KR20050026102A - Filter structure of ventilation system - Google Patents

Abstract

A filter structure of a ventilation system is provided to remove bad smell in the air by a deodorizing filter having TiO2 as a photo-catalyst and a light lamp for supplying light to the photo-catalyst, thereby carrying out anti-microbial operation in addition to the deodorizing operation. A filter structure of a ventilation system includes a dust collecting filter part(76) for filtering impurities in the air. A deodorizing filer part(78) is formed at a side of the dust collecting part and having a photo-catalyst for removing bad smell and carrying out anti-microbial operation for the air. Filter supporting parts(74) support the above filters. A light source(79) is mounted at a side of the deodorizing filter part for supplying light to the photo-catalyst of the deodorizing filter part.

Description

Filter structure of ventilation system

The present invention relates to a ventilation system, and more particularly to a filter structure of the ventilation system to remove the fine dust mixed with the outside air as well as the smell by a clean filter.

In recent years, due to problems such as energy conservation and noise, the residential space of human beings is gradually becoming airtight and insulated. However, the air in these closed spaces gradually changes to carbon dioxide and contaminates over time, thereby inhibiting the breathing of life.

Therefore, a place where many people stay in a narrow space, such as an office or a vehicle, needs to be frequently ventilated. In this case, a ventilation system using an electrothermal exchange method is usually used. This is for supplying the outside air while maintaining the indoor air temperature, and for exhausting the indoor air.

1 is a perspective view of an exterior of a conventional ventilation device.

As shown in the drawing, the outside air inlet 12 is formed on one side of the main body case 10 forming the exterior so as to suck the outside air. A suction duct (not shown) is provided inside the external air inlet 12 to allow the external air sucked from the suction hole 12 to reach the heat exchanger 14 to be described below. ) Is formed to be a passage of external air.

In order to exchange heat between the air sucked from the outside and the air discharged from the outside to the outside, an electrothermal heat exchanger 14 as shown in FIG. 2 is provided at the inner center of the main body case 10. It is configured to have.

The heat exchanger 14 as described above normally exchanges moisture and sensible heat for exchanging latent heat by means of highly efficient heat exchange membranes forming layers of the different flow paths by allowing each air having a temperature difference to pass through different flow paths. Follow the principle of electrothermal exchange by heat.

The external air passing through the heat exchanger 14 from the external air inlet 12 is formed on the opposite side to the suction hole 12 by an external air supply unit (not shown) formed in the main body case 10. It is supplied into the room through the external air supply hole (16).

On the other hand, the indoor air inlet 18 is formed on the side of the external air supply hole 16, the indoor air is sucked into the main body case 10 of the ventilator. In addition, an indoor air exhaust hole 20 through which the indoor air sucked into the inside of the ventilator from the indoor air intake port 18 is formed at a side of the external air intake port 12.

The total heat exchanger 14 is formed in the four corners of the total heat exchanger support frame 22 long before and after, the lower one side of the heat exchanger 14 is provided with a HEPA filter 24. The hepa filter 24 serves to filter foreign matter mixed in the outside air.

That is, the HEPA (High Efficiency Particulate Air, 24) is a filter paper made of asbestos fiber, which is a special specially charged fiber, which filters even harmful substances and polluted dust. It cleans up to 99.97% of harmful substances such as mites, viruses, and fungi, and pollutants of about 0.3 microns in size, the most harmful particles. Therefore, it serves to purify the contaminated air to a fairly clean state.

3 shows an example in which the HEPA filter 24 is configured in a pleated form in cross section. According to this, the HEPA filter 24 is zigzag-shaped between the filter support parts 24 'of both sides.

In this way, when the hepa filter 24 is formed to be pleated, the screen area of the filter paper as the hepa filter 24 can be formed to the maximum. The HEPA filter 24 is installed at one side of a passage through which external air flows into the inside to filter external air.

However, the above conventional technologies have the following problems.

That is, in the conventional ventilator as described above, the HEPA filter 24 as described above is used to clean the outside air. However, the HEPA filter 24 conventionally used as described above is contaminated with fine harmful substances. Only serves to remove the dust, there is a problem that can not remove the smell of tobacco, pet smell, toilet smell, garbage smell, unpleasant odor and, in particular, harmful odors such as formaldehyde in the home.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to provide a filter structure of a ventilation system having a odor removing function as well as filtering harmful substances and pollutants harmful to the human body.

The filter structure of the ventilation system according to the present invention for achieving the above object is a dust collecting filter for filtering foreign matter in the air; A deodorizing filter part formed at one side of the dust collecting filter part and provided with a photocatalyst to remove odor and antibacterial activity in the air; A filter support part for supporting the dust collecting part and the deodorizing filter part; Is installed on one side of the deodorizing filter unit is characterized in that it comprises a light source for providing light to the photocatalyst provided in the deodorizing filter unit.

One side of the filter support is further formed with a lamp support for supporting the light source.

One end of the lamp support is connected to one side of the filter support, and the other end is configured to be connected to one side of the light source.

The photocatalyst is characterized in that the titanium dioxide (TiO₂).

In addition, the light source is characterized in that the fluorescent lamp.

According to the filter structure of the ventilation system according to the present invention having such a configuration, since not only dust but also odors are removed, there is an advantage that clean air is supplied to the room.

4 is an exploded perspective view of an example of a ventilation system employing a ventilation system filter structure according to the present invention, and FIG. 5 illustrates an internal configuration of the ventilation system according to the present invention. 6 is a cross-sectional view of a ventilation system filter structure according to the present invention installed in the total heat exchanger, and FIGS. 7A and 7B show a perspective view and a cross-sectional view of the clean filter according to the present invention, respectively.

As shown in these figures, a substantially rectangular box-shaped body case 50 forms an appearance. The body case 50 forms the appearance of the entire product, and supports the installation of the internal structure to protect, and at the same time serves to block foreign matter from entering the product from the outside.

On the left side of the main body case 50, an external air inlet 52, which is an inlet for inhaling external air, is installed to protrude laterally. An inlet mounting hole (not shown) is formed at the left end of the main body case 50 so that the external air inlet 52 is inserted and mounted therein.

Inside the outside air inlet 52, a left suction duct 54 is disposed between the outside air intake 52 and the heat exchanger 60 so that the outside air drawn from the intake 52 can reach the heat exchanger 60, which will be described below. Is formed. That is, the left suction duct 54 serves as a suction passage that guides the outside air to be sucked smoothly.

An internal heat exchanger 60 is provided at an inner central portion of the main body case 50. The heat exchanger (60) has a hexagonal columnar shape and has a cross-flow plate type structure. That is, it is configured to separate the supply and exhaust passages with a partition plate of special processed paper so that outside air and indoor air are not mixed with each other.

Therefore, the heat exchanger 60 as described above allows each air having a temperature difference to pass through different flow paths, thereby allowing moisture and sensible heat to exchange latent heat by a high-efficiency heat exchanger film forming layers of the different flow paths. Heat exchange causes heat exchange. That is, the special processing paper used for the total heat exchanger 60 is characterized by passing only heat and moisture without passing air.

The total heat exchanger (60) having the configuration described above performs electrothermal exchange between the air supply and the exhaust in the apparatus, absorbs the heat of the air from the exhaust to the outside, and transfers it to the air supplied to the room, whereby the state of the indoor air is Make it less affected.

This electrothermal ventilation mode may be implemented by the user's selection. That is, in general, the heat transfer ventilation mode as described above is mainly used in summer and winter when the temperature difference between the indoor and outdoor is large, and when the temperature difference between the indoor and outdoor is not very large, such as spring or autumn, the damper 94 will be described below. By changing the passage of the air discharged to the outside to prevent the air exhausted to pass through the heat exchanger 60, it can be used in the normal ventilation mode.

On the other hand, the upper and lower ends of the heat exchanger 60 having a hexagonal cross-section is provided with a support frame 61, the heat exchanger 60 long before and after. The support frame 61 supports the load of the total heat exchanger 60 so that the total heat exchanger 60 is firmly supported, and also serves as a guide rail when the front heat exchanger 60 is attached and detached.

The support frame 61 of the heat exchanger 60 is an element support part 62 for guiding forward and backward movement while supporting the load of the heat exchanger 60, and a filter extending laterally from the element support part 62. It consists of a support part 63.

The element support portion 62 is composed of a main body contact surface 62 'contacting the main body case 50, and an element contact surface 62 "formed to protrude upward from both ends of the main body contact surface 62'. The element support portion 62 has a central portion recessed to form a tunnel shape. The lower end portion of the tunnel shape is in contact with the main body case 50, and the filter support portion 63 is formed of the element support portion 62. And an inclined surface 63 'which is formed to be inclined laterally downward from the side end, and a bent rib 63 "which is formed to be bent vertically from the inclined surface 63'.

Side guides 64 are provided at the side edges of the heat exchanger 60. The side guide 64 is composed of an element support portion 65 surrounding the edge of the heat exchanger 60, and a filter support portion 66 protruding from the element support portion 65. The filter support portion 66 is composed of a vertical surface 66 'protruding vertically from the element support portion 65, and a bending rib 66 "formed laterally bent from the vertical surface 66'.

That is, the element support portion 65 of the side guide 64 is provided in the corner of the heat exchanger 60 is formed in a substantially 'b' shape so as to be in contact with both sides of the corner at the same time, the 'b' shaped A pair of filter support portions 66 are formed to protrude from each surface of the element support portion 65.

Accordingly, the prefilter 68 is mounted to slide forward and backward between the support frame 61 and the filter support 63 of the side guide 64 facing each other. The prefilter 68 is provided to both sides of the lower portion of the total heat exchanger (60) to filter the foreign matter in the air.

That is, the pre-filter 68 provided on the lower left side of the total heat exchanger 60 into which the external air is sucked increases the cleanliness of the air supplied to the room by filtering out the foreign matter mixed in the external air, and the heat exchanger 60 ) Protects against foreign objects. In addition, the pre-filter 68 provided on the lower right side of the heat exchanger (60) filters the foreign matter mixed in the air exhausted from the inside to the outside, thereby protecting the heat exchanger (60) to extend the life. Will be

The total heat exchanger (60) is generally provided with two before and after, such a heat exchanger (60) is supported by the support frame 61 of the heat exchanger (60) and slide back and forth. Therefore, the front surface of the heat exchanger 60 is further provided with a handle 71 for facilitating forward and backward movement.

The upper right side of the total heat exchanger 60 is further provided with a clean filter (73). The clean filter 73 serves to filter dust particles in the outside air to be sucked again and at the same time to remove the odor in the air.

As shown in FIGS. 7A and 7B, the clean filter 73 includes a filter support part 74 formed at an edge to support an internal filter, a dust collecting filter part 76 to remove even fine dust in the air, and It is composed of a deodorizing filter portion 78 for removing the odor in the air.

The dust collecting filter portion 76 is pleated in a zigzag shape, and the pleated grooves 76 'are formed on the upper and lower surfaces to shift each other. In addition, the dust collecting filter 76 is generally composed of a HEPA (High Efficiency Particulate Air), and removes even the fine dust in the air with a strong adsorption force.

In other words, the pre-filter 68 of the fibrous mat form, the large dust in the air is first filtered, the heat is transferred while passing through the heat exchanger 60, the air passed through the heat exchanger (60) Is filtered by the dust collecting filter unit 76 of the clean filter 73 to fine foreign matter again.

On the other hand, the back of the dust collecting filter 76 is provided with a deodorizing filter 78. The deodorizing filter unit 78 is an odor removing adsorbent 78 'which is seated in the pleated groove 76' of the dust collecting filter unit 76, and the clean filter to prevent separation of the adsorbent 78 '. It consists of a departure prevention surface 78 "provided in the outer surface (upper surface in FIG. 7B) of 73. As shown in FIG.

A photocatalyst is used as the odor removing adsorbent 78 '. Titanium dioxide (TiO2) is used as a typical photocatalyst. The photocatalyst (titanium dioxide Tio2), which is a fine powder of white color, has negative (-) electricity when it is subjected to ultraviolet rays from sunlight or fluorescent light. Holes (h +) with electrons (e-) and positive (+) electricity are formed. Among them, the hole (h +) forms a particularly powerful oxidizing hydroxide (OH Radical), which has a stronger oxidizing power than chlorine for sterilization or ozone hypochlorite.

In addition, the electrons generate oxygen ions adsorbed on the photocatalyst to oxygen ions, which produce intermediates and peroxides of the oxidation reaction or water reaction through hydrogen peroxide. According to this reaction, the photocatalyst enables the pollution prevention effect, the air purification effect, the water purification effect, the sterilization effect, and the odor removal effect.

When a photocatalyst (titanium dioxide Tio2) is used as the adsorbent 78 'as described above, it is preferable to provide a separate fluorescent lamp or a light emitter such as an LED (LED) together. That is, the photocatalyst is a material that causes a catalytic reaction upon receiving light, so a light source must be installed to continuously perform the adsorbent function.

Therefore, a fluorescent lamp 79 is further installed on one side of the deodorization filter unit 78. The fluorescent lamp 79 is provided at a predetermined distance from the escape preventing surface 78 ″ so that light can be projected onto the adsorbent 78 ′ composed of titanium dioxide.

To this end, a lamp support 79 'is formed at one end of the filter support 74. As shown, the lamp support portion 79 'is formed in pairs at both ends to extend upward at a predetermined angle from the filter support portion 74 surrounding the internal filter to meet at the center portion.

In addition, one end of the fluorescent lamp 79 is supported at an upper end portion, that is, a vertex portion of the filter support portion 74. Therefore, when power is supplied from the outside to the fluorescent lamp 79, the adsorbent 78 'which receives the light of the fluorescent lamp 79 causes a catalytic reaction to deodorize.

The left rear end of the main body case 50 is provided with an indoor air outlet 56 for discharging the indoor air to the outside, the outlet 56 is an outlet mounting hole (not shown) formed in the main body case 50 Is inserted and fixed). In addition, an exhaust fan housing 58 is formed inside the outlet mounting hole to guide the indoor air forcedly blown by the exhaust fan 80 to the indoor air outlet 56.

An indoor air exhaust fan 80 is provided at one side of the exhaust fan housing 58. The exhaust fan 80 serves to forcibly blow the air sucked through the indoor air intake port 88 to be described below to the discharge port 56. Preferably, the exhaust fan 80 is configured as a siroco fan.

An external air outlet 82 is formed at the right end of the main body case 50, that is, on the side opposite to the position at which the external air inlet 52 is installed. The outlet 82 is inserted into the outlet mounting hole 84 formed on the right side of the main body case 50 and is installed to protrude in a right direction from the right side of the main body case 50 to the right side. In addition, an air supply fan housing 86 is formed in the air outlet mounting hole 84 to guide external air forcedly blown from the air supply fan 96 to the air outlet 82 to be described below.

An indoor air suction port 88 is provided at the right rear end of the main body case 50, that is, the opposite side to the position where the indoor air discharge port 56 is installed. The indoor air inlet 88 is installed to protrude from the right side of the main body case 50 to the right side, and is fixed to the circular indoor inlet mounting hole 90 formed at the rear end of the right side of the main body case 50. do. In addition, a right suction duct 92 is formed inside the indoor suction hole mounting hole 90 to guide the air sucked from the indoor air suction hole 88 to the heat exchanger 60.

On the other hand, a damper 94 is provided inside the right suction duct 92 to selectively flow the indoor air sucked through the indoor air suction port 88 to the heat exchanger 60. That is, the damper 94 opens and closes the right suction duct 92 under the control of the control box 100 to be described below. Therefore, if the damper 94 shields the right suction duct 92, the indoor air sucked through the indoor air intake port 88 does not pass through the heat exchanger 60, and the indoor air outlet 56 Is discharged to the outside through).

An air supply fan 96 is provided between the external air outlet 82 and the indoor air outlet 56 to force external air to the external air outlet 82. Therefore, the outside air sucked through the outside air inlet 52 is discharged into the room through the outside air outlet 82 by the air supply fan 96.

The control box 100 is installed at the right end of the main body case 50. A control unit is formed inside the control box 100 to control the operating conditions of the ventilation system. That is, the power is interrupted to turn on / off the ventilation system, and the fan speed is controlled by controlling the fan rotation speed of the air supply fan 96 and the exhaust fan 80. On the other hand, by controlling the driver (not shown) of the damper 94 controls the ventilation method and the like to enable the selection of the total heat exchange mode or normal ventilation mode.

On the front of the main body case 50 is installed a ceiling fixture 102 to allow the ventilation system is installed on the ceiling of the house. In addition, a check hole 104 is formed at the front center portion of the main body case 50. An inspection door 106 is provided on the front surface of the inspection opening 104 to selectively open and close the inspection opening 104. Therefore, when it is necessary to replace or check the heat exchanger 60, the inspection door 106 is opened and the heat exchanger 60 can be taken out to work.

Hereinafter, a state in which air outside the room flows through the ventilation system according to the present invention having the configuration as described above will be described with reference to FIGS. 8 and 9.

8 shows a state of air flow through the ventilation system when the full heat ventilation mode is activated. This electrothermal ventilation mode is generally used when there is a large difference in temperature and humidity between indoors and outdoors, such as summer or winter.

Referring to the ventilation state as shown in the drawing, the damper 94 opens the right suction duct 92 according to a control command in the control box 100 according to the user's selection of the heat transfer ventilation mode.

In addition, according to the operation of the air supply fan 96, external air is sucked into the ventilation system through the external air inlet 52, and the external air is guided by the left suction duct 54 to transfer the heat. It is sucked into the total heat exchanger (60) through the lower left side of the exchanger (60). At this time, since the external air passes through the pre-filter 68 mounted on the lower left side of the heat exchanger (60), foreign matter in the air is first filtered and then sucked into the heat exchanger (60).

The air sucked into the heat exchanger (60) exchanges heat and moisture from the discharged indoor air and then is discharged through the upper right side of the heat exchanger (60). At this time, since the clean filter 73 is installed on the upper right side of the heat exchanger (60), foreign matters of the air passing through the heat exchanger (60) are filtered again, and even the smell is removed, resulting in cleaner air.

That is, external air passing through the total heat exchanger 60 passes through the clean filter 73, and odor molecules in the air are adsorbed and removed by the adsorbent 78 ′ provided in the deodorization filter unit 78. Therefore, outside odors are prevented from entering the room.

Air passing through the heat exchanger (60) and the clean filter (73) is forcibly blown by the air supply fan (96) through an external air outlet (82) installed on the right side of the main body case (50). It is discharged to the room.

On the other hand, the indoor air is exhausted to the outside by the operation of the exhaust fan 80, the indoor air is sucked into the ventilation system through the indoor air inlet 88 and then guided by the right suction duct 92 And is sucked into the total heat exchanger (60) through the lower right side of the total heat exchanger (60).

At this time, since the pre-filter 68 is mounted on the lower right side of the heat exchanger 60, foreign matter in the indoor air is filtered out. Therefore, since the clean air is sucked into the heat exchanger (60), the heat exchanger (60) is protected and its life is extended more.

The indoor air sucked into the heat exchanger (60) exchanges heat and moisture to outside air sucked from the outside, and then exits through the lower left side of the heat exchanger (60). The indoor air exiting the heat exchanger (60) is forcedly blown by the exhaust fan (80) and exhausted to the outside through the indoor air outlet (56) provided at the rear end of the left side of the main body case (50). .

Next, an air flow state in the general ventilation mode will be described with reference to FIG. 9. In the general ventilation mode, when indoor and outdoor temperature and humidity differences are small, such as spring or autumn, indoor air is bypassed by the heat exchanger 60 and bypassed immediately.

Therefore, when the user selects the general ventilation mode, the damper 94 shields the right suction duct 92 according to a control command inside the control box 100. In this case, the air sucked through the indoor air intake port 88 is forcibly blown to the indoor air outlet 56 by the exhaust fan 80 and discharged to the outside without passing through the heat exchanger 60.

On the other hand, when looking at the flow of the outside air, according to the operation of the air supply fan 96, the outside air is sucked into the ventilation system through the outside air inlet 52, the outside air is the left side suction duct (54) It is guided by) and is sucked into the heat exchanger 60 through the lower left side of the heat exchanger (60). At this time, since the external air passes through the pre-filter 68 mounted on the lower left side of the heat exchanger (60), foreign matter in the air is first filtered and then sucked into the heat exchanger (60).

Since the air sucked into the heat exchanger (60) does not pass through the heat exchanger (60), the discharged indoor air is discharged through the upper right side of the heat exchanger (60) without exchanging heat and moisture. At this time, since the clean filter 73 is installed on the upper right side of the total heat exchanger 60, foreign matters of the air passing through the total heat exchanger 60 are filtered again, and even the smell in the air is removed, resulting in cleaner air.

Air passing through the heat exchanger (60) and the clean filter (73) is forcibly blown by the air supply fan (96) through an external air outlet (82) installed on the right side of the main body case (50). It is discharged to the room.

As described above, in the general ventilation mode, unlike in the case of the total heat ventilation mode, heat and moisture are not exchanged inside the heat exchanger 60.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention may be made by those skilled in the art within the above technical scope.

For example, in the above embodiment, although the fluorescent lamp 79 is used as the light source, other light emitters such as LEDs may be used.

According to the ventilation system as described above, in addition to the dust collecting filter portion composed of hepa filter, it was provided with a clean filter further provided with a deodorizing filter portion capable of removing odor in the air. In addition, the deodorization filter unit is provided with a titanium dioxide (TiO 2) and a fluorescent lamp as a photocatalyst.

Therefore, the deodorizing filter part composed of a photocatalyst can remove odors in the air as well as antibacterial action, thereby providing more clean air in the room, thereby creating a pleasant environment.

As a result, according to the ventilation system according to the present invention, not only small foreign substances such as fine dust in the air but also bad odors in the air are removed, thereby providing a comfortable environment for the human being, and bringing the effect of improving the purchase desire of the ventilation system as a whole. .

1 is a perspective view of a ventilation apparatus according to the prior art.

Figure 2 is a perspective view of the heat exchanger and hepa filter of the ventilation apparatus according to the prior art.

Figure 3 is a cross-sectional view of the ventilator hepa filter according to the prior art.

Figure 4 is an exploded perspective view showing the main configuration of the ventilation system employing a preferred embodiment of the ventilation system filter structure according to the present invention.

5 is a perspective view showing the internal configuration of a ventilation system employing a preferred embodiment of the ventilation system filter structure according to the present invention.

Figure 6 is a front view showing a preferred embodiment of the ventilation system filter structure according to the present invention installed in the total heat exchanger.

Figure 7a is a perspective view showing a preferred embodiment of the ventilation system filter structure according to the present invention.

FIG. 7B is a sectional view of FIG. 7A; FIG.

8 is a state diagram showing a state in which air flows inside the ventilation system according to the present invention during the full-heat ventilation mode operation.

9 is a state diagram showing a state in which air flows inside the ventilation system according to the present invention during the normal ventilation mode operation.

Explanation of symbols on the main parts of the drawings

50. Main body case 52. External air intake

54. Left suction duct 56. Indoor air outlet

58. Exhaust Fan Housing 60. Heat Exchanger

61. Support frame 62,65. Element support

63,66. Filter Support 68. Pre Filter

71. Handle 73. Clean filter

74. Filter support 76. Dust collecting filter

76 '. Pleated groove 78. Deodorizing filter part

78 '. Sorbent 78 ".

79. Fluorescent lamp 79 '. Lamp support

80. Exhaust fan 82. External air outlet

84. Outlet mounting hole 86. Air supply fan housing

88. Indoor air intake port 90. Indoor air intake hole

92. Right suction duct 94. Damper

96. Air supply fan 100. Control box

102. Ceiling Fixture 104. Checking Fixture

106. Inspection Door

Claims (5)

A dust collecting filter unit for filtering foreign substances in the air; A deodorizing filter part formed at one side of the dust collecting filter part and provided with a photocatalyst to remove odor and antibacterial activity in the air; A filter support part for supporting the dust collecting part and the deodorizing filter part; The filter structure of the ventilation system, characterized in that it comprises a light source provided on one side of the deodorizing filter unit for providing light to the photocatalyst provided in the deodorizing filter unit The filter structure as claimed in claim 1, wherein a lamp support portion for supporting the light source is further formed on one side of the filter support portion. 3. The filter structure according to claim 2, wherein one end of the lamp support part is connected to one side of the filter support part, and the other end is connected to one side of the light source. The filter structure of a ventilation system according to claim 1, wherein the photocatalyst is titanium dioxide (TiO₂). 5. The filter structure according to any one of claims 1 to 4, wherein the light source is a fluorescent lamp.