KR20220017232A - Air purifying apparatus - Google Patents

Abstract

The present invention relates to an air purifier that is advantageous in maintenance. According to the present invention, a housing introduces air into a passage part through an inlet by an exhaust fan and discharges the air through an outlet, and the passage part has an inlet space communicating with the inlet at one of a filter mounting space, an inlet space passing through the inlet on one side of the filter mounting space, and a discharge space communicating with the outlet on the other side of the filter mounting space. An inlet damper opens and closes the inlet. An outlet damper opens and closes the outlet. A metal filter is installed in the filter mounting space to collect harmful substances in the introduced air, and is formed of a metal material to have pores of a size that allows ash remaining in the process of decomposition of the collected harmful substances to escape. A heater heats the metal filter.

Description

Air purifying apparatus

The present invention relates to an air purifying device for collecting foreign substances in indoor polluted air and then discharging purified air.

In general, in homes or restaurants, an air conditioning system for forcibly sucking indoor polluted air and discharging it to the outdoors is basically provided. Specifically, polluted air in the room is sucked through a hood mounted on the top of the counter or an exhaust fan mounted on a ceiling or wall, and the sucked polluted air is discharged to the outside through a duct.

On the other hand, a filter-type air purifier in which a plurality of plate-type filters such as a pre-filter, a carbon filter, and a HEPA filter are sequentially arranged is installed inside the duct, and is configured to remove foreign substances contained in the inhaled polluted air.

However, looking at the configuration of the various filters described above, the filter-type air purifier tends to focus on filtering dust, etc. contained in polluted air. According to such a filter type air purification device, it can be seen that purification of soot, odor, bacteria, etc. contained in polluted air is not performed. In addition, the filter-type air purifier requires frequent replacement of the filter on a regular basis, so maintenance costs are high.

Korean Patent Publication No. 10-1550261 (published on November 14, 2014)

An object of the present invention is to provide an air purifying device advantageous for maintenance.

An air purifier according to the present invention for achieving the above object includes a housing, a damper for an inlet, a damper for an outlet, a metal filter, and a heater. The housing introduces air into the passage through the inlet by the exhaust fan and discharges it through the outlet. have space The damper for the inlet opens and closes the inlet. The damper for the outlet opens and closes the outlet. The metal filter is installed in the filter mounting space to collect harmful substances in the inlet air, and is formed of a metal material to have pores of a size that allows the ash remaining in the process of decomposition of the collected harmful substances to escape. The heater heats the metal filter.

Here, the metal filter may be formed of any one of a structure in which metal mesh nets are stacked, a metal foam structure, and a structure in which metal threads are entangled. In another aspect, the metal filter may have a structure having flow paths through which air passes in a form in which both ends are alternately sealed by partitioning in parallel with each other by porous metal barrier ribs.

The housing may include a filter inlet formed in a portion corresponding to the filter mounting space, a door opening and closing the filter inlet, and a sealing mechanism for sealing the periphery of the metal filter to the filter mounting space.

According to the present invention, since the metal filter can be used for a long time without cleaning, it is advantageous for maintenance and has the effect of reducing costs.

1 is a perspective view of an air purifying device according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of FIG. 1 .
3 is a perspective view of an example of a metal filter.
4 is a perspective view of another example of a metal filter.
5 is a cross-sectional view of another example of a metal filter.
6 is a perspective view illustrating a process of separating the metal filter from the housing and mounting the metal filter back to the housing so that both ends thereof are reversed.
7 is a perspective view illustrating an area A of FIG. 6 .
Fig. 8 is a plan view of the sealing mechanism in Fig. 6;
9 is a cross-sectional view for explaining an example in which the metal filter operates in a state in which the metal filter is mounted on the housing through the process shown in FIG. 6 .
10 is a cross-sectional view for explaining a regeneration process of a metal filter.

The present invention will be described in detail with reference to the accompanying drawings as follows. Here, the same reference numerals are used for the same components, and repeated descriptions and detailed descriptions of well-known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted. The embodiments of the present invention are provided in order to more completely explain the present invention to those of ordinary skill in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer description.

1 is a perspective view of an air purifying device according to an embodiment of the present invention. FIG. 2 is a cross-sectional view of FIG. 1 . 3 is a perspective view of an example of a metal filter. 4 is a perspective view of another example of a metal filter. 5 is a cross-sectional view of another example of a metal filter.

1 to 5 , the air purifier 100 according to an embodiment of the present invention includes a housing 110 , a damper 120 for an inlet port, a damper 130 for an outlet port, and a metal filter 140 . , metal filter), and a heater 150 .

The housing 110 introduces air into the passage 113 through the inlet 111 by the exhaust fan and discharges it through the outlet 112 . Here, when the housing 110 is disposed indoors, the indoor polluted air may be introduced into the passage 113 through the inlet 111 . The exhaust fan may be installed in the exhaust port 112 of the housing 110 or installed in the exhaust duct connected to the exhaust port 112 of the housing 110 to provide air suction power.

The passage part 113 includes a filter mounting space 113c, an inlet space 113a communicating with the inlet 111 from one side of the filter mounting space 113c, and an outlet 112 from the other side of the filter mounting space 113c. It has an exhaust space (113b) through. The housing 110 may be formed in a form in which the filter mounting space 113c has a rectangular cross-sectional area and extends from the inlet space 113a to the outlet space 113b.

The inlet damper 120 opens and closes the inlet 111 . The inlet damper 120 opens the inlet 111 so that indoor polluted air flows into the passage 113 . The inlet damper 120 maintains the inlet 111 closed while the regenerated polluted air generated in the regeneration process of the metal filter 140 is circulated through a regeneration circulation pipe 160 to be described later and undergoes regeneration purification treatment. do.

The inlet damper 120 may be configured such that a damper blade is rotatably coupled around the inlet 111 by a damper shaft and opens and closes by a damper rotation motor. Although not shown, whether the damper blade is opened or closed may be detected by a proximity sensor. A signal sensed from the proximity sensor may be provided to a controller. The controller may drive and control the damper rotation motor based on a signal sensed from the proximity sensor.

The damper 130 for the outlet opens and closes the outlet 112 . The damper 130 for the outlet opens the outlet 112 so that the purified air is discharged. While the regeneration polluted air generated in the regeneration process of the metal filter 140 is circulated through the regeneration circulation pipe 160 and undergoes regeneration purification treatment, the damper 130 for the outlet maintains the outlet 112 in a closed state.

The damper 130 for the outlet may be configured such that a damper blade is rotatably coupled to a periphery of the outlet 112 by a damper shaft and opens and closes by a damper rotation motor. Whether the opening/closing operation of the damper blade is detected by the proximity sensor may be provided to the controller. The controller may drive and control the damper rotation motor based on a signal sensed from the proximity sensor.

The metal filter 140 is mounted in the filter mounting space 113c to collect harmful substances such as fine dust/oil components in the inlet air. The metal filter 140 is formed of a metal material to have pores sized to allow ash remaining in the process of decomposing the collected harmful substances to escape.

That is, the harmful substances collected around the pores of the metal filter 140 are decomposed during the regeneration process of the metal filter 140 to a metal such as sodium (Na), magnesium (Mg), aluminum (Al), iron (Fe), etc. It leaves ashes of the ingredients. The metal filter 140 allows the ash to easily escape through pores larger than the pores of the ceramic filter having a relatively high collection efficiency. Therefore, since the metal filter 140 can be used for a long time without cleaning under conditions requiring lower collection efficiency than the ceramic filter, it can be economically advantageous.

The metal filter 140 may be formed of a material such as stainless steel. When the filter mounting space 113c of the housing 110 has a rectangular cross-sectional area, the metal filter 140 may have a rectangular outer circumference. The metal filter 140 may be supported by being surrounded by a casing 146 on its outer peripheral surface.

That is, the metal filter 140 may be accommodated and supported in the hollow of the casing 146 with both ends exposed from both openings of the casing 146 . The casing 146 may be formed of a material such as stainless steel. A plurality of metal filters 140 may be arranged in a width direction and a height direction of the filter mounting space 113c.

For example, as shown in FIG. 3 , the metal filter 140A may have a structure in which metal mesh nets 141 are stacked. The metal mesh network 141 allows the meshes to form pores to collect harmful substances around the pores. The metal filter 140A may be disposed in the filter mounting space 113c with the outermost metal mesh networks 141 facing the inlet 111 and the outlet 112 of the housing 110, respectively. The metal mesh networks 141 are sequentially stacked from one opening of the casing 146 to the opposite opening of the casing 146 to be accommodated in the hollow of the casing 146 .

As another example, as shown in FIG. 4 , the metal filter 140B may have a metal foam structure. The metal foam has pores according to foam molding, and allows harmful substances to be trapped around the pores. The metal foam may have a hexahedral shape. The metal filter 140B may be accommodated in the hollow of the casing 146 with both ends exposed from both openings of the casing 146 .

As another example, although not shown, the metal filter may have a structure in which metal threads are entangled. Tangled metal threads form pores between adjacent pores, allowing harmful substances to be collected around the pores.

As another example, as shown in FIG. 5 , the metal filter 140C is partitioned in parallel with each other by the porous metal partition walls 141 ′, so that both ends are alternately sealed with the flow path 142 ′ through which air passes. ) may have a structure with Here, the flow passages 142 ′ are the forward flow passages 143 ′ having an open end toward the inlet 111 and a sealed end toward the outlet 112 , and the end toward the inlet 111 is sealed and It may include forward flow passages 143' and reverse flow passages 144' alternately arranged in a form in which the end facing the outlet 112 is opened.

Contaminated air is introduced into the forward flow path 143' from the inlet space 113a, passes through the porous metal partition wall 141', and then flows through the adjacent reverse flow path 144' and is discharged. In this process, harmful substances contained in the polluted air are collected in the porous metal partition wall 141'. The harmful substances collected in the porous metal partition wall 141 ′ are decomposed into gas during the regeneration process of the metal filter 140C. The flow paths 142' are illustrated as having a rectangular cross-sectional structure, but may have various cross-sectional structures such as hexagonal, octagonal, and circular structures.

In a further aspect, the metal filter 140 may be coated with a cracking catalyst around the pores. The cracking catalyst serves to crack the harmful substances collected in the metal filter 140 to more smoothly decompose it into gas. In addition, the cracking catalyst serves to lower the combustion temperature for burning the harmful substances collected in the metal filter 140 by the heater 150 .

In the case of the metal filter 140C having the porous metal partition walls 141', one side of the porous metal partition walls 141' forms the inner surface of the forward flow passage 143' and the other side is the inner surface of the reverse flow passage 144'. The cracking catalyst may be coated on each inner surface of the forward flow passages 143' as well as on each inner surface of the reverse flow passages 144'. Therefore, the metal filter 140C can be used even if it is mounted in the filter mounting space 113c so that both ends are positioned opposite to each other.

In a further aspect, the housing 110 may include a filter entrance 114 , a door 115 , and a sealing mechanism 118 . Referring to FIGS. 6 to 9 together with FIGS. 1 and 2 , the filter entrance 114 is formed in a portion corresponding to the filter mounting space 113c. Accordingly, the filter entrance 114 allows the user to put the metal filter 140 back in so that both ends of the metal filter 140 are reversed after the user takes the metal filter 140 out of the filter mounting space 113c. The filter entrance 114 may be formed on one side of the housing 110 . The filter entrance 114 may be sized to smoothly enter and exit the metal filter 140 .

The door 115 opens and closes the filter entrance 114 . The door 115 allows the metal filter 140 to be mounted or detached from the filter mounting space 113c while the filter entrance 114 is opened. The door 115 closes the filter entrance 114 while the metal filter 140 is mounted in the filter mounting space 113c to prevent air leakage from around the filter entrance 114 .

The door 115 may include an inner door member 116 and an outer door member 117 . The inner door member 116 may be bolted to the periphery of the filter entrance 114 in a state in which the filter entrance 114 is closed. The inner door member 116 may be released from the bolted state around the filter entrance 114 to open the filter entrance 114 . Alignment protrusions 114a may be formed around the filter entrance 114 . The inner door member 116 may be aligned with the filter entrance 114 by inserting the alignment protrusions 114a into the alignment holes 116a, respectively.

The outer door member 117 may cover the inner door member 116 from the outside to improve the aesthetics. The housing 110 may have a support frame 114b formed along the periphery of the filter entrance 114 to support the periphery of the external door member 117 . The outer door member 117 may have locking protrusions at the bottom.

The support frame 114b may have locking grooves for inserting the locking protrusions. The upper portion of the outer door member 117 may be locked to the support frame by the lock 117a after the locking protrusions are inserted into the locking grooves of the support frame 114b. The outer door member 117 may have gripping grooves formed on the outer surface. Accordingly, the user can hold the external door member 117 by hooking his or her finger on the gripping grooves.

The lock 117a may include a lock passage, an operating table, and a lock groove. The lock box is mounted on the outer door member 117 so that the key hole is exposed. When the key is inserted into the key hole and recognized successfully, the lock can rotate the movable member inside according to the rotation of the key. One end of the operating table is fixed to the movable member of the lock box. The operating table rotates according to the rotation of the movable member. The lock groove is formed in the support frame 114b to insert or separate the operating table according to the rotational operation of the operating table.

7 and 8, the sealing mechanism 118 seals the periphery of the metal filter 140 with respect to the filter mounting space 113c. The sealing mechanism 118 may include a sealing diaphragm 118a and a pusher 119 .

The sealing partition plate 118a is fixed to the inner wall of the housing 110 while being disposed between the inlet space 113a and the filter mounting space 113c. The sealing diaphragm 118a is formed to be in close contact with the periphery of the inlet space 113a of the metal filter 140 , thereby sealing between the periphery of the metal filter 140 and the inner wall of the housing 110 .

When a plurality of metal filters 140 are arranged in a width direction and a height direction of the filter mounting space 113c, the sealing diaphragm 118a may have a rib in the center that is in close contact with the boundary of the metal filters 140. have. The sealing diaphragm 118a may be equipped with a packing material or made of a packing material itself.

The pusher 119 may include pushing supports 119a, pushing blocks 119b, links 119c, and adjustment bolts 119d. The pushing supports 119a are fixed to the inner wall of the housing 110 while being disposed between the discharge space 113b and the filter mounting space 113c. Each of the pushing supports 119a may be disposed to be long in the width direction of the filter mounting space 113c.

The pushing supports 119a are disposed above and below the metal filter 140 . When a plurality of metal filters 140 are arranged in the height direction, the pushing supports 119a are the upper portion of the uppermost metal filter 140 , the lower portion of the lowermost metal filter 140 , and the boundary between the metal filters 140 . It may be provided to correspond to each of the parts.

The pushing blocks 119b are disposed closer to the metal filter 140 than the pushing supports 119a and operate to be closer to or spaced apart from the metal filter 140 . The pushing blocks 119b push the metal filter 140 as they approach the metal filter 140 so as to be in close contact with the sealing diaphragm 118a. The pushing blocks 119b allow the metal filter 140 to be released from the sealing diaphragm 118a as they are spaced apart from the metal filter 140 .

The links 119c connect the pushing support 119a and the pushing block 119b to guide the operation of the pushing block 119b. The links 119c are arranged in the longitudinal direction of the pushing support 119a. Each link 119c is hinged so that one end pivots about a vertical axis to the pushing support 119a, and the other end is hinged to the pushing block 119b to pivot about a vertical axis. Accordingly, the pushing block 119b may operate to be close to or spaced apart from the metal filter 140 according to the rotation of the links 119c while being connected to the pushing support 119a by the links 119c.

The adjustment bolts 119d are respectively inserted into the fastening holes 119e of the pushing support 119a in a state of being parallel to the longitudinal direction of the pushing support 119a and screwed to the pushing block 119b. Each fastening hole 119e is formed in the form of a long hole extending long in the longitudinal direction of the filter mounting space 113c. Accordingly, the adjustment bolt 119d can move without interference with the fastening hole 119e when the pushing block 119b is operated according to the manipulation.

Adjustment bolts 119d pull or push the pushing block 119b in the longitudinal direction of the pushing support 119a according to the rotation direction, thereby bringing the pushing block 119b closer to or spaced apart from the metal filter 140. do. Accordingly, as the user operates the pushing block 119b by manipulating the adjusting bolts 119d, the metal filter 140 can be brought into close contact with or released from the sealing diaphragm 118a.

When the metal filter 140 is used for a certain period of time, after the harmful substances are decomposed, a small amount of ash is left and may be continuously accumulated around the pores on the inlet 111 side or on the inner surface of the forward flow path 143 ′. Accordingly, the air cannot smoothly escape the metal filter 140 , and thus the back pressure of the metal filter 140 increases.

When the back pressure of the metal filter 140 reaches the reference value, the user separates the metal filter 140 from the filter mounting space 113c through the filter entrance 114 . At this time, the user may open the door 115 to open the filter entrance 114 and then release the sealing mechanism 118 to take out the metal filter 140 from the filter entrance 114 . The user places both ends of the metal filter 140 taken out from the filter entrance 114 so that they are reversed, then puts it back into the filter mounting space 113c through the filter entrance 114 and seals it with the sealing mechanism 118 to mount it. . Thereafter, the user closes the door 115 to close the filter entrance 114 .

Then, in the metal filter 140 , the periphery of the pores on the inlet 111 side and the periphery of the pores on the side of the outlet 112 are positioned opposite to each other. In this state, when the metal filter 140 is used, the ash accumulated around the pores on the inlet 111 side is separated and discharged by the force of the air passing through the pores.

As another example, as shown in FIG. 9 , when the forward flow paths 143 ′ and the reverse flow paths 144 ′ are positioned opposite to each other, the air in the inlet space 113a is introduced into the previous reverse flow path 144 ′. After passing through the porous metal partition wall 141', it flows through the adjacent forward flow path 143' and is discharged.

In this process, the ash accumulated on the inner surface of the forward flow passage 143' is separated from the inner surface of the forward flow passage 143' and discharged by the force of air passing through the porous metal partition wall 141'. In this way, the metal filter 140 can be used for a long time without cleaning.

Although not shown, the back pressure of the metal filter 140 may be measured by a pressure gauge. When it is determined that the back pressure of the metal filter 140 has reached the reference value based on the information provided from the pressure gauge, the controller may notify the user visually or audibly through an alarm.

The heater 150 heats the metal filter 140 . The heater 150 serves to supply heat for regenerating the metal filter 140 by removing foreign substances collected in the metal filter 140 . Here, the heater 150 may burn and remove foreign substances such as soot collected by the metal filter 140 , and may also remove odors in polluted air. The heater 150 may be controlled to be driven by a controller.

The heater 150 is installed in the regeneration circulation tube 160 when a regeneration circulation pipe 160 to be described later is connected to the housing 110 to heat the air in the regeneration circulation tube 160 to provide it to the metal filter 140 . can The heater 150 may be installed adjacent to the metal filter 140 in the housing 110 to heat the metal filter 140 . The heater 150 may have various configurations, such as a heater using an electric heating wire.

In an additional aspect, the air purifier 100 may include a regeneration circulation pipe 160 , a circulation fan 170 , and an oxidation catalyst 180 . The regeneration circulation pipe 160 has an inlet end connected to the inlet space 113a and an outlet end connected to the outlet space 113b. Accordingly, the air introduced into the passage 113 can circulate through the passage 113 and the regeneration circulation pipe 160 .

The regeneration circulation pipe 160 may be opened and closed by a damper 161 for the circulation pipe. While the regenerated polluted air generated in the process of regenerating the metal filter 140 is circulated through the regenerated circulation pipe 160 in the passage 113 and undergoes regeneration purification treatment, the damper 161 for the circulation pipe is the regenerated circulation pipe 160 . open the While the indoor polluted air is purified by the metal filter 140 , the damper 161 for the circulation pipe maintains the regeneration circulation pipe 160 in a closed state.

The damper 161 for circulation pipe may be configured such that a damper blade is rotatably coupled to the regeneration circulation pipe 160 by a damper shaft and opens and closes by a damper rotation motor. Whether the opening/closing operation of the damper blade is detected by the proximity sensor may be provided to the controller. The controller may drive and control the damper rotation motor based on information sensed from the proximity sensor. The damper blade of the damper 161 for the circulation pipe may be disposed to open and close the end of the regeneration circulation pipe 160 toward the discharge space.

The heater 150 may be installed in the regeneration circulation pipe 160 to heat the air in the regeneration circulation pipe 160 . The air heated by the heater 150 is sent into the passage part 113 by the circulation fan 170 , and may heat the metal filter 140 while passing through the metal filter 140 . Accordingly, foreign substances such as soot collected by the metal filter 140 may be burned and removed, and odors in the regenerated polluted air may also be removed.

The circulation fan 170 is installed in the regeneration circulation pipe 160 to suck air from the inlet space 113a and send it to the outlet space 113b. The circulation fan 170 sends the air heated by the heater 150 in the regeneration circulation pipe 160 into the passage 113 , and sucks the air in the passage 113 into the regeneration circulation tube 160 . works to do In this process, as the heating air by the heater 150 is circulated and supplied to the entire area of the metal filter 140 , foreign substances collected in the metal filter 140 can be evenly removed, and the metal filter 140 is regenerated. This can reduce the hassle of frequently replacing the metal filter 140 .

In a state in which the inlet 111 is closed, the indoor pressure may be lower than the pressure of the inlet space 113a. The pressure of the inlet space 113a can be lowered by sucking air into the regeneration circulation pipe 160 from the air and sending it to the outlet space 113b through the end of the regeneration circulation pipe 160 toward the outlet space. Accordingly, it is possible to prevent the air in the passage 113 from leaking into the room. The circulation fan 170 may be driven and controlled by a controller.

Additionally, during the purification treatment by circulating the contaminated air through the regeneration circulation pipe 160, the circulation fan 170 intermittently sucks air from the discharge space side end of the regeneration circulation pipe 160 to the regeneration circulation pipe 160. It is also possible to reverse the direction of air circulation by operating it to blow out through the inlet end of the .

The oxidation catalyst 180 is disposed in the regeneration circulation tube 160 in a form in which the oxidation catalyst is coated on a carrier. The oxidation catalyst may be formed of a metal oxide such as platinum (Pt), palladium (Pd), or rhodium (Rh). The oxidation catalyst may serve to cause an oxidation reaction of the CH gas cracked during the regeneration process of the metal filter 140 into CO ₂ , H ₂ O, and NOx gas. In addition, the oxidation reaction by the oxidation catalyst is an exothermic reaction, thereby reducing the burden on the heater 150, thereby reducing the amount of power used.

The carrier may be made of a material such as ceramic having a honeycomb structure. The carrier may be partitioned in parallel with each other by barrier ribs to have flow paths through which air passes. Both ends of the flow paths are opened to allow air to pass therethrough. The carrier may be supported by coating the oxidation catalyst on the partition walls. Accordingly, the oxidation catalyst 180 introduces the cracked gas into the flow passages of the carrier and passes it through, and in the process, it can be oxidized by the oxidation catalyst and discharged.

The air purifier 100 may accommodate the regeneration circulation pipe 160 in the cabinet 190 supporting the lower side of the housing 110 . The cabinet 190 has caster wheels 191 installed at the bottom thereof to facilitate movement of the air purifier 100 .

An operation example of the above-described air purifier 100 will be described with reference to FIG. 10 together with FIG. 2 as follows.

During the daytime business, when a relatively large amount of polluted air is generated indoors, as shown in FIG. 2, the inlet 111 of the housing 110 is opened by the inlet damper 120, and the outlet of the housing 110 ( 112 is opened by the damper 130 for the outlet. At the same time, the regeneration circulation pipe 160 is maintained in a closed state by the damper 161 for the circulation pipe. In this state, the indoor polluted air is introduced into the passage 113 of the housing 110 through the inlet 111 by the exhaust fan. The polluted air introduced into the passage 113 is filtered through the metal filter 140 and then discharged through the outlet 112 .

At night time when polluted air is generated relatively little indoors, as shown in FIG. 9 , the inlet 111 of the housing 110 is closed by the inlet damper 120 , and the outlet 112 of the housing 110 is closed. ) is closed by the damper 130 for the outlet. At the same time, the regeneration circulation pipe 160 is maintained in an open state by the damper 161 for the circulation pipe.

In this state, the heater 150 and the fan 170 for circulation are driven. Then, the air in the passage 113 may be sucked into the regeneration circulation pipe 160 by the circulation fan 170 , and then heated by the heater 150 to be discharged into the passage 113 . The heated air blown into the passage 113 is oxidized by the oxidation catalyst 190 and heated to a high temperature while passing through the metal filter 140 .

As such, when the air circulates through the passage 113 and the regeneration circulation pipe 160 while being heated and oxidized, foreign substances such as soot collected in the metal filter 140 during the daytime are burned and removed as the metal filter ( 140) can be regenerated, and the regenerated polluted air in the passage section 113 can be regenerated and purified again.

When the regeneration and purification process for the regenerated polluted air in the passage 113 is completed through this process, the heater 150 and the circulation fan 170 stop, and the outlet 112 of the housing 110 closes the outlet damper ( 130), the purified air can be discharged to the outside.

In this way, if the metal filter 140 is used for a certain period of time and then ash is accumulated on the metal filter 140 and the back pressure of the metal filter 140 reaches a reference value, the user reverses both ends of the metal filter 140 to After the filter 140 is reinstalled, it can be used. Accordingly, the metal filter 140 can be used for a long time without cleaning.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, it will be understood that this is merely exemplary, and that various modifications and equivalent other embodiments are possible therefrom by those skilled in the art. will be able Accordingly, the true scope of protection of the present invention should be defined only by the appended claims.

110..Housing 111..Inlet
112..Outlet 113..Passage
114..filter entrance 115..door
116..Internal door member 117..External door member
118..Sealing mechanism 118a..Sealing plate
119..pusher 120..damper for inlet
130..Damper for outlet 140..Metal filter
150..Heater 160..Regeneration circulation pipe
170..Circulation fan 180..Oxidation catalyst

Claims (4)

The exhaust fan introduces air into the passage through the inlet and discharges it through the outlet, and the passage includes an inlet space communicating with the inlet at one of the filter mounting space and the filter mounting space, and the outlet at the other side of the filter mounting space. A housing having a discharge space communicating with;
a damper for opening and closing the inlet;
a damper for the outlet opening and closing the outlet;
a metal filter installed in the filter mounting space to collect harmful substances in the inlet air, and to have pores sized to allow ash left in the process of decomposing the collected harmful substances to escape; and
a heater for heating the metal filter;
An air purifier comprising a. According to claim 1,
The metal filter,
An air purifier comprising any one of a structure in which metal mesh nets are stacked, a structure in a metal foam, and a structure in which metal threads are entangled. According to claim 1,
The metal filter is partitioned in parallel with each other by porous metal barrier ribs, and both ends are alternately sealed and have a structure having flow paths through which air passes. According to claim 1,
The housing is
a filter entrance formed in a portion corresponding to the filter mounting space;
a door that opens and closes the filter entrance, and
and a sealing mechanism for sealing the periphery of the metal filter to the filter mounting space.

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