spraying unit installed on one side wall of the inlet side and spraying microdroplets into the inlet side by using a plurality of micro nozzles;
An electrode portion spaced apart from the microdroplet spray portion at a position facing the microdroplet spray portion;
A power supply unit for forming an electric field between the microdroplet spraying unit and the electrode unit; And
It is installed in front of the micro-droplet spraying part, and includes a hole corresponding to the plurality of micro-nozzles and electrodes formed in each hole to control the electrostatic spray for each nozzle of the micro-droplet spraying part; containing Ventilation device having an electric dust collecting filter, characterized in that. According to claim 1, The first air moving unit,
An external air inlet passage formed on one side of the main body and introducing external air into the main body; A first inlet side guide portion installed inside the main body and guiding external air passing through the external air inlet passage to the electrothermal exchange without leaking; A first discharge passage which is installed on the opposite side of the external air inlet passage and discharges air that has passed through the heat exchange part to the outside of the main body; A first discharge side guide portion installed on the opposite side of the first inlet side guide portion and guiding air passing through the heat exchange part to the first discharge passage; And a first pump installed on the first discharge side guide portion and providing power to force air to move to the first air moving portion. According to claim 2, The second air moving unit,
An indoor air inlet passage formed on the other side of the main body and introducing indoor air into the main body; A second inlet side guide portion installed inside the main body and guiding indoor air passing through the indoor air inlet passage to the heat exchanger without leaking; A second discharge passage which is installed on the opposite side of the indoor air inlet passage and discharges air that has passed through the heat exchanger to the outside of the main body; A second discharge side guide portion installed on the opposite side of the second inlet side guide portion and guiding air passing through the heat exchanger portion to the second discharge passage; And a second pump installed on the second discharge-side guide portion and providing power to force air to move to the second air moving portion. delete

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