KR102105640B1 - Heating air freshener - Google Patents

Abstract

The present invention relates to an air purifier with a heating function and, more specifically, to an air purifier with a heating function, capable of sterilizing and deodorizing indoor air by heating the indoor air. According to the present invention, the air purifier with a heating function comprises: a housing including a filtering path and a circulation path; a filter assembly arranged in the filtering path; a blowing fan arranged in the filtering path; a heater assembly arranged in the rear of the filter assembly in the filtering path; and a cooling structure including a body unit, a thermoelectric module, and a circulation fan.

Description

Heating air freshener

The present invention relates to a warm air purifier, and more specifically, to filter and purify the indoor air, as well as to sterilize and deodorize the indoor air by heating, and to heat the room using heated heat. It is about the purifier.

Recently, urbanization and industrialization are progressing, and in addition to air pollutants due to increased vehicle operation, new air pollutants such as yellow dust and fine dust flowing from China have been raised as a social problem.

Accordingly, in order to reduce the harmfulness of these air pollutants, air cleaners are widely used in general households. Currently, a general air purifier that is widely used filters indoor air using mechanical or physicochemical filters such as a dust filter, a hepa filter, an antibacterial filter, and a deodorizing filter, but has limitations in terms of sterilization and deodorization.

『Korean Registered Patent Publication No. 10-0376384』

An object of the present invention is to provide a warm air purifier capable of sterilizing and deodorizing indoor air by heating as well as filtering and purifying indoor air.

In addition, an object of the present invention is to provide a warm air cleaner that can be utilized by controlling heated heat.

In order to achieve this object, the present invention, a housing including a filtration path of the air connecting the inlet and outlet of the outside air, and a circulation path connected to the front end of the filtration path at the rear end of the filtration path; A filter assembly disposed in the filtration path to filter foreign substances contained in the outside air; A blower fan disposed in the filtration path and allowing the outside air to flow through the inlet port to proceed along the filtration path; A heater assembly disposed behind the filter assembly in the filtration path to heat the air filtered through the filter assembly; And flow paths formed in plural along the traveling direction of the filtration path, disposed between the rear of the heater assembly in the filtration path and the front end of the circulation path, and the heated air flowing from the heater assembly is the After being distributed and passed along the flow paths, the body portion that faces the outlet along the filtration path and the low temperature portion contact the body portion and are installed so that the high temperature portion is exposed to the circulation path, and flows in the flow paths of the body portion during operation. The thermoelectric module for cooling the heated air to be installed, and installed in the circulation path to pass some of the cooled air while passing through the body portion to the circulation path to dissipate the high temperature portion of the thermoelectric module, and the air in the circulation path It provides a warm air cleaner comprising a cooling structure including a circulation fan to re-enter the front end of the filtration path.

According to the present invention has the following effects.

First, by heating the indoor air filtered by the filter assembly through the heater assembly, the filtered air discharged from the housing can be sterilized and deodorized to be provided indoors.

Second, it is possible to assist the heating in the winter by using the heated air discharged from the housing, or to drive the thermoelectric module of the cooling structure in the summer, so that the sterilized and deodorized air is supplied to the room in a cooled state.

Third, when the thermoelectric module is driven, the heat source obtained by heat exchange for cooling of the heated air can be recycled as a heating source for sterilization and deodorization by re-entering the filtration path through a circulation path.

Fourth, when the heater assembly and the cooling structure are formed in a honeycomb structure, a proper heat flow of the indoor air can be secured while maximizing a contact surface with the indoor air to obtain a better heat exchange effect.

1 is a perspective view showing the external configuration of a warm air cleaner according to an embodiment of the present invention.
2 is a cross-sectional view showing the internal configuration of the warm air cleaner of FIG. 1.
3 is an exploded perspective view of only the main portion to explain the heating and re-entry process of the indoor air of FIG. 2.
4 is a flowchart illustrating a method of controlling and utilizing heated air of a warm air purifier according to an embodiment of the present invention.

1 shows the external configuration of the warm air purifier 100 according to an embodiment of the present invention, FIG. 2 shows the internal configuration of the warm air purifier 100 of FIG. 1, and FIG. 3 shows the interior of FIG. 2 The process of heating and re-entering air is shown.

1 to 3, the warm air purifier 100 according to an embodiment of the present invention filters and heats indoor air to sterilize and deodorize it, as well as utilize or filter the heat source of the heated air for indoor heating For recycling the heated indoor air as a heating source, housing 110, filter assembly 120, blower fan 130, heater assembly 140, cooling structure 150, supply fan 160, LED It includes a lamp 170, a display panel 180 and a control panel 190.

The housing 110 constitutes a main body of the warm air purifier 100, and also provides an inlet 111, an inner passage 112, an outlet 113, and an outer passage 114. The inlet 111 is formed by a plurality of perforations in the housing 110 along the outer circumferential surface of the lower portion of the housing 110 so that indoor air (outdoor) is introduced. The inner flow path 112 is connected to the inlet 111 and is formed to extend from the bottom to the top along the center of the housing 110 to provide a filtration path FP for indoor air. The outlet 113 is formed at the end of the inner flow path 112 that is the filtration path FP, that is, the uppermost portion of the housing 110 to discharge filtered indoor air into the room. At this time, the inner flow path 112 may be a straight line shape extending from the bottom to the top as described above, but the height of the outlet 113 is formed higher than that of the inlet 111 but may be refracted between them. Of course, it is obvious that the outlet 113 is formed at a lower height than the inlet 111, and is also within the technical spirit of the present invention. The outer flow path 114 extends from the top to the bottom of the housing 110 to connect the rear end and the front end of the inner flow path 112, and is formed on the left, right, and back sides along the circumferential direction of the inner flow path 112, respectively. Provide a circular path (CP). In one embodiment of the present invention, as described above, three inner flow paths 112 are assumed and illustrated (see FIG. 3) and described, but this is only one example, and the direction of the inner flow path 112 It may be a unitary form along the perimeter or a structure divided into three or more.

The filter assembly 120 is disposed at the tip of the filtration path FP, which is the inner flow path 112 of the housing 110, to physically and chemically filter indoor air flowing from the inlet 111. In the filter assembly 120, a dust filter 121 is disposed at the front end of the filtration path FP, and at the rear end, three types of filters 122 of a hepa filter, an antibacterial filter, and a deodorizing filter are disposed to filter the introduced indoor air. . In an embodiment of the present invention, the dust filter 121 and the three-type filter 122 are illustrated and described as examples, but the technical spirit of the present invention is not limited thereto, and other mechanical filters, pre-filters, etc. may be used. , Fiber filter method, which is a method of removing particles by a well-known capture mechanism such as inertial collision, gravity sedimentation, blocking, and diffusion, may be applied. In addition, the electrostatic filter method for removing particulate contaminants using electrostatic force may be applied. The various filters described above are known techniques, and detailed description thereof will be omitted.

The blowing fan 130 is disposed behind the filter assembly 120 of the filtration path FP to introduce indoor air into the housing 110 through the inlet 111, and the introduced indoor air is introduced into the filter assembly 120, heater It provides a driving force that passes through the assembly 140 and the cooling structure 150, that is, proceeds along the filtration path FP. At this time, the blowing fan 130 is preferably disposed behind the filter assembly 120 to reduce the influence or damage caused by particulate contaminants.

The heater assembly 140 is disposed at the rear of the blower fan 130 of the filtration path FP to sterilize and deodorize the filtered air by heating the physically and chemically filtered air. It consists of four heaters (141, 142, 143, 144) including a plurality of flow paths of a honeycomb structure formed along the path (FP). At this time, the four heaters 141, 142, 143, and 144 have a plurality of flow paths 145 formed therein to form a honeycomb structure to ensure flow rate and maximize contact area with incoming air. By improving the heat exchange effect, four heaters 141, 142, 143, and 144 are arranged side by side in a direction crossing the filtration path FP, respectively, to uniformly heat the filtered indoor air.

When the air heated through the heater assembly 140 flows out through the outlet 113, the cooling structure 150 heats the heated air for cooling to be supplied to room temperature, and is obtained by heat exchange in the cooling process By re-entering the heat to the front end of the filtration path (FP), the body portion 151, the flow paths 152, the thermoelectric module 153, the heat sink 154, the heat dissipation module binding hole 155 and the circulation fan 156 ).

The body portion 151 is disposed behind the heater assembly 140 of the filtration path FP, and a plurality of flow paths 152 formed along the filtration path FP is formed therein to pass through the heater assembly 140 As the heated air passing through is dispersed and passed through the respective flow paths 152, heat exchanges with the heated air passing therethrough to cool, as well as a part of the body portion 151 is connected to the circulation path CP through heat exchange. The obtained heat is provided to the circulation path (CP). At this time, a plurality of flow paths 152 are formed in a honeycomb structure having a regular hexagonal cross section like the flow paths 145 of the heater assembly 140 to secure an appropriate amount of flow rate and increase a heat exchange rate. The thermoelectric module 153 is installed on the exposed surface of the body portion 151 in the circulation path CP, so that the heated body portion 151 is heat-exchanged in the cooling process, and the high temperature portion is cooled in the circulation path CP. It is arranged to be exposed to provide heat generated in the cooling process to the circulation path (CP). The heat sink 154 is installed in the high temperature portion of the thermoelectric module 153 in the circulation path CP, so that the heat generated in the thermoelectric module 153 can be radiated to the circulation path CP, within the circulation path CP. It has a structure in which a plurality of pins are formed to have a wide contact surface with a fluid. The heat dissipation module binding hole 155 couples or binds the thermoelectric module 153 and the heat radiation plate 154 installed in close contact with the thermoelectric module 153 to the body portion 151. Here, in one embodiment of the present invention, the outer flow path 114, that is, the circulation path CP is formed in three on the left, right, and rear surfaces of the inner flow path 112 of the housing 110, and thus, the thermoelectric module 153 ) And the heat sink 154 are also installed in three sets in each circulation path CP. Thus, the heat dissipation module binding hole 155 combines one thermoelectric module 153 and a heat sink 154 to the body portion 151, but binds the adjacent thermoelectric module 153 and the heat sink 154 together to form a body portion ( 151). The circulation fan 156 is installed at the front end of the circulation path CP and supplies heat radiated from the heat sink 154 to the front end of the filtration path FP through the outer flow path 114. At this time, the circulation fan 156 is formed in a centrifugal structure to alleviate the constraints due to the refractive structure of the circulation path CP and the filtration path FP.

The supply fan 160 is disposed at the outlet 113 to close the outlet 113, and discharges the sterilized and deodorized air cooled through the cooling structure 150 into the room.

Here, the circulation path CP is connected to the front end from the rear end of the filtration path FP, as described above, specifically, the front end is connected between the cooling structure 150 and the supply fan 160, the cooling structure 150 ) To allow air to pass through, and the rear end is connected between the filter assembly 120 and the inlet 111 so that air in the circulation path CP is re-entered into the filtration path FP to be provided to the filter assembly 120. do.

The LED lamp 170 is installed along the circumferential outer circumferential surface of the housing 110 at the upper portion of the housing 110 to transmit light, so that the blowing fan 130, the heater assembly 140, the thermoelectric module 153, and the circulation fan The driving operation of the warm air purifier 100 including 156 and the supply fan 160 is visible to the user.

The display panel 180 and the control panel 190 are respectively installed on the front surface of the housing 110 to blow the fan 130, the heater assembly 140, the thermoelectric module 153, the circulation fan 156, and the supply fan 160 ) Graphs the driving operation of the user, and the control panel 190 allows the user to blow fan 130, heater assembly 140, thermoelectric module 153, circulation fan 156 and supply fan 160. It is possible to control on / off operation of the interlocked warm air cleaner 100, temperature setting, driving time setting, and the like.

In the following, through the operation of the thermoelectric module 153 according to an embodiment of the present invention to heat the room using the air heated in the warm air purifier 100, or through the circulation path (CP) filtration path ( FP) will be described in detail with reference to Figure 4 for recycling as a heat source for sterilization and deodorization.

Referring to Figure 4, the warm air purifier 100 according to an embodiment of the present invention is driven by the blowing fan 130 according to the control operation of the user's control panel 190, the indoor air flows through the inlet 111 Take and filter physically and chemically through the filter assembly 120 disposed in the filtration path FP. (S1100)

The physically and chemically filtered air is heated and sterilized and deodorized while passing through the heater assembly 140 disposed at the next stage of the filtration path FP by the driving force of the blowing fan 130. (S1200)

Thereafter, the sterilized and deodorized indoor air is dispersed and passed through the flow paths of the honeycomb structure formed in plural in the cooling structure 150 by the driving force of the supply fan 160, thereby being heat exchanged and discharged to the outlet 113 in a cooled state (S1300) Here, the heated air is not cooled to cool, but is cooled according to the indoor air temperature, and for this purpose, an indoor temperature sensor for measuring the indoor temperature may be further installed in the housing 110.

At this time, when the indoor temperature is higher than the proper indoor temperature or the user's set temperature, such as in the summer, the thermoelectric module 153 exchanges heat with the cooling structure 150 to cool the cooling structure 150 so that cooled air is supplied to the room. , Re-entry the heat obtained by heat exchange through the circulation path (CP) to assist the heating operation of the heater assembly 140. (S1400)

On the other hand, when the room temperature is less than a suitable temperature or a user's set temperature, such as in winter, the thermoelectric module 153 does not cool the cooling structure 150 by stopping the operation, and the cooling structure 150 is heated by heat exchange to heat the heater By approaching the temperature of the heated air discharged from the assembly 140, the air heated in the heater assembly 140 is supplied to the room without being cooled (S1500).

However, when approaching a set temperature, an appropriate room temperature, or a user's set temperature to prevent a safety accident due to heated air discharged to the outlet 113 by the supply fan 160, it is driven again and the corresponding thermoelectric By providing an effect, the cooling structure 150 is cooled to control the temperature of the heated air discharged through the outlet 113 and supply it to the room. (S1600)

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: warm air cleaner
110: housing 111: inlet
112: inner passage 113: outlet
114: outer flow path 120: filter assembly
121: dust filter 122: three types of filters
130: blowing fan 140: heater assembly
141 ~ 144: Heaters 145: Euro
150: cooling structure 151: body portion
152: Euro 153: Thermoelectric module
154: heat sink 155: heat sink module binding hole
156: circulation fan 160: supply fan
170: LED lamp 180: display panel
190: control panel
FP: Filtration path CP: Circulation path

Claims (14)

A housing including a filtration path for air connecting the inlet and outlet of the outside air and a circulation path connected to a front end of the filtration path at a rear end of the filtration path;
A filter assembly disposed in the filtration path to filter foreign substances contained in the outside air;
A blower fan disposed in the filtration path and allowing the outside air to flow through the inlet port to proceed along the filtration path;
A heater assembly disposed behind the filter assembly in the filtration path to heat the air filtered through the filter assembly; And
It is disposed between the rear end of the heater assembly in the filtration path and the front end of the circulation path, including a plurality of flow paths formed along the traveling direction of the filtration path therein, the heated air flowing from the heater assembly is the flow path After being dispersed and passing along the body portion, the body portion facing the outlet along the filtration path and the low temperature portion contacting the body portion are installed so that the high temperature portion is exposed to the circulation path and flows in the flow paths of the body portion during operation. The thermoelectric module for cooling the heated air, and installed in the circulation path to pass some of the cooled air while passing through the body portion to the circulation path so as to dissipate the high temperature portion of the thermoelectric module, and the air in the circulation path A warm air cleaner comprising a cooling structure including a circulation fan that re-enters the front end of the filtration path. The method according to claim 1,
The cooling structure,
It is installed in the high temperature portion of the thermoelectric module in the circulation path, further comprising a heat sink to conduct heat generated in the thermoelectric module to radiate heat to the circulation path. The method according to claim 2,
The cooling structure,
It is formed in a structure surrounding the body portion, and further comprising a heat dissipation module binding hole for binding the thermoelectric module and the heat sink to be mounted on the body portion. The method according to claim 1,
The housing,
A warm air purifier having a relatively high position of the outlet than the inlet, so that the filtration path is directed from bottom to top. The method according to claim 1,
The housing,
In the state in which the filtration path is formed in the inner center, the circulating path is provided with one or more, and the warm air cleaner is formed in a structure surrounding the filtration path. The method according to claim 1,
The housing,
A warm air purifier in which the circulation path starts from the filtration path in the rear portion of the heater assembly and connects to the filtration path in the front portion of the filter assembly. The method according to claim 1,
The blowing fan,
A warm air cleaner disposed behind the filter assembly in the filtration path. The method according to claim 1,
The heater assembly,
It includes at least one heater formed with a plurality of flow paths having a honeycomb (honeycomb) structure along the traveling direction of the filtration path,
When there are a plurality of heaters, the plurality of heaters are arranged to be adjacent to each other in a direction crossing the filtration path. The method according to claim 1,
The cooling structure,
A warm air cleaner in which a plurality of flow paths formed in the interior are formed in a honeycomb structure. The method according to claim 1,
The filter assembly,
A warm air purifier comprising at least one of a dust filter, a hepa filter, an antibacterial filter, or a deodorizing filter. The method according to claim 1,
It is installed in the outlet, a warm air cleaner further comprising a supply fan for supplying the air of the filtration path through the cooling structure to the room. The method according to claim 11,
A thermal air cleaner further installed on the outer circumferential surface of the housing, the LED lamp operating in conjunction with the operation of the blowing fan, the thermoelectric module, or the supply fan. The method according to claim 11,
It is installed on the outer circumferential surface of the housing, further comprising a display panel for displaying the operation information of the blowing fan, the thermoelectric module or the supply fan. The method according to claim 11,
It is installed on the outer circumferential surface of the housing, further comprising a control panel for controlling the operation of the blowing fan, the thermoelectric module or the supply fan.

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